Renewable Energy and Jobs: Annual Review 2019

1111

million jobs in 2018million jobs in 2018

Renewable Energy and Jobs

Annual Review 2019

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ABOUT IRENA

The International Renewable Energy Agency (IRENA) is an intergovernmental

organisation that supports countries in their transition to a sustainable ener-

gy future and serves as the principal platform for international co-operation,

a centre of excellence, and a repository of policy, technology, resource and

ﬁnancial knowledge on renewable energy. IRENA promotes the widespread

adoption and sustainable use of all forms of renewable energy, including bio-

energy, geothermal, hydropower, ocean, solar and wind energy, in the pursuit

of sustainable development, energy access, energy security and low-carbon

economic growth and prosperity.

www.irena.org

ACKNOWLEDGEMENTS

This report was developed under the guidance of Rabia Ferroukhi (IRENA)

and authored by Michael Renner, Celia García-Baños (IRENA), and Arslan

Khalid (consultant).

The report greatly beneﬁtted from modelling work on hydropower by Ulrike

Lehr and Maximilian Banning (GWS). IRENA also acknowledges the valuable

contribution by William Brent (Power for All) on o-grid employment.

For further information or to provide feedback: publications@irena.org

Available for download: www.irena.org/publications

DISCLAIMER

This publication and the material herein are provided “as is”. All reasonable

precautions have been taken by IRENA to verify the reliability of the

material in this publication. However, neither IRENA nor any of its ocials,

agents, data or other third-party content providers provides a warranty of

any kind, either expressed or implied, and they accept no responsibility or

liability for any consequence of use of the publication or material herein.

The information contained herein does not necessarily represent the

views of all Members of IRENA. The mention of speciﬁc companies or

certain projects or products does not imply that they are endorsed or

recommended by IRENA in preference to others of a similar nature that

are not mentioned.

The designations employed and the presentation of material herein do

not imply the expression of any opinion on the part of IRENA concerning

the legal status of any region, country, territory, city or area or of its

authorities, or concerning the delimitation of frontiers or boundaries.

Photographs are from Shutterstock unless otherwise indicated.

IRENA HEADQUARTERS

Masdar City

P.O. Box 236, Abu Dhabi, United Arab Emirates

www.irena.org

A Renewable Energy Roadmap

Francesco La Camera

Director-General

International Renewable

Energy Agency

Renewable energy delivers on all main pillars of sustainable development:

environmental, economic and even social. Alongside declining costs

and steadily improving technologies, the transition to renewables is also

creating numerous employment opportunities.

Beyond pursuing climate goals, many governments have prioritised

renewables as a driver of low-carbon economic growth. Diversiﬁcation of

the supply chain has broadened the sector’s geographic footprint beyond a

few leading markets, as more countries link sustainable technology choices

to broader socio-economic beneﬁts. Increasingly, countries envisage a

domestic renewable energy industry taking the place of unsustainable

fossil-based industries.

The sector now employs at least 11 million people worldwide, with more

countries manufacturing, trading and installing renewable energy

technologies every year. As the global energy transformation continues

to gain momentum, this employment dimension ensures socio-economic

sustainability and provides yet another reason for countries to commit to

renewables.

MESSAGE FROM THE

IRENA DIRECTOR-GENERAL

million

jobs in 2018

% of all renewable

energy jobs are

in China

3.6

million

jobs are in

the solar PV

industry

% of renewable

energy jobs are

held by women

Key Numbers

KEY FACTS

Annual Review 2019

The global renewable energy sector employed 11 million people in 2018. This

compares with 10.3 million in 2017, based on available information.

Employment remains concentrated in a handful of countries, with China, Brazil, the

United States, India and members of the European Union in the lead. Asian countries’

share remained at 60% of the global total.

Several factors — including national deployment and industrial policies, changes

in the geographic footprint of supply chains and in trade patterns, and industry

consolidation trends — shape how and where jobs are created.

Nonetheless, the increasingly diverse geographic footprint of energy-generation

capacities and, to a lesser degree, assembly and manufacturing plants, has created

jobs in a rising number of countries.

The solar PV industry retains the top spot, with a third of the total renewable energy

workforce. In 2018, PV employment expanded in India, Southeast Asia and Brazil,

while China, the United States, Japan and the European Union lost jobs.

Rising off-grid solar sales are translating into growing numbers of jobs in the context

of expanding energy access and spurring economic activities in previously isolated

communities.

Rising output pushed biofuel jobs up 6% to 2.1 million. Brazil, Colombia, and Southeast

Asia have labour-intensive supply chains, whereas operations in the United States

and the European Union are far more mechanised.

Employment in wind power supports 1.2 million jobs. Onshore projects predominate,

but the offshore segment is gaining traction and could build on expertise and

infrastructure in the offshore oil and gas sector.

Hydropower has the largest installed capacity of all renewables but is now expanding

slowly. The sector employs 2.1 million people directly, three quarters of whom are in

operations and maintenance.

While the analysis suggests job growth in 2018, some of the increase reﬂects the

continued improvement and reﬁnement of methodologies that allows a rising share

of employment to be captured in statistics.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

Annual Review 2019

The renewable energy sector employed at least 11 million people, directly and indirectly, in

2018.

The total includes, for the ﬁrst time, a fuller estimate of o-grid solar in parts of the

developing world. Renewable energy employment has continued to grow worldwide since

the ﬁrst annual assessment by the International Renewable Energy Agency (IRENA) in 2012.

The solar photovoltaics (PV), bioenergy, hydro, and wind power industries were the biggest

employers (Figure 1).

1 Data are principally for 2017 – 2018, with dates varying by country and technology, including some instances where only earlier information is available.

The data for hydropower include direct employment only; the data for other technologies include both direct and indirect employment where possible.

This sixth edition of Renewable Energy and Jobs – Annual Review provides

the latest available estimates and calculations on renewable energy

employment. It represents an on-going eort to reﬁne and improve data

and methodologies. Global numbers are based on a wide range of studies

with varying methodologies and uneven detail and quality.

RENEWABLE

ENERGY

AND JOBS

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

The ﬁrst section of this report discusses key factors

shaping renewable energy employment. This is followed

by observations on job quality and inclusiveness, with

Box 1 focused on gender. The third section highlights

the latest employment trends in the modern energy

context by technology. The fourth section presents

a discussion of employment in o-grid solar for

energy access. The ﬁfth section oers insights for

selected regions and countries; countries are listed in

order of their jobs, installations or market size, rather

than alphabetically. The report wraps up with a brief

discussion of IRENA's ongoing work on the socio-

economic impacts of renewable energy.

FACTORS SHAPING

RENEWABLE ENERGY

EMPLOYMENT

Several factors shape how and where employment

is generated along the renewable energy supply

chain. These include governmental policies; the

diversiﬁcation of supply chains; trade patterns; and

industry reorganisation and consolidation trends.

Aside from these factors, which are discussed below,

labour productivity grows in importance over time. As

renewable energy industries become more mature,

gain economies of scale, navigate learning curves and

turn more to automated processes, fewer people will

be needed for a given task.

FIGURE 1: GLOBAL RENEWABLE ENERGY EMPLOYMENT BY TECHNOLOGY, 2012-2018

Source: IRENA jobs database.

Note: Except for hydropower where a revised methodology led to revisions of job estimates, numbers shown

in this figure reflect those reported in past editions of the Annual Review.

1.66

2.21

2.04

2.16

2.06

1.99

2.05

7.28 8.55

9.50

10.04 10.13 10.9810.53

5.6

6.3 7.5 7.9 8.1 8.98.5

Solar Photovoltaic

Bioenergy

Wind Energy

Solar Heating /

Cooling

Others

Hydropower

Total

Subtotal

2017 201820162015201420132012

Million jobs

0.89

0.75

2.40

1.36

0.22

0.50

0.83

2.27

2.50

1.03

2.99

2.50

1.08

2.88

2.77

1.16

2.74

3.09

1.15

3.06

3.37

1.16

3.18

3.61

0.76

0.94

0.83

0.800.81

0.23 0.19 0.20 0.24 0.16 0.18

a. Includes liquid biofuels, solid biomass

and biogas.

b. Other technologies include geothermal

energy, concentrated solar power, heat

pumps (ground-based), municipal and

industrial waste, and ocean energy.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

Governmental Policies

Governmental measures, such as auctions, feed-in

taris, subsidies, and industrial, labour and trade

policies, are indispensable as the renewable energy

sector expands and matures. They thus retain strong

inﬂuence on employment prospects.

Feed-in taris were essential to the creation of many of

today’s markets, but if their rates are too generous they

can become a budgetary burden. The growing embrace

of auctions in recent years has translated into lower

project costs, greater competitiveness with fossil fuels,

and thus more deployment. But the competitive pressure

of tenders also entails risks. Winning bids may not always

come to fruition. Cost pressure may lead some ﬁrms to

use inexpensive but low-quality equipment, or to skimp

on stang levels, wages or skills-training (IRENA, IEA and

REN21, 2018; IRENA, 2017a)

Above all, policymaking needs to minimise swings

from strong supportive measures to aggressive curbs.

Likewise, prolonged periods of policy uncertainty can

trigger job loss if they lead equipment manufacturers,

project developers, and other industry actors to

mothball or shutter facilities.

Industrial policies leverage capabilities within an economy

and strengthen domestic supply chains (IRENA, 2017b;

2017c; 2018). Well-designed incentives are needed to

nurture nascent industries, along with preferential access

to credit, economic incubators and supplier development

programmes, as well as appropriate education, training

and labour market policies to build a capable workforce.

The proper policy mix – between enabling measures and

mandates, and between inviting foreign investment and

building domestic capabilities–needs to be tailored to

country- or region-speciﬁc circumstances (IRENA, IEA

and REN21, 2018)

A key example of a successful industrial policy is the well-

developed domestic supply chains and economies of scale

in China’s solar PV industry. Manufacturing clusters in the

Yangtze River Delta play a key role. The area’s extensive

industrial infrastructure, low power prices, and presence of

suppliers from sectors such as the glass industry enables

solar ﬁrms to purchase primary and intermediate inputs

inexpensively. Strong support from central, provincial

and municipal governments has been critical. Many other

countries could, in principle, imitate such policies in order

to build viable domestic supply chains (Ball et al., 2017).

Trade, Supply-Chain Dynamics and

Industry Consolidation

Domestic installation markets are important for

employment generation in the downstream segments of

the value chain. Deeper domestic supply chains translate

into a lower degree of reliance on imports of equipment

and components. On the other side of the equation,

however, export sales hold great signiﬁcance for job

creation in countries that serve as regional or global

manufacturing hubs. This is particularly true for China and

a number of European countries (EurObserv’ER, 2019).

Countries’ trade proﬁles vary considerably from one

renewable energy technology to another (see Figure 2).

For example, while China is the largest exporter in the

ﬁeld of solar PV, its wind power ﬁrms mostly serve their

domestic market (BNEF, 2019). By contrast, Europe is a

net importer of solar PV equipment, but the continent’s

wind sector (especially in Denmark, Germany, and Spain)

is heavily export-oriented, and European wind ﬁrms also

have an extensive international manufacturing footprint.

The United States is a minor exporter of wind equipment

and runs a very small negative trade balance in the sector,

but is a large net solar importer along with India and

Turkey (EurObserv’ER, 2019).

In biofuels, the United States accounted for close to

30% of exports in 2016, ahead of European countries

(principally the Netherlands, France, Belgium, Hungary,

Germany and the United Kingdom). In hydropower,

China represented a quarter of global exports, while

European ﬁrms (primarily based in Germany, Austria,

and Italy) commanded a 46% share. The United States

and India contributed just under 5% each.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

FIGURE 2: SHARE OF GLOBAL EXPORTS AND NET TRADE VALUES IN THE WIND AND SOLAR PV

SECTORS FOR SELECTED COUNTRIES, 2016

Source: EurObserv’ER, 2019.

WIND

Net trade (million Euros)

3000

2500

2000

1500

1000

500

-500

-1000

Denmark

Germany

Spain

China

United States

Turkey

United States

0.02%

Rest of the World

China 8%

Denmark

42%

Germany

29%

Spain

15%

8 000

6 000

4 000

2 000

-2 000

-4 000

-6 000

-8 000

Net trade (million Euros)

Turkey

India

United States

China

Germany

United Kingdom

Japan

Rest of

the

World

52%

United States 4%

China

31%

Germany

Japan

SOLAR PV

2 Based on UN COMTRADE data. The year 2016 was chosen because the available 2017 data do not cover China.

3 Not including India.

Changes along renewable energy supply chains alter the

industry's geographic footprint and its trade patterns,

with consequences for where jobs are created and lost.

Corporate strategies are a key driver, although some

countries have sought to take an active role through

local content requirements.

The footprint of the solar PV industry, for instance,

has changed signiﬁcantly since 2012. The bulk of

manufacturing capacity has shifted to Asia, which

now accounts for 92% and 85% of global cell and

module capacities, respectively

. While China remains

dominant, a number of Southeast Asian countries have

emerged as signiﬁcant exporters (Roselund, 2018). By

contrast, the United States, India and Europe rely heavily

on imports. In an eort to build or retain a domestic

manufacturing base, some importing countries have

adopted a variety of import taris and levies, but the

eectiveness of such policies can vary (Trendforce,

2019; Gupta, 2018a).

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

In the face of intensifying competitive pressures,

industry consolidation is changing the face of the

renewable energy sector. In wind power, for example,

Siemens and Gamesa merged; Mitsubishi Heavy

Industries and Vestas formed an oshore joint venture

(MHI Vestas); and GE bought Alsthom’s wind assets

and acquired Denmark’s LM Wind Power.

Just three companies (Vestas, GE and Siemens

Gamesa) have dominated the US installation market in

recent years (BNEF and BCSE, 2019). GE and Siemens

Gamesa together control about half of the Brazilian

market. Just ﬁve turbine manufacturers accounted for

two thirds of all onshore wind turbines commissioned

globally during 2018: Vestas (Denmark), Goldwind

(China), GE (United States), Siemens Gamesa (Germany

and Spain), and Envision (China) (see left-hand chart of

Figure 3).

In the oshore segment, Siemens Gamesa and MHI

Vestas are the undisputed global leaders with a

combined 59% share in 2018, followed by three Chinese

companies (Sewind, Envision, and Goldwind) that

hold a combined 35% share (see right-hand chart of

Figure 3). In Europe, just two ﬁrms accounted for 93%

of cumulative oshore turbine installations as of the

end of 2018: Siemens Gamesa (69%) and MHI Vestas

(24%) (Wind Europe, 2019a).

FIGURE 3: MARKET SHARES, ONSHORE AND OFFSHORE WIND, 2018

Allothers

Seewind

Envision

Goldwind

35%

Siemens

Gamesa

Renewable

Energy

MHI Vestas

59%

All others

33%

OFFSHORE

Siemens Gamesa

Renewable Energy

Envision

19%

48%

Vestas

Goldwind

GE Wind Energy

ONSHORE

Top tier Second tier All others

Source: Wood Mackenzie, 2019.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

Quality and Inclusion

As important as it is to shed light on the quantity of

jobs created in renewable energy, job quality must

be examined as well. Although detailed information

remains quite limited, job quality is a critical aspect.

A well-paying job that requires well-honed skills

and is performed in a safe, rewarding workplace is a

greater multiplier of socio-economic beneﬁts than one

that pays little, carries few beneﬁts, or is temporary.

Employment also needs to be inclusive, providing

opportunities for people with dierent talents and skills,

and ensuring that no population group, such as women,

is systematically excluded. IRENA has emphasised the

importance of gender equity in particular (see Box 1).

What makes for good jobs? The International Labour

Organization (ILO, n.d.) deﬁnes “decent work” as work

that is “productive and delivers a fair income, security

in the workplace and social protection for families,

better prospects for personal development and

social integration, freedom for people to express their

concerns, organize and participate in the decisions

that aect their lives and equality of opportunity and

treatment for all women and men”.

As is true for the economy at large, job quality in

renewable energy varies widely across the industries

and companies that make up the sector and its

diverse supply chain. Variations in required skills

and occupational patterns explain some of this. The

signiﬁcant role of the agricultural supply chain gives

bioenergy a very dierent proﬁle from the solar, wind,

hydropower, and geothermal industries.

With respect to issues like wage levels and workplace

protections, national regulations can make a big

dierence, as can corporate management culture and

the presence of labour representatives. A friendly

workplace tends to minimise sta turnover rates

and is more likely to yield high-quality performance

in equipment manufacturing, construction and

installation, and operations and maintenance.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

100

% shares of women

STEM jobs Non-STEM

technical jobs

Administrative

jobs

average share in

renewable energy

average share in

oil and gas

32%

22%

45%35%28%

BOX 1. ENGENDERING THE ENERGY TRANSITION

The global shift to renewables demands a growing

array of skills – technical, business, administrative,

economic and legal, among others. Widening the

talent pool is thus a pragmatic reason for boosting the

participation of women in renewable energy, coming

on top of considerations of greater gender equity and

fairness.

Over the years, IRENA has addressed the gender

dimension of renewable energy in multiple

publications and programmatic activities to help ﬁll

the knowledge gap in this ﬁeld. Based on an in-depth

literature review and a ground-breaking survey of

over 1 400 employees, companies and institutions,

Renewable Energy: A Gender Perspective (IRENA,

2019a) contributed to a better understanding of

challenges and opportunities at the intersection of

gender and renewable energy.

The report found that

because of its multi-

disciplinary dimension,

the renewable energy

ﬁeld appeals to women

in ways that the fossil

fuel industry does

not. Women currently

represent 32% of the

renewable energy

workforce, substantially

higher than the 22%

average reported for the global oil and gas industry (see

Figure 4). The ﬁnding is consistent with national level

surveys. In the United States, for example, the share of

women among all solar workers has risen from about

19% in 2013 to 26% in 2018 (Solar Foundation, 2019).

FIGURE 4: SHARES OF WOMEN IN STEM, NON-STEM AND ADMINISTRATIVE JOBS

IN RENEWABLE ENERGY

Source: IRENA, 2019b.

STEM = science, technology, engineering and mathematics.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

Yet, much remains to be done to boost women’s

participation, ease their entry into the industry, and

improve their career prospects to allow their talents to

be fully utilised. At 28%, women’s presence in science,

technology, engineering and mathematics (STEM)

jobs is far lower than in non-STEM positions (35%) and

administrative jobs (45%).

IRENA survey respondents highlighted barriers

that prevent women from entering the workforce

and advancing in their careers – prominent among

them social and cultural norms, prevailing hiring

practices, a lack of relevant skills, lack of awareness

of job opportunities and lack of access to professional

networks.

A persistent glass ceiling remains the most signiﬁcant

barrier to retention and career advancement. In close

to half of the private sector organisations participating

in the survey, at least three-quarters of board members

are men. Other challenges relate to the lack of a

supportive environment, such as ﬂexible work hours,

family-friendly measures, mentoring, networking,

training opportunities and gender equity targets.

Wage inequalities were ﬂagged as an issue as well, with

close to two-thirds of respondents expressing the view

that women in renewable energy earn less than men for

the same position. The remaining third believe that men

and women are paid equally.

In the access context (i.e., where modern energy

services are limited or non-existent), decentralised

renewable energy solutions oer tremendous

opportunities for women’s engagement in multiple

segments of the value chain. Here, too, however,

barriers exist: cultural and social norms, the lack of

gender-sensitive programmes and policies, insucient

skills and training opportunities, inequity in ownership

of assets, and lack of access to ﬁnance. For example,

a study of the Indian solar rooftop sector found that

women accounted for just 11% of the workforce (a

low share, but higher than women’s presence in the

country’s fossil fuel sector). Segments of the solar value

chain where oce-based occupations predominate

(design and pre-construction) attract women much

more than construction or operations and maintenance

(Nobuoka, Patnaik, Jha and Kuldeep, 2019).

Gender diversity in renewable energy can be

substantially improved in both the modern and access-

deprived contexts by action at several levels:

• Mainstreaming gender in policy design and project

implementation, backed by solid disaggregated data

gathering and monitoring;

• Tailoring training and skills, a task requiring

government coordination of all actors;

• Implementing policies to attract and retain talent

and thereby ensure a supportive environment in the

workplace;

• Supporting women to become agents of change

and to challenge cultural and social norms in their

environment;

• Unlocking new livelihood opportunities in the access

context, such as ﬁnancing and market entry. Beyond

gender-sensitive changes in the renewable energy

sector, social and economic policies must address

legal and social barriers that limit women’s education,

asset and land ownership and access to credit.

In 2019, IRENA will present a new report based on

ground-breaking primary data on how large-scale

solar and wind projects in Sub-Saharan Africa can

beneﬁt women in rural communities (IRENA, 2019c

forthcoming).

Adapted from IRENA, 2019a

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

RENEWABLE ENERGY

EMPLOYMENT BY

TECHNOLOGY

This section highlights employment trends by

technology (Figure 5). It discusses employment

in solar PV, liquid biofuels, wind, solar heating and

cooling, and hydropower. The remaining renewable

energy technologies — biogas, geothermal energy and

ground-based heat pumps, CSP, waste-to-energy, and

ocean or wave energy — employ far fewer people, and

less information is available for them.

SOLAR PHOTOVOLTAICS

Globally, the solar PV industry installed 94 gigawatts

(GW) of capacity during 2018, the same amount as in

2017. China, India, the United States and Japan were

the most important installation markets, followed by

Australia, Germany, the Republic of Korea, and Turkey

(IRENA, 2019b).

A recent listing reveals that 50 leading solar PV panel

manufacturers maintain factories in 23 countries

(Solar Power World, n.d.). China remains dominant,

accounting in 2018 for 69% and 64% of global cell and

module capacities, respectively. All Asian countries as

a group (excluding India) held shares of 92% and 85%,

respectively (Trendforce, 2019). Japan, the Republic

of Korea, and Chinese Taipei are important producers.

Driven by Chinese and other foreign investment,

Malaysia, Thailand and Viet Nam are playing signiﬁcant

roles as producers and exporters

. Viet Nam hosts

FIGURE 5: RENEWABLE ENERGY EMPLOYMENT BY TECHNOLOGY

5000 1 000 1 500 2 000 2 500 3 000 3 500

4 000

Jobs (thousands)

Solar

Photovoltaic

Liquid Biofuels

Hydropower

Wind Energy

Solar Heating/

Cooling

Solid Biomass

Biogas

Geothermal

Energy

Municipal and

industrial waste

CSP

Tide, Wave and

Ocean Energy

O-grid solar for

energy access

1 160

3 605

801

787

334

2 063

2 054

Source: IRENA jobs database.

Note: Another 7 600 jobs, not shown separately here, cannot readily be broken down by individual renewable energy technology.

4 Module manufacturing capacities are 7.2 GW in Viet Nam, 6.5 GW in Malaysia, and 1.8 GW in Thailand (Beetz, 2018a).

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

facilities owned by 11 dierent manufacturers; Malaysia,

9; and Thailand, 6 (Solar Power World, n.d.).

IRENA estimates that global solar PV employment stood

at 3.6 million jobs in 2018

. Of the leading ten countries

shown in Figure 6, eight are Asian (for the purposes of

this report, Turkey is counted as part of Asia). Overall,

Asia is home to almost 3 million solar PV jobs (85% of the

global total), followed by North America’s 6.4% share,

Africa’s 3.9% and Europe’s 3.2%. This year’s global total

is not directly comparable to the ﬁgure reported in last

year’s edition. It includes an o-grid jobs estimate of

372 000 jobs for South Asia and parts of Africa (see the

section on "Renewable Energy Employment: Focus on

Access" further below). Earlier editions did not have fully

comparable estimates for these regions.

China, the leading producer of PV equipment and the

world’s largest installation market, accounted for about

two-thirds of PV employment worldwide, or some

2.2 million jobs (CNREC, 2019). A strong pace of capacity

additions in India (9.2 GW in 2018) led IRENA to raise its

on-grid solar employment estimate from 92 400 jobs

to 115 000 jobs, a number that could double if o-grid

deployments were included.

Solar PV employment in the European Union declined

by about 5% to 90 800 jobs in 2017, reﬂecting a drop of

more than 10% in installations

(EurObserv’ER, 2019).

Policy uncertainties caused US employment to fall for

a second year in 2018, to an estimated 225 000 jobs

Japan’s solar PV industry continues to face diculties,

including shortages of available land for deployment.

Although the country’s installation market is still one

of the world’s largest, additions in 2018 were below

those of 2017. IRENA estimates that employment fell to

250 000 jobs in 2018.

FIGURE 6: TOP 10 COUNTRIES IN SOLAR PV EMPLOYMENT

Japan

China

United States

India

2.3

2.2

2.1

2.0

0.3

0.2

0.1

Million jobs

Bangladesh

Malaysia

Germany

Turkey

Chinese Taipei

Viet Nam

61%

of PV

jobs

Top 10:

84% of

PV jobs

Source: IRENA jobs database.

5 The countries for which IRENA’s database has solar PV employment estimates represent 464 GW of cumulative installations in 2018, or 97% of the global total.

They represent 99.6% of the 94 GW of new installations in 2018.

6 The jobs data for the European Union and its member states throughout this report are for 2017, the most recent year for which such information is available.

Details are at the EurObserv’ER website, https://www.eurobserv-er.org/category/all-annual-overview-barometers/.

7 This is an IRENA estimate based on the all-solar (PV, solar heating and cooling, and concentrated solar power) estimate of 242 300 jobs published by Solar

Foundation, 2019.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

LIQUID BIOFUELS

The leading bioethanol producers all reached new

output peaks in 2018. Biodiesel production also

rose in many of these countries, but declined in

Argentina and the European Union, and remained

level in Australia, China, Malaysia and the Philippines

Worldwide employment in biofuels is estimated at

2 million, an increase of 6% from 2017. Most of these

jobs are generated in planting and harvesting of

feedstock. Fuel-processing facilities tend to oer fewer

jobs than does feedstock supply, but those jobs typically

require higher technical skills and oer better pay.

Annual changes in biofuels employment, notably, do

not always equate to net job gains or losses. Oil palm,

soybean, corn, and other feedstocks are used for a

range of agricultural and commercial purposes outside

the energy sector, and their end-use may therefore

vary from year to year without people losing jobs. On

the other hand, when people are displaced from their

land by expanding biofuels plantations, agricultural

livelihoods may be lost irretrievably.

The regional proﬁle of biofuels employment diers

considerably from that of the solar PV sector. Latin

America accounts for half of all jobs worldwide,

whereas Asia (principally labour-intensive Southeast

Asian feedstock supply) accounts for 23%, North

America for 16% and Europe for 10%. Figure 7 includes

the top 10 countries, which together account for about

91% of global estimated employment.

With 832 000 jobs, Brazil has the world’s largest

liquid biofuel workforce. Record production drove

up employment in the United States to more than

8 The 2018 production estimates are derived from the national biofuel reports published by the US Department of Agriculture’s Foreign Agriculture Service,

available at https://www.fas.usda.gov/commodities/biofuels.

FIGURE 7: TOP 10 COUNTRIES FOR EMPLOYMENT IN LIQUID BIOFUELS

Brazil

United States

Colombia

0.9

0.8

0.3

0.2

0.1

Million jobs

Indonesia

Thailand

Malaysia

China

India

Romania

Poland

Top 10:

91% of

total biofuels

jobs

40%

of biofuel

jobs

Source: IRENA jobs database.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

311 000 jobs. Biofuel employment in the European

Union was estimated at 208 000 jobs in 2017, the most

recent year for which data are available (EurObserv’ER,

2019).

For Southeast Asian producers, IRENA uses an

employment-factor calculation that distinguishes

labour requirements at plantations and smallholder

farms. Backed by rising output (USDA-FAS, 2018a),

Indonesia’s biodiesel sector is estimated to employ

237 000 people in 2018, a 12% gain

. In Malaysia, the

Philippines and Thailand, IRENA estimates a combined

workforce of some 176 000 people

Colombia’s biofuel output rose to a new peak of about

1.1 billion litres in 2018 (USDA-FAS, 2018b). Employment

factors based on data published by Federación Nacional

de Biocombustibles de Colombia (FNBC, n.d.) suggest

the number of people active in biofuels may have been

as high as 202 000 jobs in 2018, but could include

some part-time employment not converted to full-time

equivalents.

WIND

Most of the wind industry’s activity still occurs on land.

The 540 GW of cumulative onshore capacity compares

with about 23 GW in oshore projects (IRENA, 2019b).

But oshore is gaining traction, receiving USD 25.7

billion of investments in 2018, or 20% of the wind total.

For the ﬁrst time, China led the way with oshore

projects worth USD 11.4 billion. European projects

attracted spending of USD 3.3 billion (Efstathiou, 2019).

Oshore wind farms tend to require more labour inputs

than onshore projects. In addition to the construction,

assembly, and deployment of new equipment such

as platforms, they can leverage existing technical

capacities and skills (IRENA, 2018) and use converted

and upgraded existing infrastructure from the oshore

oil and gas and shipping industries (Froese, 2018).

Oshore wind development in northern Europe, for

example, utilises the expertise of workboats that

provide surveying, lifting and other services, and draws

on the know-how of companies that build foundations

for production platforms (O’Connell, 2018).

Together, onshore and oshore wind employ

1.16 million people worldwide, up 1% from 2017

. Most

wind jobs are found in a small number of countries,

although the concentration is less than in the solar PV

sector. China accounts for 44% of the global total; the

top ﬁve countries represent 75%. The regional picture

is also more balanced than in the solar PV industry.

Asia’s 620 000 wind jobs make up about half the total,

while Europe accounts for 28% and North America for

10%. Of the top 10 countries shown in Figure 8, ﬁve are

European, three are Asian, and one each is from North

and South America.

China remained the leader in new installations during

2018, adding 20 GW, of which 1.8 GW oshore (IRENA,

2019b). The country’s total wind employment was

estimated to hold steady at 510 000 jobs (CNREC,

2019), followed by Germany (140 800 jobs) and the

9 The calculation relies on revisions of an employment factor initially developed by APEC (2010). This factor is applied as a constant each year for smallholder

production, which accounts for 45% of volume (WWF, 2012) and is more labour intensive than large-scale plantations. For plantations, IRENA applies an

assumed “decline” factor of 3% per year as a proxy for rising labour productivity.

10 In Thailand, IRENA estimates 111 000 jobs. Smallholders have a 73% production share, an average of values reported by Termmahawong (2014) and by RSPO

(2015). In Malaysia, smallholders account for roughly 35% of production (WWF, 2012). IRENA estimates 28 600 jobs in Malaysia, and 36 600 jobs in the Philippines.

Analysing only the construction and operations of biofuels processing facilities, the Philippine government estimates direct employment of 2 328 jobs.

11 The countries for which IRENA’s database has estimates of wind power employment represent 561 GW of cumulative installations, or 99.6% of the global total.

They also cover 99.3% of the 49 GW of new installations in 2018.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

United States, where wind employment grew 8% to a

new peak of 114 000 jobs (AWEA, 2019).

Based on EurObserv’ER (2019) and national-level

reports, IRENA estimates European employment at

314 200 jobs in 2017, the year with the latest available

data. The continent’s cumulative capacity reached

189 GW in 2018 (Wind Europe, 2019b). Europe is not

only a leader in domestic installations but also holds a

strong position in exports of turbines and foundations.

In Denmark, export sales support the majority of wind

manufacturing jobs (EurObserv’ER, 2019).

FIGURE 8: TOP 10 COUNTRIES FOR WIND EMPLOYMENT

China

Germany

India

United States

United Kingdom

Philippines

Denmark

Brazil

Spain

France

0.55

0.50

0.45

0.20

0.15

0.10

0.05

Million jobs

Top 10:

85%

of wind

jobs

44%

of wind

jobs

Source: IRENA jobs database.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

FIGURE 9: HYDROPOWER CAPACITY, TOTAL AND RELATIVE TO ALL

RENEWABLE ELECTRICITY CAPACITY, 2012-2018

100

1 200

1 150

1 100

1 050

1 000

950

Share of hydropower of total

renewable energy capacity (%)

Cumulative hydropower

capacity (GW)

2012 2013 20152014 2016 2017 2018

Installed capacity

Source: IRENA, 2019b.

Previous editions of Renewable Energy and Jobs provided separate employment estimates for small

and large hydropower. However, dierentiating between them is dicult because of the scarcity of

data and for lack of a universally agreed threshold (set variably by dierent countries at 10, 20, 30

and even 50 MW).

This edition combines both. The total is calculated by IRENA with the help of an econometric model

based on capacity data, employment factors, and various national estimates and statistics.

HYDROPOWER

Of all renewable energy technologies, hydropower

continues to have the largest installed capacity. In 2018,

it accounted for almost 50% of renewable energy in the

world, but the share has declined as other renewables,

in particular solar PV and wind, have grown faster than

hydropower (Figure 9).

The analysis suggests that in 2018, over 2 million people

were directly employed in the hydropower sector

worldwide. Although the pace of new construction in key

markets has slowed, the sector nonetheless experienced

a growth of 3% over the previous year (Figure 10).

The distribution of employment across dierent

segments of the value chain remains similar to previous

years. More than 70% of the jobs are in operations and

maintenance. Construction and installation represent

23% of the total; manufacturing is characterised by

lower labour intensity and contributes just 5%.

Employment shares by country in 2018 provide

interesting insights (Figure 11). India’s labour-intensive

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

hydropower sector is the largest employer, accounting

for 17% of the total, followed by China (15%) which

experienced a decline in new installations. Brazil, where

hydropower provides 77% of electricity supply (IRENA,

2019b), accounts for 10 % of the total. Other large

players are Viet Nam (6%), Pakistan (5%), the European

Union and the Russian Federation (4% each), and Iran

(Islamic Republic of) and the United States (3% each).

FIGURE 11: HYDROPOWER EMPLOYMENT

BY COUNTRY, 2018

Rest of

the World

Brazil

India

34%

17%

15%

10%

United States

Iran (Islamic

Republic of)

Viet Nam

China

Russian Federation

European Union

Pakistan

Source: IRENA jobs database.

FIGURE 10: HYDROPOWER EMPLOYMENT, 2014-2018

2.5

2.0

1.5

1.0

0.5

Million jobs

2014 2015 2016 2017 2018

2.04

2.16

2.06

1.99

2.05

Source: IRENA jobs database.

Note: Employment in hydropower is derived from a macroeconomic model and adjusted with national and regional data.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

SOLAR HEATING AND COOLING

Major solar heating and cooling markets, including

China and Brazil, continued their downward trend in

2018, while India and several other markets showed

increased activity (Malaviya 2019; Zhang 2019;

Sother 2019). IRENA’s estimates indicate that global

employment in the sector declined to 801 400 jobs.

The top ﬁve countries account for 93% of all jobs. Asia is

home to 711 000 jobs, 88% of the world total. Of the top

10, three countries are from Asia and three from Europe.

Estimates for China suggest that employment held

steady in 2018 from the previous year (CNREC, 2019).

With more than 70% of global installed capacity and

a strong position in export markets, the country also

remains dominant in employment. In cumulative terms,

the US is the second largest national market, followed

by Turkey, Germany, Brazil, India and Australia (Weiss

and Spörk-Dür, 2018).

According to Eurobserv’ER (2019), the number of

people working in the industry in the European Union

declined from 29 000 in 2016 to 21 900 in 2017 (the

latest year for which data are available)

. In the United

States, employment was estimated by IRENA at

12 100 jobs in 2018.

Brazil and Turkey are among the key markets. The

Brazilian market dropped by 1.1% in 2018, the third

straight year of reductions (ABRASOL, 2019). IRENA’s

employment-factor-based estimates

suggest that the

country’s employment in this sector also fell slightly,

to about 40 630 jobs. Turkey reported a major loss

of employment, with the number of jobs down to just

8 660 in 2018 from 16 600 in 2017 (Akata, 2019).

India had the sixth-largest installed capacity in 2017.

IRENA’s employment-factor calculation suggests that

the country may have employed some 20 700 people

in 2018, when annual collector additions reached a

new peak of almost 1.8 million square metres. However,

since imports of Chinese-manufactured equipment have

captured a growing share of the market, this calculation

may over-estimate domestic jobs (Malaviya, 2019).

12 Eurobserv’ER does not differentiate between solar heating and cooling and concentrated solar power. National-level reports suggest a higher figure of

29 300 in 2017. For Spain, APPA (2018) puts employment at 6 200, lower than the 8 100 reported by Eurobserv’ER. For the United Kingdom, REA (2018)

offers a much higher figure of about 9 500 jobs compared with the 200 jobs estimated by Eurobserv’ER.

13 IRENA uses an employment factor of one full-time job per 87 square metres (m

) installed, as suggested by IEA SHCP (2016).

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

RENEWABLE ENERGY

EMPLOYMENT:

FOCUS ON ACCESS

Renewable energy plays an increasingly important

role for improving energy access. Global renewable o-

grid capacity more than doubled in the past decade,

to 8.8 GW in 2018; o-grid solar PV expanded 10-fold,

to 2.9 GW (IRENA, 2019b).

In South Asia, public sector programmes have had a

strong role in improving energy access. By contrast,

private sector “pay-as-you-go” (PAYG) business

models predominate in Sub-Saharan Africa (see

Box 2). Worldwide, investment in private off-grid

ventures grew from USD 10 million in 2010 to USD

511.5 million in 2018, for a cumulative USD 1.7 billion.

Nearly four ﬁfths of the money went to Sub-Saharan

Africa, compared with 15% to South Asia and 5% to

Latin America. The top 10 firms, including Zola,

M-KOPA, d.light, Mobisol, BBOXX, and others, secured

two thirds of the total investment (St. John, 2019).

Information remains relatively sparse on the full

employment impacts of o-grid renewable projects.

Some 130 million o-grid solar lanterns, SHS, and

other products had been sold worldwide by 2017

(Dalberg Advisors and Lighting Global, 2018). Through

the use of sales data, survey information from close

to 40 companies and in-depth interviews, GOGLA

and Vivid Economics (2018) estimated direct o-grid

solar employment in parts of Sub-Saharan Africa and

in South Asia at 372 000 full-time equivalent jobs (see

Figure 12). Some 56% of these jobs are located in rural

areas and 27% are ﬁlled by women.

This employment estimate covers sales and distribution,

installation and maintenance, and customer support,

but excludes manufacturing and assembly. The jobs

span a wide skills spectrum across sales, management,

ﬁnance, logistics, engineering, technical support and

software development. Cash-based transactions

typically create more employment in the sales and

distribution segments, whereas the PAYG model

relies more on technical jobs such as software design,

BOX 2. PAY AS YOU GO

Companies operating under the PAYG model are

creating growing numbers of jobs (IRENA, 2016).

A recent example is BBOXX’s contract under the

Democratic Republic of Congo’s “Energie pour Tous”

rural electriﬁcation initiative to provide energy access

through solar home systems (SHS) and mini grids to

2.5 million people by 2020. This venture could create

some 10 000 jobs (Tisheva, 2018).

However, the bankruptcy of Mobisol in April 2019

raises a cautionary note. Aordability is key, as prices

and payment schedules are typically set to match

households’ cash ﬂow. Customers make regular

micropayments over a period of one, two or more

years. Given the need for upfront ﬁnancing, the model

relies on continuous injections of capital for deploying

additional systems.

Rising disposable incomes will grow the o-grid

market. But PAYG companies need to adjust in

the face of the rapidly falling costs of new solar

products and growing competition from new

market entrants (Dizard, 2019).

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

logistics, and customer service. In general, wages in

o-grid solar are substantially higher than the average

wages in the countries where these jobs are created

(Vivid Economics, 2019).

Additional analysis is needed to gain a more ﬁne-

grained understanding of the socio-economic impacts

in dierent countries. In 2018, Power for All launched

an annual jobs census on the decentralised renewable

energy (DRE) sector in low-energy access countries

(Power for All, 2018). It covers a wide range of solar

technologies. Initially focused on Kenya, India and

Nigeria, the geographic scope is to expand to 10

countries in 2019 and 25 the following year. The study

surveys nearly 150 DRE organisations and includes

focus group discussions with stakeholders from

government, the skills and training sector, civil society,

ﬁnance, and industry (Power for All, 2019).

The research analysis, to be released later in 2019,

will yield valuable insights on total DRE employment,

permanency of jobs and levels of compensation, current

skill demand, recruitment challenges, and gender and

youth representation. The study maps areas of indirect

employment impacts in upstream activities such as

equipment suppliers, or service providers such as

training and education (Power for All, 2019).

Direct or indirect formal jobs are only the tip of the

iceberg of the DRE sector’s employment impact. In

emerging economies, the informal sector is a major

driver of the economy

. According to the survey

and sector experts, companies selling SHS and solar

lanterns are heavily dependent on a large network of

informal workers such as ﬁeld technicians and sales

agents to distribute their products (Power for All, 2019).

Another key area of the DRE sector’s employment

impact is among rural DRE end-users. Newly acquired

or improved energy access can beneﬁt rural business

performance, free up workers’ time, encourage more

studying hours for children, and create or enhance jobs

as a result. Despite the lack of systematic reporting of

induced jobs as an impact metric, 71% of the literature

studying productive use impact found increased

employment from energy access (Willcox et al., 2015).

A 2018 study (GOGLA and Altai Consulting, 2018)

found that 7% of households owning an SHS reported

that ownership of such a system had enabled a

family member to take on a new job. Among 44%

of households, an SHS also unlocked more time for

people to work, and 24% of households use the energy

generated directly in a business or other income-

generating activity.

Most developing economies have ambitious

electriﬁcation goals that necessitate rapid expansion of

DRE solutions. Kenya’s National Electriﬁcation Strategy

established a goal of 100% electriﬁcation by 2022; in

Nigeria, a total capacity of 8 GW of DRE solutions is

needed to achieve its 30:30:30 Vision (World Bank,

2018b; Federal Republic of Nigeria, 2016). Based on

an analysis of energy access policies, the Power for

All study estimates future job creation potential and

demand for talent. With a demand for more than two-

thirds of its workforce skilled, the DRE workforce is

facing a skills gap that is no longer a future threat but a

challenge today.

FIGURE 12: DIRECT EMPLOYMENT IN OFF-GRID

SOLAR, 2018 AND 2022

262

350

150

745

2018 2022 (proj.)

1.400

1.200

1.000

800

600

400

200

Thousand Jobs (Full-time equivalent direct employment)

South Asia

Central Africa

West Africa

East Africa

Source: GOGLA and Vivid Economics, 2018.

14 In India, 88.2% of the employed population are informal workers, 82.7% in Kenya and 92.9% in Nigeria (ILO, 2018; World Bank, 2016).

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

1 235

719

267

1125

855

4 078

China

North

Africa

Rest of

Africa

South Africa

Jobs (thousands)

India

Japan

Brazil

United States

of America

Germany

291

million jobs in 2018

227

FIGURE 13: RENEWABLE ENERGY EMPLOYMENT IN SELECTED COUNTRIES

RENEWABLE ENERGY

EMPLOYMENT IN

SELECTED COUNTRIES

This section presents key country-level trends and

observations. It ﬁrst discusses leading countries –

China, Brazil, the United States, India, and members of

the European Union (see Figure 13) – and then presents

information on additional countries by region. Overall,

the bulk of renewable energy employment is in Asian

countries, which accounted for 60% of jobs in 2018.

Source: IRENA jobs database.

Disclaimer: Boundaries and names shown on this map do not imply any official endorsement or acceptance by IRENA.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

LEADING MARKETS

CHINA

39% of global renewable energy jobs

Solar PV: 2.2 million jobs

Solar Water Heating: 670 000 jobs

Wind: 510 000 jobs

China remains the clear leader in renewable energy

employment worldwide, accounting for 39% of the

world’s total. The country’s total number of jobs, at

4.1 million, dipped below last year’s level (CNREC, 2019).

In large part, this reﬂects the drop in solar PV from

2.216 million jobs to 2.194 million (CNREC, 2019). In

May 2018, the government announced that it was

suspending advantageous arrangements for utility-

scale solar, imposing a cap on subsidised distributed

solar, and reducing feed-in taris in response to

continuous growth in solar subsidies. Subsidies had

expanded in part because the authority that approves

solar farms was delegated to the local level in 2013,

making policy coordination dicult (Bin, 2018).

The country installed 43 GW of solar PV during 2018, 18%

less than the previous year. Although rooftop PV saw

gains, utility-scale deployment dropped signiﬁcantly.

Overall production of solar PV modules still grew by

21% in 2018 to 87 GW (Yuanyuan, 2019), but substantial

overcapacities in the supply chain led to some factory

closures and layos (Hutchins, 2018; Lin, 2018).

Osetting lower domestic sales to a large extent,

exports rose by 30%, to about 41 GW, during 2018.

PV exports to emerging markets are being promoted

through China’s newly unveiled International

Investment Alliance for Renewable Energy

. Chinese

PV manufacturers are also increasing their global

footprint, with production facilities in close to

20 countries (Yuanyuan, 2019).

Employment in the Chinese solar water heating industry

held steady at 670 000 jobs. Following a sharp drop in

new domestic capacity additions in 2014 from a peak of

close to 45 GW

, subsequent years saw more marginal

reductions; in 2018, 24.8 GW

was added (Zhang, 2019).

However, these small reductions in market volume are

not assumed to have translated into job losses. Changes

in the product mix and greater eorts to integrate such

technology into buildings have required additional

labour inputs that oset volume reductions.

China’s 2018 wind employment is estimated at 510 000

jobs, roughly the level of the previous year. Although

the pace of new installations picked up (IRENA, 2019b),

policy changes (such as more competitive bidding

processes and subsidy cuts) may have discouraged

companies from additional hiring. Meanwhile, the strong

growth in the oshore segment did not fully translate

into more domestic jobs, as imported components play

a greater role than they do for onshore projects.

BRAZIL

Largest biofuels employer

Biofuels: 832 000 jobs

Solar Water Heating: 41 000 jobs

Solar PV: 15 600 jobs

Wind: 34 000 jobs

In Brazil, the biofuels sector remains the most important

renewable energy employer. Output of fuel ethanol

rose to record levels in 2018, and plans are to increase it

further from 27.8 billion litres to 47.1 billion litres in 2028.

Biodiesel production of 5.4 billion litres also hit a record

in 2018 (ABIOVE, 2019), driven by a rise in the biodiesel

blend to 10% (USDA-FAS, 2018c). Output is expected to

double to 11.1 billion litres over the next decade. To meet

these targets, new ethanol and corn mills and soybean

15 The Alliance is a joint initiative by the National Development and Reform Commission, the National Energy Agency, the Ministry of Commerce and the

Chinese Chamber of Commerce, and includes PV module manufacturer Jinko, and other Chinese PV and wind manufacturers, as well as companies specialis-

ing in engineering, planning and construction or operations and maintenance (Enkhardt, 2018).

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

oil extracting plants are needed; these could create

an additional 1.4 million jobs over the coming decade

(USDA-FAS, 2018c). Biodiesel employment rose to

an estimated 257 000 jobs in 2018

, while ongoing

mechanisation of the feedstock supply chain caused

bioethanol jobs to decline to about 575 000 jobs in 2017

New additions to Brazil’s wind power generating capacity

ran to 2.1 GW in 2018, the ﬁfth-largest amount worldwide

(IRENA, 2019b), bringing cumulative capacity to 14.7 GW.

More than 85% of this capacity is located in the northeast.

The wind sector can bring industrial development and

job creation to an area with comparatively low economic

development, but skills deﬁcits are an obstacle to local

hiring (ABEEólica, 2019; Lucena and Lucena, 2019).

IRENA estimates the country’s wind workforce at close

to 34 000 people

. Roughly one third of the jobs are in

manufacturing, 42% in construction, and the remainder

in operations and maintenance.

Trade statistics suggest that in 2014, domestic content

in Brazil’s wind energy manufacturing sector was about

89%

(CEMAC, 2017; CEMAC, n.d.). Brazil’s national

development bank BNDES oers subsidised loans if

developers meet local content requirements of 65%.

Over the years, this requirement has stimulated the

emergence of a domestic supply chain of more than

300 companies

(Cu, 2018; Ferreira, 2017). Among

the foreign manufacturers investing in Brazil, LM Wind

Power’s blade facility in the Suape Port Complex of

Pernambuco today employs nearly 900 people (Suape,

n.d.; LM Wind Power, 2018).

New installations in Brazil’s solar heating market

declined by 1.1% in 2018, and employment is estimated

to have declined, to 40 630 jobs (ABRASOL, 2018)

But the country is ramping up activities in solar PV,

installing 828 MW of large-scale capacity and 318 MW

of distributed capacity during 2018. In operation since

mid-2018, the country’s 399 MW Pirapora solar complex

in Minas Gerais is one of Latin America’s largest, and

uses domestic modules (Power Technology, 2018).

IRENA’s employment factor calculations suggest that

Brazil presently has close to 15 600 jobs in solar PV,

mostly in construction and installation. According to

the industry group Associação Brasileira de Energia

Solar Fotovoltaica, about 1 GW of capacity will likely

be installed during 2019, and ABSOLAR projects that

15 000 new jobs could be created as a result (ABSOLAR,

2019a and 2019b).

16 The calculation is based on employment factors for different feedstocks (Da Cunha et al., 2014). The shares of feedstock raw materials are derived from

ABIOVE (2019). Soybean oil accounts for the bulk (about 70%), followed by beef tallow (16%) and cotton seed and vegetable oils (14%).

17 Employment data are not yet available for 2018. In 2017, Brazil had around 217 000 workers in sugarcane cultivation and 158 000 in ethanol processing (MTE/

RAIS, 2019). IRENA’s employment estimate also includes an estimate of 200 000 indirect jobs in equipment manufacturing, though the figure is rough and dated.

18 This calculation is based on employment factors published by Simas and Pacca (2014).

19 Net imports were USD 254 million, out of total value-added of USD 2 400 million that year.

20 Domestic firms are well-established in tower production, but less so in turbine manufacturing, which is more technologically demanding (WEG, established in

2012, holds a small turbine market share; it acquired expertise through technology transfer and benefited from incentive programmes for local wind technology

development, including an R&D programme by ANEEL (Agência Nacional de Energia Elétrica) and the Economic Subsidy for Innovation Programme operated

by FINEP (Financiadora de Estudos e Projetos) (Ferreira, 2017).

21 This IRENA calculation of installation jobs is based on Brazilian market data and a solar heating and cooling employment factor. The estimate for manufacturing

jobs is derived from an original 2013 estimate by Alencar (2013).

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

United States

Largest biofuels producer

Biofuels: 311 000 jobs

Solar: 242 000 jobs

Wind: 114 000 jobs

In the United States, the liquid biofuels, solar, and wind

industries are the largest employers in the renewable

energy ﬁeld. US biodiesel output rose 16% to about

7 billion litres in 2018 (EIA, 2019b), and our estimations

suggest that employment reached a new peak of

72 300 jobs. US ethanol production edged up slightly to

60.6 billion litres, with employment (direct and indirect)

estimated at 238 500 jobs. In addition, economic

modelling suggests that induced jobs, supported by

income spent by employees in the bioethanol supply

chain, number about 127 300 (Urbanchuk, 2019).

Solar experienced a second consecutive year of job

loss, down to 242 300

. Two-thirds of these jobs are

in installations and project development (mostly in

the residential market). Manufacturing accounts for

14% (Solar Foundation, 2019). Domestic US module

production has ﬂuctuated over the years, but the vast

majority of shipments are imported (EIA, 2019a).

Uncertainty surrounding US tari policy delayed several

utility-scale projects

. State-level policy changes in

California and Massachusetts also dampened activity

(Solar Foundation, 2019). New project announcements

surged once the uncertainty over taris had lifted.

Also, the Chinese government’s decision in May to cut

domestic solar incentives had the eect of reducing

global demand for modules; the resulting over-supply

lowered prices worldwide and counteracted the impact

of the taris (Foehringer Merchant, 2018). As foreign

suppliers continue to set up domestic manufacturing

facilities (Roselund, 2019), taris become a less

important factor.

Beneﬁting from the market stability aorded by the

December 2015 extension of the Production Tax Credit

(BNEF and BCSE, 2019), the US wind industry added

about 7.6 GW during 2018, raising cumulative capacity

to 96.4 GW or almost four times as much as a decade

earlier (AWEA, 2019). Employment rose 8% in 2018 to

114 000 jobs (AWEA, 2019).

Listed in order of magnitude, employment in the

construction and installation segment and in operations

and maintenance is concentrated in Texas, Oklahoma,

Iowa, California, and Kansas. Most manufacturing

jobs are located in seven states: Ohio, Texas, Illinois,

Pennsylvania, Wisconsin, North Carolina, and Michigan.

Wind projects induce additional economic activity, and

employment, through USD 761 million in annual state

and local tax revenues and USD 289 million in land lease

payments (AWEA, 2019).

22 This figure includes jobs in solar PV, solar heating and cooling, and concentrated solar power. A solar job is defined as one held by a worker spending at least

50% of his or her time on solar-related work. Census findings indicate that about 90% of these workers spend all of their time on such work. An additional

92 650 employees spent less than half their time on solar-related work. The 2018 edition of the Solar Jobs Census includes two job categories not covered

in previous editions. The first concerns the territory of Puerto Rico, which has roughly 2 000 jobs. There are also 3 900 battery storage-related jobs in 2018.

Adding these brings the US total to 248 200.

23 In April 2017, two solar manufacturers petitioned the U.S. International Trade Commission to impose tariffs on all imported crystalline silicon solar modules

and cells. Tariffs were imposed in January 2018.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

INDIA

719 000 jobs

Hydropower: 347 000 jobs

Solar PV:

115 000 jobs (Grid-connected)

Wind: 58 000 jobs

In India less utility-scale capacity was added in 2018

than in 2017, but rooftop installations expanded by 66%.

By late 2018, cumulative capacity in the utility-scale

segment was 24.4 GW, 3.8 GW in rooftop, and 0.8 GW in

o-grid solar (Mercom India Research, 2019; Kenning,

2018b).

Auctions have pushed solar power taris to record lows.

While this has generally led to higher installations in recent

years, the resulting intense competitive pressure has led

project developers to choose low-cost components

over quality, sometimes cutting corners to win bids

(Sushma, 2018). An analysis of six representative plants

— conducted in collaboration with Indian government

agencies — highlighted the importance of a well-trained

(and by implication well-remunerated, thus higher-cost)

workforce to guarantee installations and operations of

sucient quality (GIZ, PTB, and PIB, 2017).

India’s employment in grid-connected solar PV, as

estimated by IRENA using employment factors,

increased to 115 000 jobs in 2018, a gain of more than

20 000. Jobs in o-grid solar applications cannot be

calculated with precision but may well double total solar

employment.

Seven of India’s top 10 module suppliers are Chinese

ﬁrms. Indian manufacturers cannot compete on

cost, and many have limited access to low-cost

loans. Imports, principally from China

and Malaysia

but increasingly also from Thailand, Viet Nam, and

Singapore

, dominate the Indian market. In ﬁscal year

2018, domestic manufacturers had a market share of

just 7% (Singh, 2019).

China is also becoming a leading force in the Indian

inverter market. Replacing ABB (a Swiss-Swedish ﬁrm)

and Japan’s TMEIC as the leading suppliers, Huawei and

Sungrow garnered a combined 31% share in 2017/18.

Indian companies retain a much stronger foothold in

solar project development, accounting for eight of the

top 10 ﬁrms, and in the engineering, procurement and

construction segment, where they represent six of the

top 10 (Kenning, 2018a).

The Indian government has sought to craft workable

policies in support of local manufacturing. Safeguard

taris imposed in mid-2018 on imports from China

and Malaysia were eectively oset by falling prices

(Beetz, 2018b). A 10 GW manufacturing-linked tender

by Solar Energy Corporation of India failed due to

low tari ceilings, safeguard duties, and other factors

(Gupta, 2019). Viability gap funding of USD 1.2 billion

for 12 GW worth of projects mandates that all modules

and 40% of other components for grid-connected

projects be domestically manufactured; for o-grid

projects, the requirement was set at 70% (Gupta,

2018b; Verma Lal, 2019).

India came in fourth in wind generating capacity

additions in 2018, but the pace of 2.2 GW was down

substantially from 4.1 GW the previous year (GWEC,

2019). The sector is adjusting to the switch from

preferential taris to an auction model (Kenning,

2018a). IRENA estimates that employment in the sector

stood at 58 000 at the end of the year.

24 China accounted for 89% of imports in the last financial year. In 2017, India became China’s largest foreign solar PV market with a 31% share of total exports

(Upadhyay, 2018). The volume of Chinese sales in India rose almost eight-fold between 2014/15 and 2017/18, to about 9.8 GW (Verma Lal, 2018).

25 To sidestep trade barriers imposed by the European Union and the United States, Chinese solar companies set up manufacturing capacities in Southeast Asia:

12 GW in PV cells and 14 GW in modules (Upadhyay, 2019).

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

EUROPEAN UNION

1.2 million jobs

Solid biomass: 387 000 jobs

Wind: 314 000 jobs

Solar PV: 96 000 jobs

In 2017, the most recent year for which data are

available, the total number of renewable energy

jobs in member countries of the European Union

was estimated at 1.2 million (EurObserv’ER, 2019)

This is virtually unchanged from the previous year

but conceals ﬂuctuations among technologies and

countries. Five countries — Germany, Spain, France,

the United Kingdom, and Italy — top the job rankings

in most renewable energy sectors. Employment grew

in liquid biofuels but declined in all other renewables

industries.

Heat and electricity derived from solid biomass

supported approximately 387 000 jobs in 2017.

The biofuels sector employed about 230 000, up 12%

from 2016. The countries with the largest agricultural

supply chains have the bulk of the jobs, including

Romania, Poland, Spain, France, and Hungary

(EurObserv’ER, 2019).

IRENA estimates EU wind power employment in 2017 at

about 314 200 jobs, down somewhat from the previous

year

. The United Kingdom, Germany and Denmark

are among the global leaders in this industry (including

its oshore component, where Europe now has a

cumulative capacity of 18.5 GW (Wind Europe, 2019a).

From just under 100 000 jobs, European solar PV

employment dipped slightly to 95 600 in 2017,

reﬂecting the diversiﬁcation of the supply chain, rising

labour productivity, and reduced domestic installation

rates. Solar thermal employment

also contracted as

a result of restrictive policies and regulations as well as

competition from gas-ﬁred heating and heat pumps,

dropping from almost 40 000 jobs to 29 300.

A recent study (EY, 2017) concluded that greater

ambition (raising the EU renewable energy target from

27% to 35%

) and proper policy support could raise PV

employment to 175 000 jobs by 2021. Most of the added

employment would be in installations and in operations

and maintenance, which are more labour intensive than

manufacturing.

Greater employment may also be possible in

manufacturing (where wages tend to be higher),

according to the newly-founded European Solar

Manufacturing Council (ESMC, 2019). Meanwhile, a draft

industrial policy was submitted by SolarPower Europe

to the European Commission. It envisages a 20% solar

share in electricity usage; accelerating utility-scale

deployment and installing at least 30 million solar roofs

by 2030; boosting building-integration for PV; and

pursuing solar-based sector coupling. It calls for 5 GW

of solar PV module manufacturing capacity in Europe,

supported by state aid and by easier access to ﬁnancing

and land (Beetz, 2018d). The association expects that

such a policy could triple European solar employment to

300 000 jobs (SolarPower Europe, 2019).

26 The EU total, along with the estimates for individual renewable energy technologies, is based on EurObserv’ER (2019) and adjusted with national data in

the cases of Spain (APPA, 2018) and the United Kingdom (REA, 2018). In some cases, notably, differences in econometric modelling methodologies used

by the cited sources generate widely differing employment estimates.

27 EurObserv’ER (2019) offers a much higher estimate for Spain than APPA (2018): 37 200 jobs compared with 20 500. EurObserv’ER (2019) also presents

a much higher figure for the United Kingdom than the Renewable Energy Association (2018): 69 900 jobs versus 44 100.

28 Including solar heating/cooling and concentrated solar power technologies.

29 In 2014, the European Union adopted a renewable energy target of at least 27% of final energy consumption by 2030, up from the previous 20% target for 2020.

In mid-2018, a compromise was reached to raise the 2030 target to 32%, with an interim review set for 2023.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

Germany has Europe’s largest renewable

energy workforce. Following some years of

job loss, the number rose from 283 100 in

2016 to 290 700 in 2017 (Eurobserv’ER, 2019). Wind,

solar PV, solid biomass and biogas gained, while other

sectors still shed jobs. At 140 800 jobs the wind industry

represented almost half the country’s total renewables

workforce. Deviating from European trends, the

solar PV workforce expanded slightly, due to higher

domestic installations

(BSW, 2018) and export sales.

Germany accounts for almost half of Europe’s biogas

employment, but the local market is stagnant and

equipment manufacturers are relying more on export

sales (Eurobserv’ER, 2019).

The United Kingdom and France are among

Europe’s leaders in renewables. In the

United Kingdom, the Renewable Energy

Association (REA, 2018) put total employment at

110 900 jobs

for 2016/17, a slight uptick. Close to 40%

of all renewables jobs in the United Kingdom, ﬁlled

by some 44 140 people, are in wind power.

Oshore wind projects are helping to revitalise coastal

communities in the Humber and East Yorkshire regions,

the Isle of Wight, and other areas. A GBP 310 million

(USD 411 million) investment by Siemens Gamesa and

ABP in turbine assembly and blade manufacturing has

created about 1 000 direct and indirect jobs in Hull. The

more than 300 jobs in blade manufacturing at an MHI

Vestas Oshore Wind facility on the Isle of Wight are

to expand to 380 (plus 720 indirect and induced jobs)

(MVOW, 2018). A former oil-ﬁred power plant has been

converted into a paint and logistics facility for wind

blades (Whitmarsh, 2019).

Roughly two-thirds of the UK’s oshore wind supply

chain are located overseas, principally in Denmark,

Germany, the Netherlands and Belgium (Yang, 2019).

The government’s “Oshore Wind Sector Deal”

seeks to raise the domestic share to 60% (Pantry,

2019). The Oshore Wind Industry Council projects

that deploying up to 30 GW of capacity by 2030

could boost employment from 11 000 jobs to 27 000

(Whitmarsh, 2019). Women account for only 16% of the

workforce, but the share can be doubled by 2030 (HM

Government, 2019).

France is still a small player in the wind

sector, but employment is expanding,

supported by a diversiﬁed industrial base

that encompasses more than a thousand small and

large ﬁrms. According to the Wind Observatory 2018,

France had a total of 17 100 direct and indirect jobs

in the wind value chain, up 37% from 2014 (FEE and

BearingPoint, 2018 and 2017). Most employment in

2017 was in engineering and construction (about

5 000) and in planning and design (4 900), followed by

component manufacturing (3 800) and operations and

maintenance (3 400). Manufacturing employment has

remained unchanged since 2015, but other segments

have grown strongly. The 3 GW of oshore capacity

that is to be installed under the country’s ﬁrst tender

could create nearly 10 000 more jobs, and the 2030

target of 15 GW could generate up to 30 000 jobs

(Syndicat des Énergies Renouvelables, n.d.).

Specialising in dierent segments of the supply chain,

several regions have beneﬁted. Many head oces are

in the Paris basin, while planning and design ﬁrms are

primarily in the south (Occitanie). The northeast hosts

half the installed generating capacity and thus many

operations jobs. Most component manufacturing takes

place in Pays de la Loire and Grand Est. The traditional

industrial regions of Auvergne–Rhône-Alpes and

Bourgogne–Franche-Comté are also beginning to take

advantage of new opportunities. More than a dozen

industry clusters have emerged around the country

to facilitate innovation, knowledge-sharing and skill-

building (FEE and BearingPoint, 2018).

30 In 2018, new grid-connected installations reached 2.96 GW, up from 1.76 GW the previous year (Schmela, 2019). However, this remains far below the peak levels

achieved in the period 2009 to 2012, when about 7.5 GW were installed annually (BSW-Solar, 2016).

31 REA (2018) reports a total of about 9 800 jobs in the heat pump sector. However, including only ground source heat pumps (which most closely align with

the renewable energy sector), employment is more likely to be about 1 700 jobs. The UK total employment estimate includes this smaller estimate.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

OTHER COUNTRIES

In addition to the leaders in renewable energy

manufacturing and deployment, some countries are

expanding their presence, though others confront

various challenges. A number of countries in East and

Southeast Asia and in Oceania are rising to prominence

in solar PV.

Japan’s solar PV installations reached

55.5 GW in 2018, the second largest capacity

after China. However, the pace of new

installations declined for the third year in a row (IRENA,

2019b). The reasons include lower feed-in taris, land

shortages and grid constraints (Bellini, 2019). Close to

300 solar ﬁrms have declared bankruptcy since 2015,

with the number rising year after year (Teikoko Databank,

2019). IRENA estimates 2018 employment at some

250 000 jobs, a reduction of 22 000 from 2017

A fresh impulse for larger installations and more

jobs may come from the government’s “Zero Energy

Homes” policy, which requires new buildings to

integrate solar PV and energy eciency technologies

by 2030 (Publicover, 2019).

The Republic of Korea employs about

7 500 people directly in the manufacturing

and distribution of solar PV, slightly less

than the previous year. Altogether the country puts

renewable energy employment at 11 650 in 2018 (Korea

Energy Agency, 2019).

Foreign direct investment has turned

Malaysia into a major solar PV manufacturer

for export markets. The Sustainable Energy

Development Authority (SEDA, 2019) estimates that

the number of people working in solar PV in 2018 rose

to more than 54 300, from 40 300 jobs in 2017. Around

17 000 of these jobs are in component manufacturing

For other renewables, SEDA reports that solid biomass

and biogas employment declined slightly in 2018

to 9 400 jobs. IRENA’s employment factor-based

calculation yields an estimate of 28 600 jobs in the

biodiesel supply chain. Altogether, IRENA estimates

Malaysia’s renewable energy workforce to have grown

from 87 400 jobs in 2017 to 98 500 in 2018.

In contrast to Malaysia’s on-going solar

expansion, PV jobs in the Philippines

declined from 34 000 in 2017 to just

20 800 in 2018. Wind power contributes close to

16 900 jobs, solid biomass more than 11 000, and

geothermal power another 7 450 (Neri, 2019). IRENA

estimates biofuels employment at 36 600 jobs,

including informal jobs in the agricultural supply chain.

According to the Australian Bureau of

Statistics (ABS, 2019), direct, full-time

renewable energy employment stood at

17 740 jobs in the 2017/18 ﬁscal year, the highest level

since 2011/12. Rooftop PV employed 8 240 people.

Reﬂecting dierent methodologies and reporting

periods, Green Energy Markets (2019) puts the total

at 25 700 renewable energy jobs in 2018. This includes

wind power employment of 10 100 people in 2018,

almost 7 700 people in large-scale solar projects and

7 800 in rooftop solar.

32 In the absence of direct employment data, this calculation is based on the assumption that employment closely tracks the reduction in demand during 2018.

33 Including 520 jobs in silicon feedstock operations, 2 851 in ingot and wafer production, 9 660 in cell manufacturing, and 4 850 in module production

(IEA-PVPS, 2018).

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 201932

In the Americas, Canada has long had a

footprint in hydropower and biomass, but

wind is growing in importance, particularly in

the provinces of Ontario and Quebec. Wind contributed

6% to national electricity in 2018 (CANWEA, 2018). In

Quebec, the industry employs 5 000 full-time workers,

including 1 000 in the city of Montreal (CANWEA, n.d.).

Wind power has also helped to promote economic

development in the Gaspé peninsula, where an industrial

cluster of some 30 businesses comprises 1 000 direct

jobs (Quebec Wind Energy Cluster, n.d.). Among them

is a blade factory producing for the Canadian and US

markets. Its expansion brought employment to 450 in

2018 (LM Wind Power, 2017). The province of Alberta

has the third-largest installed capacity. A supply chain

study found that 4.5 GW worth of new projects could

result in about 14 900 job-years of employment by 2030,

spread among services (6 634), manufacturing (5 472),

construction (2 756), and operations and maintenance

(714) (CANWEA, 2017).

In Latin America, Mexico, Chile and Argentina

are among the largest actors after Brazil.

Solar PV capacity in Mexico quadrupled in

2018 to reach 2.5 GW.

In Argentina, progress in adoption of

renewable energy has been driven by

legislation. Law 27191 (October 2015), which

established a 2025 target of 20% renewables in total

electricity consumption, led to the implementation

of successful “Plan RenovAr” auctions and helped

mobilise private sector participation. Moreover, the

Renewable Energy Term Market (MATER) allows

renewable energy generators and large users to trade

renewable energy. As of March 2019, Argentina reports

9 614 people working in renewable energy, principally

in construction. This includes wind energy, with 5 343

jobs (just over half of the total renewables workforce),

and solar energy, with 2 555 jobs (Ministerio de Energía,

2019).

In the Middle East and North Africa region,

Turkey’s renewable energy workforce

declined to about 62 000 people in 2018

(Akata, 2019) under the combined eects of broad

economic dynamics, industry-speciﬁc developments

and diculties in securing project ﬁnancing (Guler,

2019; Tsagas, 2019). In solar PV, employment fell as

new installations dropped to 1.6 GW from 2.6 GW the

previous year, when the end of feed-in tari rates

triggered a year-end rush of new construction (Kavruk,

2019). Turkey requires a 60% local share in module

production, but many assembly plants are now closed

(Tsagas, 2019).

If ﬁnancing issues can be addressed, a wind power

tender issued in late 2018 could lift employment. The

new issue follows an initial 1 GW tender in 2017; the

winning bid by Siemens Gamesa and its local partners,

Kalyon Enerji and Turkerler Holding, included a

commitment to set up a nacelle factory to satisfy a 65%

local content requirement (O’Brian, 2018).

A number of large-scale wind and solar

projects will increase the share of non-

fossil energy and provide much-needed

employment in Egypt. The ﬁrst of a planned 41 plants

of the Benban solar complex opened in early 2019 and

employs some 650 people. Construction of the entire

complex is estimated to require more than 10 000

workers, while some 4 000 people perform operations

and maintenance activities (Reda, 2019).

A ﬁrst employment estimate from Iran

(Islamic Republic of) estimates that some

13 500 workers are employed in solar PV

and 7 100 in the wind power sector (Bagheri, 2019).

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

In Morocco, about 100 people are employed

at a new solar PV module factory in Al

Hoceima (Bellini, 2018). Most employment

to date has been generated at the Noor Ouarzazate

solar facility (consisting of three concentrated solar

power plants and one PV assembly) in the central

Drâa-Taﬁlalet region. Working closely with ANAPEC

(the National Agency for Employment and Capacity

Promotion), the Moroccan Agency for Sustainable

Energy has encouraged the use of local sta and

materials. Commitments by project owners were higher

than the required minimum (Stitou, 2019). On average,

the share of Moroccan nationals at Noor runs to 70%, of

which people from the local area represent somewhat

less than half (see Table 1).

Lower-skilled jobs were more common in construction

(46% of all construction jobs) than in operations (21%)

(Stitou, 2019). The share of women is in the single

digits. A 2017 study reported a high level of enthusiasm

among women about the projects, but concluded that

cultural norms, knowledge gaps about job options and

requirements, and skill gaps were key obstacles to

higher participation (World Bank, 2018a).

In Sub-Saharan Africa, direct employment

in projects under South Africa’s Renewable

Energy Independent Power Producer

Procurement Programme more than doubled from

17 800 job-years in 2014 to 36 500 by mid-2018.

The majority of these are held by people from local

communities. Some 85% of jobs were created in the

construction phase, the remainder in operations.

The programme has led to the emergence of a small

domestic wind and solar manufacturing industry

(Govender, 2019). For example, a 300 MW solar PV

module manufacturing facility set up by the Chinese

company Seraphim created 100 direct jobs. That

number is set to multiply as the plant expands (Beetz,

2018c). In the wind industry, tower manufacturing

plants were set up to satisfy local content rules. But a

foray into more complex blade-making did not succeed

owing to high quality requirements and companies’

perceptions that demand was insucient to justify local

production. Key nacelle components are imported.

TABLE 1. EMPLOYMENT AT MOROCCO’S NOOR OUARZAZATE FACILITY

Employees on site

Local share

commitment

Total Moroccan employees Local area employees

(percent) (number) (number)

(percent

of total)

(number)

(percent

of total)

Noor I 35 1 906 1 471 77 659 35

Noor II 40 4 063 2 723 67 927 23

Noor III 40 2 524 1 695 67 797 32

Noor IV 24 656 541 82 386 59

Combined - 9 149 6 430 70 2 769 30

Source: Stitou, 2019.

2011 2012 2013 2014 2015 2016 2017 2018 2019

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 201934

THE WAY FORWARD

As the global energy transformation gathers pace,

leaders and decision makers seek to maximise the social

and economic beneﬁts. Alongside decarbonisation and

climate goals, countries need to create jobs and spur

economic development.

IRENA’s annual jobs reports (see Figure 14) have

encouraged several governments, most recently

Argentina’s, to issue national estimates of renewable

energy employment. Going forward, IRENA intends to

work more closely with countries to collect knowledge

on the renewable energy workforce worldwide.

IRENA will continue to estimate the number of jobs in the

sector and analyse socio-economic impacts including

skill levels, jobs and workplace quality, and the degree

of gender equality. Policies to promote renewables must

be accompanied by industrial and labour policies aimed

at boosting supply chains, supporting local, national and

regional economic development and providing technical

and vocational training.

IRENA’s Leveraging Local Capacities studies further

assess skills and occupational requirements along the

renewables value chain. Further, IRENA is modelling

employment impacts in the REmap 2050 accelerated

uptake scenario and continues to highlight ways to

improve the gender balance in energy employment.

Gender is receiving greater national and international

attention. Overcoming gender gaps in electricity access

advances several Sustainable Development Goals.

Access to clean, aordable, renewable energy also

lowers barriers to women’s market employment (IEA,

IRENA, UNSD, WB, WHO, 2019).

IRENA noted links between SDG 7 (energy) and SDG 8

(jobs) for the UN’s 2018 High-Level Political Forum (UN

DESA, 2018). A new Energy and Jobs platform aims to

foster information exchange and raise awareness among

decision makers (see Box 3).

FIGURE 14. IRENA’S KNOWLEDGE BASE ON RENEWABLE ENERGY EMPLOYMENT

Renewable Energy and Jobs

December 2013

International Renewable Energy Agency

IRENA

IRENA woRkINg pApER

Renewable

Energy Jobs:

StAtUS, PROSPECtS & POlICIES

BIOfUElS AND gRID-CONNECtED

ElECtRICIty gENERAtION

Renewable Energy and Jobs

Annual Review 2014

MAY 2014

June 2012

Renewable Energy

Jobs & Access

Renewable Energy and Jobs

Annual Review 2015

2015

BOX 3. ENERGY AND JOBS PLATFORM

IIn 2019, IRENA initiated the Platform under the

umbrella of the SDG7 Technical Advisory Group

convened by the UN Department of Economic and

Social Aairs. Partners include the International

Labour Organization, the UN Industrial Development

Organization, the World Bank,

the European Commission, the

Global Green Growth Institute,

and Power for All.

Key goals include: Improving knowledge about

the forces shaping renewable energy job

creation; studying education and skills-training

needs along the supply chain; evaluating

opportunities to leverage domestic capacities;

analysing policies and approaches to ensure a

just transition; assessing the employment and

livelihood opportunities linked to energy access;

and highlighting the gender dimension.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

TABLE 2. ESTIMATED DIRECT AND INDIRECT JOBS IN RENEWABLE ENERGY WORLDWIDE,

BY INDUSTRY, 2017-18

Source: IRENA jobs database.

Note: Figures provided in the table are the result of a comprehensive review of primary national entities such as ministries and statistical agencies, and secondary

data sources such as regional and global studies. This is an on-going effort to update and refine available knowledge. Totals may not add up due to rounding.

Previous editions distinguished between small and large hydropower. Given changes in the available industry capacity data, this edition offers a single estimate

for all hydropower facilities.

Also in contrast to previous editions, this edition does not include country columns for Germany and Japan for lack of sufficiently up-to-date or detailed information.

a. Power and heat applications.

b. Traditional biomass is not included.

c. Direct jobs only.

d. Includes 8 600 ground-based heat pumps for EU countries.

e. Includes an estimate by GOGLA of 372 000 jobs in off-grid solar PV in South

Asia and in East, West, and Central Africa. South Asia accounts for 262 000

of these jobs. IRENA estimates Bangladesh’s solar PV employment at

135 000 jobs; most of the rest of the South Asian regional total is in India.

f. Includes 41 100 jobs in waste and 1 100 jobs in ocean energy, principally

reflecting available employment estimates in the European Union, as well as

7 600 jobs not broken down by individual renewable energy technology.

g. About 217 000 jobs in sugarcane cultivation and 158 000 in ethanol

processing in 2017, the most recent year available; also includes a rough

estimate of 200 000 indirect jobs in equipment manufacturing, and

256 900 jobs in biodiesel in 2018.

h. Includes 238 500 jobs for ethanol and 72 300 jobs for biodiesel in 2018.

i. Based on employment factor calculations for biomass power.

j. Based on an IRENA employment-factor estimate. Separately, NASEO and EFI

(2019) report direct geothermal power employment at just 8 526 in 2017-18.

k. Grid-connected solar PV only. Also see note e.

l. All European Union data are for 2017.

m. May include concentrated solar power for some countries.

Thousand jobs

World

China Brazil United States India

European

Union

Solar

Photovoltaic

3 605

2 194 15.6 225 115

Liquid

biofuels

2 063 51 832

311

35 208

Hydro power

2 054 308 203 66.5 347 74

Wind

power

1 160 510 34 114 58 314

Solar

heating/

cooling

801 670 41 12 20.7 24

Solid

biomass

a,b

787 186 79

58 387

Biogas 334 145 7 85 67

Geothermal

energy

a,d

94 2.5 35

CSP 34 11 5 5

Total

10 983

4 078 1 125 855 719 1 235

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

REFERENCES

ABEEólica (2019), Infowind, no. 9,

15 February, http://abeeolica.org.

br/wp-content/uploads/2019/03/

Infovento_ENG.pdf.

ABIOVE (Brazilian Association

of Vegetable Oil Industries)

(2019), “Biodiesel production by

raw material”, updated 12 March,

www.abiove.com.br/site/index.

php?page=statistics&area=MTAtMi0x.

ABRASOL (Associação Brasileira

de Energia Solar Térmica) (2019),

Communication with experts, April 2019.

ABS (Australian Bureau of Statistics)

(2019), “Employment in renewable energy

activities, Australia, 2017-18”, 17 April,

https://www.abs.gov.au/ausstats/abs@.

nsf/mf/4631.0.

ABSOLAR (Associação Brasileira de

Energia Solar Fotovoltaica) (2019a),

“Energia solar fotovoltaica ultrapassará a

marca de 3.000 megawatts no brasil em

2019”, 11 January, http://absolar.org.br/

noticia/noticias-externas/energia-solar-

fotovoltaica-ultrapassara-a-marca-de-

3000-megawatts-no-brasil-em-2019.

html.

ABSOLAR (2019b), “Energia Solar

Fotovoltaica no Brasil”, Infográﬁcao,

7 March, http://www.absolar.org.br/

infograﬁco-absolar-.html.

Akata, M. N. (2019), Communication with

experts, March.

Alencar, C. A. (2013), “Solar Heating &

Cooling Market in Brazil”, presentation at

Intersolar, September.

APEC (Asia-Paciﬁc Economic

Cooperation) (2010), “A study of

employment opportunities from biofuel

production in APEC economies”,

Singapore.

APPA (Asociación de Productores de

Energía Renovables) (2018), “Estudio del

impacto macroeconómico de las energías

renovables en España 2017”, Madrid.

AWEA (American Wind Energy

Association) (2019), US Wind Industry

Annual Market Report Year Ending 2018,

April, Washington, DC.

Bagheri, N. (2019), Communication with

experts, March 2019.

Ball, J. et al. (2017), The New Solar

System: China’s Evolving Solar Industry

and its Implications for Competitive Solar

Power in the United States and the World,

Steyer-Taylor Center for Energy Policy and

Finance, March.

Beetz, B. (2018a), “EU MIP decision to

have more eect on Indian PV market

than safeguard taris”, PV Magazine India,

19 July.

Beetz, B. (2018b), “Even with duties,

Chinese PV modules will be competitive in

India”, PV Magazine India, 2 August.

Beetz, B. (2018c), “Seraphim plans 1.5

GW solar module, 300 MW cell fab in

Africa”, PV Magazine, 13 August.

Beetz, B. (2018d), “SolarPower Europe

calls for 5 GW of EU solar module

manufacturing”, PV Magazine, 5

December.

Bellini, E. (2019), “FIT cuts and lower

revenue may cause more bankruptcies in

Japan”, PV Magazine, 1 February.

Bellini, E. (2018), “Ecoprogetti supplies

250 MW production line for Moroccan

bifacial module fab”, PV Magazine, 9

October.

Bin, L. (2018), “China’s solar industry is at a

crossroads”, China Dialogue, 13 August.

BNEF (Bloomberg New Energy Finance)

(2019), “Vestas leads break-away group

of big four turbine makers”, 14 February.

BNEF and BCSE (Business Council

for Sustainable Energy) (2019), 2019

Sustainable Energy in America Factbook,

Washington, DC.

BSW-Solar (Bundesverband

Solarwirtschaft) (2016), “Statistische

Zahlen der deutschen Solarstrombranche

(Photovoltaik)”, March, www.

solarwirtschaft.de/ﬁleadmin/media/

pdf/2016_3_BSW_Solar_Faktenblatt_

Photovoltaik.pdf.

BSW-Solar (2018), “Statistische Zahlen

der deutschen Solarstrom branche

(Photovoltaik)”, February, https://www.

solarwirtschaft.de/ﬁleadmin/user_upload/

bsw_faktenblatt_pv_2018_2.pdf.

CANWEA (Canadian Wind Energy

Association) (2018), “Installed capacity”,

https://canwea.ca/wind-energy/

installed-capacity/.

CANWEA (2017), “Alberta Wind Energy

Supply Chain Study”,

https://canwea.ca/wp-content/

uploads/2017/09/Delphi-AB-Wind-

Supply-Chain-Study-Final-Report.pdf,

September, Ottawa.

CANWEA (n.d.), “Social & Economic

Beneﬁts”, https://canwea.ca/wind-facts/

social-economic-beneﬁts/.

CEMAC (Clean Energy Manufacturing

Center) (2017), “Benchmarks of global

clean energy manufacturing”, https://

www.nrel.gov/docs/fy17osti/65619.pdf.

CEMAC (n.d.), “CEMAC: Benchmark

report wind trade ﬂow”, https://www.

manufacturingcleanenergy.org/

benchmark/wind.php.

CNREC (China National Renewable

Energy Centre) (2019), Communication

with experts, April 2019.

Cu, M. (2018), “Winds of change: The

shifting face of Brazilian energy”, Business

Green, 2 May, https://www.businessgreen.

com/bg/feature/3030800/

the-changing-face-of-brazilian-energy.

Da Cunha, M. P., Guilhoto, J. J. M.

and Da Silva Walter, A. C. (2014),

“Socioeconomic and environmental

assessment of biodiesel production

in Brazil”, The 22nd International

Input-Output Conference 14 18 July,

Lisbon, Portugal.

Dalberg Advisors and Lighting Global

(2018), “O-grid solar market trends

report 2018”, January, International

Finance Corporation, Washington, DC.

Dizard, J. (2019), “Mobisol: A cautionary

tale for impact investors”, Financial Times,

3 May.

Efstathiou, J. (2019), “Global clean

energy funding dips 8% as China cools

solar boom”, Bloomberg News, 16 January.

Efstathiou, J. (2018), “These four power

giants rule the world’s growing wind

market,” Bloomberg News, 26 February.

EIA (US Energy Information

Administration) (2019a), “2018 monthly

solar photovoltaic module shipments

report”, February, Washington, DC.

EIA (2019b), “Monthly biodiesel

production report,”

www.eia.gov/biofuels/biodiesel/

production/biodiesel.pdf.

Enkhardt, S. (2018), “China sets up

International Investment Alliance for

Renewable Energy”, PV Magazine, 13

August.

ESMC (European Solar Manufacturing

Council) (2019), “Our mission”, http://

europeansolar.org/index.php/mission/.

EurObserv’ER (2019), The State of

Renewable Energies in Europe, 2018

Edition, Paris.

EY, Solar PV jobs and SolarPower

Europe (2017), “Solar PV jobs & value

added in Europe”, November, Brussels,

https://www.ey.com/Publication/

vwLUAssets/EY-solar-pv-jobs-and-value-

added-in-europe/$FILE/EY-solar-pv-

jobs-and-value-added-in-europe.pdf.

Federal Republic of Nigeria (2016),

“Sustainable Energy for All action agenda

(SE4A LL-A A)”, Jul y.

FEE (France Energie Eolienne) and

BearingPoint (2018), “Wind observatory

2018”, October, https://fee.asso.fr/wp-

content/uploads/2018/10/2018_10_22_

observatoire_de_l_eolien-sim-eng-edited.

pdf.

FEE and BearingPoint (2017), “Wind

observatory 2017”, September,

http://fee.asso.fr/wp-content/

uploads/2017/09/20170829-

Observatoire-de-lEolien-2017-ENG.pdf.

Ferreira, W. C. (2017), “Política de

conteúdo local e energia eólica: A

experiência Brasileira”, doctoral thesis,

Universidade Federal Fluminense,

Center for Applied Social Studies,

http://abeeolica.org.br/wp-content/

uploads/2017/07/tese-politica-de-

conteudo-local-e-energia-e-WCF-2017.

pdf.

FNBC (Federación Nacional de

Biocombustibles de Colombia) (n.d.),

“Estadisticas”, accessed 15 March 2019,

www.fedebiocombustibles.com.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

Foehringer Marchant, E. (2018),

“Trump admin announces 25% tari on

chinese inverters”, Greentech Media, 17

September.

Froese, M. (2018), “Ports trying to keep

pace with oshore wind development”,

Windpower Engineering & Development,

3 October.

GIZ, PTB (Physikalisch-Technische

Bundesanstalt), and PIB (Photovoltaik-

Institut Berlin) (2017), “Pilot study

on quality aspects of PV power plants

in India”, September, https://www.

pi-berlin.com/images/pdf/publication/

White_Paper_-_India_PV_Projects_

Study_2017-_PI_Berlin.pdf.

GOGLA and Altai Consulting (2018),

Powering Opportunity. The Economic

Impact of O-grid Solar in an Evolving

Market, July, Utrecht.

GOGLA and Vivid Economics (2018),

Employment Opportunities in an Evolving

Market, November, Utrecht.

Govender, P. (2019), “Renewable

energy independent power producer

procurement programmes (REIPPPP)”,

ESMAP Solar Learning Event, Ouarzazate,

Morocco, 5 February, https://esmap.org/

esmap_solar_learning_event_morocco.

Green Energy Markets (2019),

“Renewable energy index December

2018”, http://greenmarkets.com.au/

images/uploads/Resources/RE_Index/

Renewable_Energy_Index_-_Dec18.pdf.

Guler, M. (2019), “Exponential or slow

growth?”, PV Magazine, 1 April.

Gupta, U. (2019), “Lone bid for 10 GW

solar tender rejected”,

PV Magazine India, 23 January.

Gupta, U. (2018a), “India: 25% safeguard

duty will threaten ongoing solar PV

projects”, PV Magazine, 18 July.

Gupta, U. (2018b), “MNRE: Preference will

be given to domestically manufactured

renewable energy products”, PV Magazine

India,

14 December.

GWEC (Global Wind Energy Council)

(2019), “Global wind report 2018”,

April, https://gwec.net/wp-content/

uploads/2019/04/GWEC-Global-Wind-

Report-2018.pdf.

HM Government (2019), Industrial

Strategy: Oshore Wind Sector Deal,

Policy paper, March, London.

Hutchins, M. (2018), “Prices begin to

stabilize, though falling revenues and

job losses expected among Chinese

manufacturers”,

PV Magazine, 2 August.

IEA-PVPS (International Energy Agency

Co-operative Programme on PV Power

Systems) (2018), “National survey report

of PV power applications in Malaysia 2017,

5 December, http://www.iea-pvps.org/

index.php?id=93&eID=dam_frontend_

push&docID=4680.

IEA SHCP (Solar Heating & Cooling

Programme) (2016),

Solar Heat Worldwide. Markets and

Contribution to the Energy

Supply 2014, Gleisdorf, Austria.

IEA, IRENA, UNSD, WB, WHO (2019),

Tracking SDG 7: The Energy Progress

Report 2019, Washington DC.

ILO (International Labour Organization)

(2018), Women and Men in the Informal

Economy: A Statistical Picture, Third

edition, Geneva.

ILO (n.d.), “Decent work”, https://www.

ilo.org/global/topics/decent-work/lang--

en/index.htm.

IRENA (2019a), Renewable Energy: A

Gender Perspective, Abu Dhabi.

IRENA (2019b), Renewable Energy

Statistics 2019, Abu Dhabi.

IRENA (2019c) forthcoming, Maximising

Local Beneﬁts of Large-Scale Renewable

Energy Deployment: Insights from Sub-

Saharan Africa,

Abu Dhabi.

IRENA (2018), Renewable Energy

Beneﬁts: Leveraging Local Capacity for

Oshore Wind, IRENA, Abu Dhabi.

IRENA (2017a), Renewable Energy

Auctions: Analysing 2016, IRENA, Abu

Dhabi.

IRENA (2017b), Renewable Energy

Beneﬁts: Leveraging Local Capacity for

Solar PV, IRENA, Abu Dhabi.

IRENA (2017c), Renewable Energy

Beneﬁts: Leveraging Local Capacity for

Onshore Wind, IRENA, Abu Dhabi.

IRENA (2016), Renewable Energy and

Jobs. Annual Review 2016, IRENA, Abu

Dhabi.

IRENA, IEA and REN21 (2018),

Renewable Energy Policies in a Time of

Transition, IRENA, OECD/IEA and REN21.

Kavruk, D. (2019), “Regulatory support for

rooftop solar market in Turkey”, presentation

at ESMAP Solar Learning Event,

Ouarzazate, Morocco,

4 February, https://esmap.org/

esmap_solar_learning_event_morocco.

Kenning, T. (2018a), “Indian solar and

wind installs to drop 49% in 2018/19 –

Bridge to India”, PV Tech, 17 September.

Kenning, T. (2018b), “Indian solar

deployment to decrease by 55% in

2018/19, but rooftop PV shines”, PV Tech,

15 November.

Korea Energy Agency (2019),

Communication with experts, March 2019.

Larsen, T. and Hansen, U. (2017),

“Vertical and horizontal dimensions of

upgrading in global value chains: the

establishment of local wind turbine

component manufacturing in South

Africa”, UNEP DTU Partnership Working

Paper Series, Technical University of

Denmark.

Lin, C. (2018), “The China eect:

Decreasing PV utilization rates, serious

oversupply and future strategies”, PV

Magazine, 4 July.

LM Wind Power (2018), “Suape, Brazil

factory expands to meet demand for

longer wind turbine blades”, 12 November,

https://www.lmwindpower.com/en/

stories-and-press/stories/news-from-lm-

places/suape-brazil-factory-expands-to-

meet-demand-for-longer-wind-turbine-

blades.

LM Wind Power (2017), “LM Wind Power

Gaspé Factory Expansion Shows How

Wind Industry Growth Brings Strategic

Economic Gains”, http://cws.huginonline.

com/L/160830/PR/201701/2072411_5.

html

Lucena, J. and Lucena, K. (2019), “Wind

energy in Brazil:

An overview and perspectives under the

triple bottom line,”

Clean Energy, March, doi: 10.1093/ce/

zkz001.

Malaviya, J. (2019), “Strong vacuum

tube collector sales in India”, Solar

Thermal World, 13 April, https://www.

solarthermalworld.org/content/

strong-vacuum-tube-collector-sales-india.

Mercom India Research (2019),

“Q4 and Annual 2018 India Solar

Market Update. Executive Summary”,

https://mercomindia.com/

q42018-india-market-update-execsumm/.

Ministerio de Energía (Government

of Argentina) (2019), communication

with experts, Subsecretaría de Energías

Renovables (Undersecretary for

Renewable Energy), April.

MTE/RAIS (Ministério do Trabalho

Emprego (Ministry of Labour and

Employment) / Relação Anual de

Informações Sociais (Annual Report

of Social Information) [Brazil] (2019),

“Annual List of Social Information.

Database including active and inactive

employments for sugarcane cultivation

and alcohol manufacture”, accessed March

2019.

MVOW (MHI Vestas Oshore Wind)

(2018), “New Blade Mould Arrives at MHI

Vestas Factory on Isle of Wight, Substantial

Economic Boost Coming to the Solent

Region”, 20 November, http://www.

mhivestasoshore.com/new-blade-mould-

arrives-at-mhi-vestas-factory/.

NASEO (National Association of State

Energy Ocials) and EFI (Energy

Futures Initiative) (2019), The 2019

U.S. Energy and Employment Report,

Washington, DC and Arlington.

Neri, E. (2019), Communication with

experts, April 2019.

Nobuoka, Y., Patnaik, S., Jha, S. and

Kuldeep, N. (2019), “Women working

in the rooftop solar sector: A look at

India’s transition to clean energy,”

Council on Energy, Environment and

Water (CEEW) and International

Energy Agency (IEA), February,

https://www.ceew.in/publications/

women-working-rooftop-solar-sector.

O’Brian, H. (2018), “Turkey launches 1GW

onshore tender”, Wind Power Monthly, 9

November.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

O’Connell, J. (2018), “Can oshore wind

save the workboat industry?”, Maritime

Executive, May/June, https://www.

maritime-executive.com/magazine/

can-oshore-wind-save-the-workboat-

industry.

Pantry, L. (2019), “’Landmark’ oshore

wind deal set to boost Yorkshire’s coastal

communities”, Yorkshire Post, 7 March,

https://www.yorkshirepost.co.uk/

business/landmark-oshore-wind-

deal-set-to-boost-yorkshire-s-coastal-

communities-1-9633247.

Power for All (2019), Communication

with experts, April 2019.

Power for All (2018), “#PoweringJobs”,

https://www.powerforall.org/campaigns/

poweringjobs.

Power Technology (2018), “EDF and

Canadian Solar raise $373m for Pirapora

solar park in Brazil”, 28 November, https://

www.power-technology.com/news/

edf-solar-park-in-brazil/.

Publicover, B. (2019), “The weekend

read: Zero energy, maximum support”, PV

Magazine, 16 March.

Quebec Wind Energy Cluster (n.d.),

“Deﬁnition”,

https://creneaueolien.ca/en/deﬁnition/.

REA (Renewable Energy Association)

(2018), REview Renewable Energy View

2018, London.

Reda, L. (2019), “Benban solar plant

starts operating, Egypt targets 37% clean

energy by 2035: Shaker”, Egypt Today,

13 March, https://www.egypttoday.com/

Article/3/45157/Benban-solar-plant-starts-

operating-Egypt-targets-37-clean-energy.

Roselund, C. (2019), “Hanwha 1.7 GW

panel factory is the second US fab to come

online this week”, PV Magazine, 1 March.

RSPO (Roundtable on Sustainable Palm

Oil) (2015), “Growth of certiﬁed palm oil

smallholders in Thailand showing no signs of

slowing down”, 29 September, www.rspo.

org/news-and-events/news/growth-of-

certiﬁed-palm-oil-smallholders-in-thailand-

showing-no-signs-of-slowing-down.

SEDA (Sustainable Energy Development

Authority) (2019), Communication with

experts, April 2019.

Simas, M. and Pacca, S. (2014),

“Assessing employment in renewable

energy technologies: A case study for

wind power in Brazil”, Renewable and

Sustainable Energy Reviews, Vol. 31,

March.

Singh, K. (2019), “2018 showed why

import duties can’t save India’s solar-panel

makers”, Quartz India, 1 January, https://

qz.com/india/1511463/safeguard-duties-

didnt-help-indias-solar-sector-in-2018/.

Solar Foundation (2019), National Solar Jobs

Census 2018, February, Washington, DC.

SolarPower Europe (2019), “SolarPower

Europe unveils supply-side industrial

strategy for solar at Clean Energy

Industrial Forum”, 19 March, http://www.

solarpowereurope.org/solarpower-europe-

unveils-supply-side-industrial-strategy-for-

solar-at-clean-energy-industrial-forum/.

Solar Power World (n.d.), “Global solar

panel manufacturing locations”, https://

www.solarpowerworldonline.com/

solar-panel-manufacturing-locations/.

Sother, L. (2019), “New Brazilian

government has no appetite for solar”,

www.solarthermalworld.org/content/

new-brazilian-government-has-no-

appetite-solar.

Schmela, M. (2019), “EU solar market

grows 36% in 2018”, SolarPower Europe

Newsletter, February.

Stitou, Y. (2019), “Socio-economic

beneﬁts of Noor Ouarzazate solar

complex”, presentation at ESMAP

Solar Learning Event, Ouarzazate,

Morocco, 5 February, https://esmap.org/

esmap_solar_learning_event_morocco.

St. John, J. (2019), “Report: Investment

in o-grid energy access totals $1.7B

through 2018”, Greentech Media, 6 March,

https://www.greentechmedia.com/

articles/read/investment-in-o-grid-

energy-access-2018.

Sushma, U.N. (2018), “India’s booming

solar sector has one major ﬂaw: Poor

quality”, Quartz, 2 August, https://

qz.com/india/1345508/poor-quality-

solar-panels-may-ruin-indias-renewable-

energy-boom/.

Syndicat des Energies

Renouvelables (n.d.), “L’éolien en

mer en France”, http://www.enr.fr/

editorial/59/162/L-eolien-en-mer.

Teikoku Databank, (2019), 特別企画: 太

陽光画連業者の倒産動向調査 (“Special

project: Bankruptcy trend investigation

of solar related companies”), 9 January,

https://www.tdb.co.jp/report/watching/

press/pdf/p190103.pdf.

Termmahawong, W. (2014), “Oil palm

production in Thailand – with a special

focus on small scale producers”, Japan

International Research Center for

Agricultural Sciences, 28 June, www.

jircas.arc.go.jp/program/proD/english/

ﬁles/2014/07/fanglei/Thai-oil-palm-

report-28-06-2014.pdf.

Tisheva, P. (2018), “BBOXX to bring

solar power to 2.5 million in Democratic

Republic of Congo”, Renewables Now,

8 June, https://renewablesnow.com/

news/bboxx-to-bring-solar-power-to-

25-million-in-democratic-republic-of-

congo-615712/.

Trendforce (2019), “Supply distribution

under trade barriers and the trend of market

diversiﬁcation”, PV Magazine, 3 April.

Tsagas, I. (2019), “Mega projects, mega

problems”, PV Magazine, 29 March.

UN DESA (United Nations Department

of Economic and Social Aairs) (2018),

“Interlinkages between Energy and

Jobs”, Policy Brief #13 in support of the

ﬁrst SDG7 review at the UN High-Level

Political Forum 2018, New York.

Upadhyay, A. (2019), “India solar duty fails

domestic producers as demand dwindles”,

Bloomberg, 30 January, https://www.

bloomberg.com/news/articles/2019-01-29/

india-solar-duty-fails-domestic-producers-

as-demand-languishes.

Upadhyay, A. (2018), “How Indian solar

taris delay Modi’s renewable goals”,

Bloomberg, 25 September, https://www.

bloomberg.com/news/articles/2018-09-24/

how-indian-solar-taris-delay-modi-s-

renewable-goals-quicktake.

Urbanchuk, J. M. (2019), “Contribution

of the ethanol industry to the economy

of the United States in 2018”, prepared

for the Renewable Fuels Association,

ABF Economics, Doylestown, PA,

https://ethanolrfa.org/wp-content/

uploads/2019/02/RFA-2018-Ethanol-

Economic-Impact-Final-1.pdf.

USDA-FAS (US Department of

Agriculture, Foreign Agricultural

Service) (2018a), “Indonesia biofuels

annual report 2017”, 13 August, https://

gain.fas.usda.gov/Recent%20GAIN%20

Publications/Biofuels%20Annual_

Jakarta_Indonesia_8-13-2018.pdf.

USDA-FAS (2018b), “Colombia biofuels

annual report 2017”, 9 September,

https://gain.fas.usda.gov/Recent%20

GAIN%20Publications/Biofuels%20

Annual_Bogota_Colombia_7-6-2018.pdf.

USDA-FAS (2018c), “Brazil biofuels

annual report 2017”, 10 August, https://

gain.fas.usda.gov/Recent%20GAIN%20

Publications/Biofuels%20Annual_Sao%20

Paulo%20ATO_Brazil_8-10-2018.pdf.

Verma Lal, P. (2019), “India prioritizes

domestic products in plan for 12 GW of

new solar”, PV Magazine, 7 February.

Verma Lal, P. (2018), “India imposes 25%

safeguard duty on solar imports”, PV

Magazine India, 31 July.

Vivid Economics (2019), “Energizing job

creation: employment opportunities along

the o-grid solar value chain”, April, Utrecht.

Weiss, W. and Spörk-Dür, M. (2018),

Solar Heat Worldwide 2018, IEA Solar

Heating & Cooling Programme, Gleisdorf,

Austria, May 2018.

Whitmarsh, M. (2019), The UK Oshore

Wind Industry: Supply Chain Review,

Oshore Wind Energy Council, https://s3-

eu-west-1.amazonaws.com/media.newore.

catapult/app/uploads/2019/02/04092232/

UK-Oshore-Wind-Supply-Chain-Review-

Jan-2019.pdf.

Willcox, M. et al. (2015), Utilizing

Electricity Access for Poverty Reduction,

Practical Action Consulting, January.

Wind Europe (2019a), The European

Oshore Wind Industry: Key Trends

and Statistics 2018, Brussels, https://

windeurope.org/wp-content/uploads/

ﬁles/about-wind/statistics/WindEurope-

Annual-Oshore-Statistics-2018.pdf.

Wind Europe (2019b), Wind Energy in

Europe in 2018. Trends and Statistics,

Brussels, https://windeurope.org/

wp-content/uploads/ﬁles/about-wind/

statistics/WindEurope-Annual-

Statistics-2018.pdf.

Wood Mackenzie (2019), “Wind power

market shares”, online dashboard, https://

power-and-renewables.woodmac.com.

RENEWABLE ENERGY AND JOBS – ANNUAL REVIEW 2019

World Bank (2018a), “Project paper on a

proposed additional loan in the amount of US$

100 million and a proposed clean technology

fund loan in the amount of US$ 25 million

to the Moroccan Agency for Sustainable

Energy (MASEN) for a Morocco Noor Solar

Power Project Additional Financing”, 15 May,

http://documents.worldbank.org/curated/

en/138481528687821561/pdf/Morocco-

Noor-AF-project-paper-P164288-May17-

clean-05212018.pdf.

World Bank (2018b), “Kenya launches

ambitious plan to provide electricity to all

citizens by 2022”, http://www.worldbank.

org/en/news/press-release/2018/12/06/

kenya-launches-ambitious-plan-to-provide-

electricity-to-all-citizens-by-2022.

World Bank (2016), “Informal enterprises in

Kenya”, January, Washington, DC.

WWF (2012), “Proﬁtability and sustainability

in palm oil production”, http://awsassets.

panda.org/downloads/proﬁtability_and_

sustainability_in_ palm_oil_production__

update_.pdf.

Yang, S. (2019), “Would a hard Brexit mean

hard times for the UK oshore wind industry?”,

Wood Mackenzie, 5 March, https://www.

woodmac.com/news/opinion/would-a-hard-

brexit-mean-hard-times-for-the-UK-oshore-

wind-industry/.

Yuanyuan, L. (2019), “Chinese solar

manufacturers increased production, export

in 2018 while domestic installations fell”,

Renewable Energy World, 4 February.

Zhang, Y. (2019), “Growing competition

from heat pumps and gas boilers”,

Solarthermalworld, 24 April, https://www.

solarthermalworld.org/content/growing-

competition-heat-pumps-and-gas-boilers.

PHOTO CREDITS

Page 13 Johannesburg, South Africa | Sunshine Seeds / Shutterstock.com

Page 17 Angtong,Thailand | Bubbers BB / Shutterstock.com

Page 22 IRENA/ADFD Project Facility, Senegal/S. Lockwood

Page 26 Bariri, Sao Paulo, Brazil | Alf Ribeiro / Shutterstock.com

Page 28 Nagpur, India | SARIN KUNTHONG / Shutterstock.com

Page 31 Melaka, Malaysia | Ahmad Fairuzazli / Shutterstock.com

All other photos are from Shutterstock.

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