Inteligencia Artificial

OECD Skills Outlook 2023
SKILLS FOR A RESILIENT GREEN AND DIGITAL
TRANSITION
V E R S
I
O
N
L
A
U
NCH
Under embargo until Monday, 6 November 2023 at 10:00 (UTC)

OECD Skills Outlook
2023
SKILLS FOR A RESILIENT GREEN AND DIGITAL
TRANSITION
V E R S
I
O
N
L
A
U
NCH

This work is published under the responsibility of the Secretary-General of the OECD. The opinions expressed and
arguments employed herein do not necessarily reflect the official views of the Member countries of the OECD.
This document, as well as any data and map included herein, are without prejudice to the status of or sovereignty over
any territory, to the delimitation of international frontiers and boundaries and to the name of any territory, city or area.
The statistical data for Israel are supplied by and under the responsibility of the relevant Israeli authorities. The use of
such data by the OECD is without prejudice to the status of the Golan Heights, East Jerusalem and Israeli settlements in
the West Bank under the terms of international law.
Please cite this publication as:
OECD (2023), OECD Skills Outlook 2023: Skills for a Resilient Green and Digital Transition, OECD Publishing, Paris,
https://doi.org/10.1787/27452f29-en.
ISBN 978-92-64-97327-5 (print)
ISBN 978-92-64-80712-9 (pdf)
ISBN 978-92-64-95577-6 (HTML)
ISBN 978-92-64-63102-1 (epub)
OECD Skills Outlook
ISSN 2521-1064 (print)
ISSN 2521-1072 (online)
Photo credits: Cover: Head: © Dome LifeThibaan/Shutterstock.com; head profile: © Hub Design/Shutterstock.com;
house: © VoodooDot/Shutterstock.com; cargo bike: © Dn Br/Shutterstock.com; birds: © Strike Pattern/Shutterstock.com;
people: © dramaj/Shutterstock.com; person in wheelchair: © Leremy/Shutterstock.com;
abstract background: © Vladystock and Studio Folzer/Shutterstock.com.
Corrigenda to OECD publications may be found on line at: www.oecd.org/about/publishing/corrigenda.htm.
© OECD 2023
The use of this work, whether digital or print, is governed by the Terms and Conditions to be found at https://www.oecd.org/termsandconditions.

 3
OECD SKILLS OUTLOOK 2023 © OECD 2023
Foreword
Climate change and policy to combat it, as well as digital transformation, are the defining challenges of our
time. The urgency to address climate change has never been more apparent. The consequences of rising
temperatures are profound and unforgiving. Extreme weather events, raging wildfires, biodiversity loss,
natural disasters and the resulting food and water insecurity are becoming increasingly commonplace.
These changes are not isolated. They trigger a domino effect of economic disruption, adverse health
effects, heightened conflict and forced migration. At the same time, progress in artificial intelligence (AI)
and, in particular, the onset of generative AI is such that, in some areas, its output has become
indistinguishable from that of humans, and in several domains, AI’s capabilities are well beyond what
humans can do. The AI revolution is redefining our workplaces, societies and knowledge exchange
mechanisms. While AI systems bear the promise of supporting scientific discoveries that could enhance
the health, productivity and well-being of many, they could also challenge many jobs and even be used to
spread false and misleading information, eroding public trust, threatening security and social cohesion.
If societies are to halt environmental destruction and harness the potential of AI and robotics effectively,
they must fundamentally strengthen initial education systems, provide upskilling and reskilling
opportunities for adults over the life course and ensure that skills are effectively mobilised. Investments in
skills are critical to building a resilient green and digital transition.
However, so far, the speed of environmental and digital transformations is outpacing the rate of change in
our education and skills policies and their capacity to respond to emerging needs in society and labour
markets. As new job profiles and skills requirements emerge, too few adults in OECD countries participate
in the formal or non-formal learning necessary to meet these new requirements. This hampers the ability
of workers to upskill and reskill, limiting their opportunities to reallocate from sectors and occupations that
shrink into sectors that grow as a result of efforts to green the economy. It also limits their ability to
strengthen the skills they will need to work alongside new technologies and make the most of potential
productivity gains. At the societal level, lack of participation in formal or non-formal learning limits the talent
pool needed to sustain the twin transition.
A key to building resilience in the face of environmental challenges and technological transformations is to
empower individuals through investments in skills. Skills alone, however, do not guarantee meaningful
action. Attitudes and dispositions, which are in large part shaped through education and training, play a
crucial role in motivating individuals to use their skills for the betterment of society. Unfortunately, we see
disparities in attitudes and dispositions that mirror inequalities in skills proficiency. Socio-economically
disadvantaged young people are particularly vulnerable in this regard, and addressing this gap must
become a priority for educators and policy makers alike.
This edition of the Skills Outlook brings a range of new, important insights into changes in the demand for
skills resulting from the green and digital transition and the role skills policies play in ensuring resilience.
Although it is important not to underestimate the challenges brought about by this twin transition, it is
equally important not to underestimate societal capacity for innovation and adaptation. An important lesson
that can be learnt from the COVID-19 pandemic is that societies have the capacity to adapt faster and to
a larger degree than previously imagined. The ability to adapt will continue to matter as societies face

4 
unprecedented disruptions. Whether the greening of jobs and proliferation of generative AI manifest as a
societal challenge or opportunity to enhance well-being rests on policy makers’ and leaders’ ability to
exercise foresight and leadership, with the consideration of ethics, equity and the advancement of social
and economic well-being at the forefront of policy making.

 5
Acknowledgements
The development of this edition of the OECD Skills Outlook report was guided by the Education Policy
Committee and the Skills Advisory Group. The OECD Skills Outlook series is the product of a close
collaborative effort among several directorates in the OECD Secretariat.
This volume was prepared by Francesca Borgonovi and Helke Seitz from the OECD Centre for Skills based
on material developed in the context of a series of background papers and analyses detailed in the
Reader’s Guide and in collaboration with colleagues from within and outside the OECD Secretariat. OECD
collaborators: the Economics of Prevention team in the Health Division in the Employment, Labour and
Social Affairs Directorate; the Modelling and Outlook teams in the Environment and Economy Integration
Division in the Environment Directorate, the Technology Diffusion team in the Productivity, Innovation and
Entrepreneurship Division in the Science, Technology and Innovation Directorate, the Directorate for
Education and Skills, and the Public Governance Directorate. Collaborators outside the OECD Secretariat:
the Gesundheit Österreich Forschungs- und Planungs GmbH, the Joint Research Centre, the International
Transport Forum, and Lightcast.
Stefano Scarpetta (Director for the Directorate of Employment Labour and Social Affairs), Andreas
Schleicher (Director for the Directorate of Education and Skills), Mark Pearson (Deputy Director for the
Directorate of Employment Labour and Social Affairs), and El Iza Mohamedou (Head of the OECD Centre
for Skills), provided strategic oversight.
Colleagues from the Directorate for Employment, Labour and Social Affairs; the Science, Technology and
Innovation Directorate; the Directorate for Education and Skills; the Public Governance Directorate; the
Centre for Entrepreneurship SMEs, Regions and Cities; the Economics Department; the Development
Centre, the OECD Translation Division; and the International Transport Forum provided valuable
comments at various stages in the preparation of this report.
The report was edited by Julie Harris. Francesca Borgonovi, Jennifer Cannon, Helke Seitz and Sarah Wildi
co-ordinated production. Communication and administrative support were provided by Jennifer Cannon,
Duniya Dedeyn, Lucy Hulett and Alastair Wood.
This document was co-funded by the European Union. The views expressed herein can in no way be taken
to reflect the official opinion of the European Union.

6 
Table of contents
Foreword 3
Acknowledgements 5
Reader’s guide 12
Acronyms and abbreviations 14
Executive summary 16
1 Overview 19
1.1. Introduction 20
1.2. Towards a sustainable and inclusive twin green and digital transition 21
1.3. Skills for a resilient green and digital transition 22
1.4. Adapting investments in skills development to a changing context 23
1.5. The role of attitudes and dispositions 25
1.6. The green transition and how skills policies can promote resilience 25
1.7. The digital transition and how skills policies can promote resilience 30
1.8. Report roadmap 35
References 36
2 From awareness to action: The role of attitudes and dispositions for mobilising
environmental sustainability skills 38
2.2. Many adults perceive climate change as a threat 41
2.3. Few young people excel in all dimensions of environmental sustainability 51
2.4. Conclusions 64
References 66
Note 68
3 Skills for a net-zero future: Empowering communities for the green transition 69
3.2. Projected employment changes resulting from the implementation of the Fit for 55 policy
targets 73
3.3. Projected changes in the demand for skills 81
3.4. Conclusions 93
References 94
Notes 96

 7
4 Preparing for a changing world: Promoting key skills to adapt to climate change
through education and training 98
4.2. Environmental conditions shape skills and human capital accumulation 101
4.3. Environmental and macroeconomic conditions shape human attitudes and dispositions 114
4.4. Physical skills needed to adapt to a changing climate 118
4.5. Conclusions 128
References 130
Notes 136
5 Skills and attitudes for new information landscapes 137
5.2. How many people lack key information-processing skills? 147
5.3. The role of metacognitive skills 151
5.4. How much are young people being taught to deal with digital information? 159
References 164
Note 169
6 Empowering through health literacy: Skills to navigate health information and make
informed decisions 170
6.2. What is health literacy? 173
6.3. Health literacy matters 174
6.4. Factors that shape the development of health literacy and how well health literacy
translates into health 175
6.5. Disparities in health literacy within and across countries 177
6.6. Policy efforts to promote health literacy and improve access to healthcare information and
services 187
References 199
Notes 208
7 Bridging language barriers: Language skills in information-rich societies 210
7.2. Language skills are crucial for communication and information exchange 214
7.3. Making the most of artificial machine translation technologies requires the development of
new skills 229
7.4. The skills of language professionals 231
References 237
8 The human behind the machine: Skills and attitudes towards the future of artificial
intelligence 242
8.2. Perceptions about AI differ by country and socio-economic characteristics 245
8.3. The demand for and the skills of workers responsible for AI development, adaptation and
maintenance 248
8.4. Attitudes and dispositions needed to make the most of generative AI systems 259

8 
References 265
Note 268
FIGURES
Figure 2.1. Percentage of adults who perceive climate change as a major threat in OECD countries, 2020 41
Figure 2.2. Gender differences in the perception of climate change as a major threat in OECD countries, 2020 42
Figure 2.3. Differences in the perception of climate change as a major threat across age groups in OECD
countries, 2020 43
Figure 2.4. Educational attainment and the perception of climate change as a major threat in OECD countries,
2020 44
Figure 2.5. Importance of environmental issues by level of educational attainment, selected countries, 2022 45
Figure 2.6. Share of respondents perceiving negative impacts of climate change or other environmental
issues, 2022 46
Figure 2.7. Respondents’ opinions on addressing environmental issues, 2022 47
Figure 2.8. Climate change belief and CO2 emissions per output in OECD countries, 2020 48
Figure 2.9. Climate change concern and CO2 emissions per output in OECD countries, 2020 49
Figure 2.10. The impact of working in CO2-intensive industries on attitudes towards climate change and
support for pro-environmental policies 50
Figure 2.11. Perceptions of climate change threat and engagement in pro-environmental behaviours and
support for environmental protection policies 51
Figure 2.12. Environmental sustainability competence 52
Figure 2.13. Distribution of students with foundational levels in environmental sustainability competence in
OECD countries (PISA 2018) 54
Figure 2.14. Distribution of students with advanced levels in environmental sustainability competence in
OECD countries (PISA 2018) 55
Figure 2.15. Distribution of students with foundational and advanced levels in environmental sustainability
competence by gender and socio-economic status, OECD average (PISA 2018) 56
Figure 2.16. Gender differences by science competency subscale (PISA 2015) 58
Figure 2.17. The association between environmental sustainability competence areas and energy-saving
behaviours among 15-year-olds in OECD countries (PISA 2018) 61
Figure 2.18. The association between environmental sustainability competence and participation in activities in
favour of environmental protection among 15-year-olds in OECD countries (PISA 2018) 62
Figure 2.19. Effect of parents’ environmental engagement on students’ engagement (PISA 2018) 63
Figure 3.1. Employment level by occupational category and sector and employment share by sector, EU
countries, 2019 74
Figure 3.2. Change in sectoral production in the Fit for 55 scenario 76
Figure 3.3. Employment in the Fit for 55 and baseline scenarios 77
Figure 3.4. Evolution in sectoral employment in the Fit for 55 scenario 78
Figure 3.5. Sectoral employment by occupational category, ETS sectors 79
Figure 3.6. Sectoral employment by occupational category, ESR sectors 80
Figure 3.7. Projected change in the demand for skills between 2019 and 2030 when considering relative
growth in employment, by main skill category 82
Figure 3.8. Projected change in the demand for skills between 2019 and 2030 when considering absolute
changes in employment, by main skill category 83
Figure 3.9. Skills similarity of employment opportunities for blue-collar and farm workers 90
Figure 3.10. Sectors with several within-cluster transition opportunities 91
Figure 3.11. Sectors with limited within-cluster transition opportunities 92
Figure 4.1. Absolute number of natural disasters due to extreme temperature events per year in OECD
countries and globally, 1980-2020 101
Figure 4.2. Share of exposure to very hot days in OECD countries, 2017-21 102
Figure 4.3. Increase in heat stress exposure in OECD countries, 2017-21 compared to 1981-2010 103
Figure 4.4. Mean population exposure to PM2.5 in OECD countries, 2000 and 2019 104
Figure 4.5. Mechanisms of the effects of adverse environmental conditions on cognition over the life course 105
Figure 4.6. Evolution of learning outcomes between pre-COVID and 2021-22 assessments 112
Figure 4.7. Trends in stated prioritisation of the environment over the economy, selected countries, 1994-2020115
Figure 4.8. Heterogeneity of the effect of unemployment on environment prioritisation, by socio-demographic
group, 1995-2020 118

 9
Figure 4.9. Cycling skills in selected countries around the world, 2022 121
Figure 4.10. Cycling skills in selected countries around the world, by education and gender, 2022 121
Figure 4.11. Willingness to prioritise bicycles over automobiles in new road and traffic infrastructure projects in
selected countries around the world, 2022 122
Figure 4.12. Willingness to prioritise bicycles over automobiles in new road and traffic infrastructure projects,
by age, degree of urbanisation and education in selected countries around the world, 2022 123
Figure 4.13. Swimming ability around the world, 2019 125
Figure 4.14. Swimming ability, by education and country income group, 2019 126
Figure 4.15. Country-level association between educational level and swimming ability, 2019 127
Figure 4.16. Swimming ability, by gender and country income group, 2019 128
Figure 5.1. Percentage of adults worrying about false online information and online fraud in OECD countries,
2019 139
Figure 5.2. Percentage of adults with the lowest levels of literacy and numeracy in selected OECD countries,
2012, 2015 and 2019 147
Figure 5.3. Young people’s reading, mathematics, and science proficiency in selected countries, 2018 148
Figure 5.4. Decline in accuracy among adult populations completing a long series of information-processing
tasks in selected countries 149
Figure 5.5. Decline in accuracy among adult populations, by socio-economic characteristic 150
Figure 5.6. Decline in accuracy among adolescent populations completing a long series of information-
processing tasks in selected countries, 2018 151
Figure 5.7. Students’ ability to understand difficult texts in selected countries, by reading proficiency level,
2018 152
Figure 5.8. Students’ ability to understand difficult texts who also have reading proficiency Level 2 or below, in
selected countries, 2018 153
Figure 5.9. Students’ ability to understand difficult texts who also have reading proficiency Level 2 or below, by
country and gender, in selected countries, 2018 154
Figure 5.10. Students’ reactions to potentially phishing email content in selected countries, 2018 155
Figure 5.11. Students’ trust in science in selected countries, 2015 156
Figure 5.12. Adults’ trust in science index and percentage trusting scientists in selected countries, 2018 157
Figure 5.13. The cross-country association between epistemic beliefs in science and trust in science and
scientists 158
Figure 5.14. The cross-country association between trust in science and estimated excess mortality due to
COVID-19 between the end of 2020 and the end of 2021 159
Figure 5.15. Countries in which young people are being taught strategies to deal with digital information, 2018 160
Figure 5.16. Students’ acquisition of strategies to deal with digital information, by economic, social and cultural
status, 2018 161
Figure 6.1. Health literacy components 174
Figure 6.2. Percentage of respondents who responded “very difficult” or “difficult” when asked to rate
performing 12 health literacy tasks, selected OECD countries, 2019-20 178
Figure 6.3. Mean score values of health literacy proficiency by gender, selected OECD countries, 2019-20 180
Figure 6.4. Mean score values of health literacy, by levels of financial deprivation, selected OECD countries,
2019-20 181
Figure 6.5. Mean score values of health literacy, by educational attainment, selected OECD countries, 2019-
20 182
Figure 6.6. Mean score values of health literacy by age in selected OECD countries, 2019-20 183
Figure 7.1. The demand for English skills among professionals in European countries, 2022 216
Figure 7.2. Share of adults who do not know a language other than their mother tongue, 2007 and 2016 219
Figure 7.3. Share of adults who do not know a language other than their mother tongue, by educational
attainment, 2016 220
Figure 7.4. Share of adults who are proficient in their best-known language after their mother tongue, 2007
and 2016 221
Figure 7.5. Level of proficiency in the best-known non-mother-tongue language among adults in European
countries, by educational attainment, 2016 222
Figure 7.6. Period during which learning a modern language other than the main language of instruction was
compulsory in pre-primary, primary and/or general secondary education in 2021/22 in European countries 224
Figure 7.7. Period during which the learning of two modern languages was compulsory in pre-primary, primary
and/or general secondary education in 2021/22 in European countries 225
Figure 7.8. Number of modern languages learnt by students in upper secondary education in European
countries, 2020 228
Figure 7.9. Learning English at school in European countries, by educational level, 2020 229

10 
Figure 7.10. Percentage of online job postings for language professionals mentioning knowledge, transversal
and digital skills in English-speaking countries, 2015-19 233
Figure 7.11. Digital skills groups required in online job postings for language professionals in English-speaking
countries, 2015-19 234
Figure 7.12. The top 20 skills groups demanded of language professionals by employers in English-speaking
countries, 2015-19 235
Figure 8.1. Adults’ perception of the long-term impact of AI in selected countries, 2021 246
Figure 8.2. Difference between positive and negative associations with AI in selected countries, 2021 247
Figure 8.3. Adults’ perception of the long-term impact of AI, by gender, discrimination and education, 2021 248
Figure 8.4. Share of online vacancies requiring AI skills in selected countries, 2019 and 2022 250
Figure 8.5. Top three sectors in which online vacancies requiring AI skills are advertised in selected countries,
2019-22 251
Figure 8.6. Trend in the demand for AI workers by skill cluster, 2019-22 253
Figure 8.7. Top three skill clusters demanded in postings requiring AI skills, selected countries, 2019-22 254
Figure 8.8. AI skill cluster distribution, by country, 2019-22 255
Figure 8.9. AI job postings mentioning keywords related to ethics, 2019-22 256
Figure 8.10. Share of AI vacancies posted by US top AI and other AI employers, by industry, 2022 257
Figure 8.11. Top 20 skills in AI job postings by US top AI employers, 2022 258
Figure 8.12. Perception of “risk” as a threat or an opportunity in selected countries, 2019 260
Figure 8.13. Perceptions of risk as a danger, by gender, income and educational attainment, OECD average,
2019 261
Figure 8.14. Students’ fear of failure in selected countries, 2018 262
Figure 8.15. Students’ fear of failure in selected countries, by gender and parental education, 2018 263
INFOGRAPHIC
Infographic 1. Key facts and figures 18
TABLES
Table 3.1. Projected change in the demand for skills between 2019 and 2030 under the Fit for 55 scenarios 84
Table 3.2. How the demand for skills will be impacted by implementing Fit for 55 87
Table 4.1. Summary of evidence in the literature on the effects of temperatures and air pollution on skills
development 106
Table 4.2. Effect of natural disasters on the likelihood that individuals will prioritise the environment over the
economy 116
Table 6.1. Mean score values of health literacy proficiency, selected OECD countries, 2019-20 179
Table 6.2. The association between health literacy and health lifestyles, in selected OECD countries, 2019-20 185
Table 6.3. The association between health literacy and health, selected OECD countries, 2019-20 186
Table 6.4. The association between health literacy and the use of emergency healthcare services and surgical
specialists, selected OECD countries, 2019-20 187
Table 7.1. Explicit and implicit language requirements in online job vacancies in European countries, 2022 215
Table 7.2. Implicit language requirements in European countries, 2022 217
Table 8.1. Examples of skill sets in the seven AI-related skill clusters 252

 11
Look for the 12 at the bottom of the tables or graphs in
this book. To download the matching Excel® spreadsheet, just type
the link into your Internet browser or click on the link from the digital
version.
This book has... A service that delivers Excel® files from the printed page!
Follow OECD Publications on:
https://twitter.com/OECD
https://www.facebook.com/theOECD
https://www.linkedin.com/company/organisation-eco-cooperation-
development-organisation-cooperation-developpement-eco/
https://www.youtube.com/user/OECDiLibrary
https://www.oecd.org/newsletters/

12 
Reader’s guide
Calculation of OECD and EU averages
The OECD averages include only OECD countries. Similarly, EU averages include only EU member states
and are calculated as unweighted averages. OECD and EU averages are calculated for member countries
with available data, and the number of countries which are part of the averages can differ. OECD and EU
averages are calculated based on the OECD and EU member countries presented in the respective figure
or table, with all data accessible via the OECD’s StatLinks service.
In Chapter 6, “Empowering through health literacy: Skills to navigate health information and make informed
decisions”, data from the European Health Literacy Population Survey 2019-2021 (HLS19) are used where
15 OECD countries participated and refer to the OECD average in this chapter as “HLS19 OECD average”.
Methodology and datasets
Detailed explanations of the methodology, analytical approach, and databases used in this report are
available in the following working papers:
Chapter 2
Asai, K., F. Borgonovi and S. Wildi (2022), “Understanding how economic conditions and natural disasters
shape environmental attitudes: A cross-country comparison to inform policy making”, OECD Social,
Employment and Migration Working Papers, No. 281, OECD Publishing, Paris,
https://doi.org/10.1787/0c2c8862-en.
Borgonovi, F., O. Brussino, H. Seitz, A. Bertoletti, F. Biagi, A. Bitat, Z. Karpinski and M. Montanari (2022),
“The environmental sustainability competence toolbox: From leaving a better planet for our children to
leaving better children for our planet”, OECD Social, Employment and Migration Working Papers, No. 274,
OECD Publishing, Paris, https://doi.org/10.1787/1097a78c-en.
Borgonovi, F., O. Brussino, H. Seitz, A. Bertoletti, F. Biagi, A. Bitat, Z. Karpinski and M. Montanari (2022),
“Young people’s environmental sustainability competence: Emotional, cognitive, behavioural, and
attitudinal dimensions in EU and OECD countries”, OECD Social, Employment and Migration Working
Papers, No. 275, OECD Publishing, Paris, https://doi.org/10.1787/27991ec0-en.
Chapter 3
Borgonovi. F., E. Lanzi, H. Seitz, R. Bibas, J. Fouré, H. Plisiecki and L. Atarody (2023), “The effects of the
EU Fit for 55 package on labour markets and the demand for skills”, OECD Social, Employment and
Migration Working Papers, No. 297, OECD Publishing, Paris, https://doi.org/10.1787/6c16baac-en.

 13
Chapter 4
Asai, K., F. Borgonovi and S. Wildi (2022), “Understanding how economic conditions and natural disasters
shape environmental attitudes: A cross-country comparison to inform policy making”, OECD Social,
https://doi.org/10.1787/8e880ea2-en.
Borgonovi, F., H. Seitz and I. Vogel (2022), “Swimming skills around the world: Evidence on inequalities in
life skills across and within countries”, OECD Social, Employment and Migration Working Papers, No. 281,
OECD Publishing, Paris, https://doi.org/10.1787/0c2c8862-en.
Horvath, D. and F. Borgonovi (2022), “Global warming, pollution and cognitive developments: The effects
of high pollution and temperature levels on cognitive ability throughout the life course”, OECD Social,
https://doi.org/10.1787/319b9a1f-en.
Chapter 6
Thomas Link, Robert Griebler, Peter Nowak, Christa Straßmayr and Jürgen Pelikan (M-POHL network, for
the HLS19 Consortium) provided the analysis for this chapter.
The HLS19 Consortium of the WHO Action Network M-POHL (2021), International Report on the
Methodology, Results, and Recommendations of the European Health Literacy Population Survey 2019-
2021 (HLS19) of M-POHL, Austrian National Public Health Institute, Vienna, https://m-pohl.net/sites/m-
pohl.net/files/inline-files/HLS19%20International%20Report.pdf.
Chapter 7
Borgonovi, F., J. Hervé and H. Seitz (2023), “Not lost in translation: The implications of machine translation
technologies for language professionals and for broader society”, OECD Social, Employment and
Migration Working Papers, No. 291, OECD Publishing, Paris, https://doi.org/10.1787/e1d1d170-en.
Marconi, G., L. Vergolini and F. Borgonovi (2023), “The demand for language skills in the European labour
market: Evidence from online job vacancies”, OECD Social, Employment and Migration Working Papers,
No. 294, OECD Publishing, Paris, https://doi.org/10.1787/e1a5abe0-en.
Chapter 8
Borgonovi, F., F. Calvino, C. Criscuolo, J. Nania, J. Nitschke, L. O’Kane, L. Samek and H. Seitz (2023),
“Emerging trends in AI skill demand across 14 OECD countries”, OECD Artificial Intelligence Papers,
No. 2, OECD Publishing, Paris, https://doi.org/10.1787/7c691b9a-en.

14 
Acronyms and abbreviations
The following are the main abbreviations and acronyms cited in the report.
Abbreviation/acronym Full description
AI Artificial intelligence
AWS Amazon Web Services
BLI Better Letter Initiative
CAD Computer-aided design
CAM Computer-aided manufacturing
CAT Computer-assisted translation
CCWC Computing and Communication Workshop and Conference
CEFR Common European Framework of Reference for Languages
CGE Computable General Equilibrium
CO2 Carbon dioxide
CRM Customer relationship management
EPIC Environmental Policies and Individual Behaviour Change
ERP Enterprise resource planning
ESCO European Skills, Competences, Qualifications and Occupations
ESCS Economic, social and cultural status
ESR Effort Sharing Regulation
ETS Emission Trading System
GDP Gross domestic product
GHG Greenhouse gas
HIQA Health Information and Quality Authority
HLS19 European Health Literacy Population Survey 2019-2021
HLS-EU European Health Literacy Survey
IAQ Indoor air quality
ICT Information and communication technology
IHF Irish Heart Foundation
IPCC Intergovernmental Panel on Climate Change
ISCED International Standard Classification of Education
ISCO International Standard Classification of Occupations
ISO International Organization of Standards
IT Information technology
KAVI Kansallinen audiovisuaalinen instituutti
LSTM Long short-term memory
MLW Media Literacy Week
MoH Ministry of Health
MT Machine translation
NALA National Adult Literacy Agency
NGOs Non-governmental organisations
NLLB No Language Left Behind

 15
Abbreviation/acronym Full description
NMT Neural machine translation
OCR Optical character reader
PIAAC Programme for the International Assessment of Adult Competencies
PISA Programme for International Student Assessment
PM Particulate matter
RBMT Rule-based machine translation
REALM Rapid Estimate of Adult Literacy in Medicine
SES Socio-economic status
SMT Statistical machine translation
STEM Science, technology, engineering and mathematics
TOFHLA Test of Functional Health Literacy
VET Vocational education and training
WHO World Health Organization

16 
Executive summary
The coronavirus (COVID-19) pandemic and policy actions aimed at halting its spread profoundly
impacted societies and economies worldwide. Incorporating lessons from the pandemic in policy
making is crucial not only to sustaining economic and social well-being in OECD countries in the short and
medium term but also to building resilience to future shocks and securing just and inclusive economic
growth in the long term.
Two areas in which investments in skills and skills policies can help societies anticipate rather
than react to future adverse events are promoting environmental sustainability and ensuring
human-centred digital technologies that effectively support communication and information
exchange. Environmental degradation and untrustworthy information landscapes challenge economies
and societies worldwide and are sources of considerable worry and anxiety among populations. On
average, almost seven in ten adults across OECD countries perceive climate change as a threat, and six
in ten worry about receiving false information on line.
Key to building system-level resilience to environmental challenges and technological
transformations applied to information exchange is empowering individuals to develop a wide
range of skills – including information-processing skills, socio-emotional skills and metacognitive skills –
and ensuring that individuals can effectively apply these skills.
Projections suggest that between 2019 and 2030, the demand for skills related to interacting with
computers, thinking creatively, analysing data and information, and communicating with persons
outside an organisation will grow the most. Making the most of interconnected labour markets also
requires proficiency in language skills. Four in ten vacancies posted on line in 2021 in non-English-
speaking European countries required a knowledge of English. Among vacancies for technicians and
associate professionals, this figure was one in two.
Yet many people worldwide do not have baseline levels of proficiency in the set of skills needed to
ensure their own and societal economic and social well-being, and to effectively contribute to a
greener future. The COVID-19 pandemic demonstrated the importance of health literacy, i.e. the ability
to access, comprehend, assess, and apply information to make informed decisions regarding healthcare
and disease prevention. Technology gave individuals the possibility to access up-to-date scientific
information in real time, but at the same time exposed them to a huge amount of false and potentially
harmful information on line. During the worst health crisis in a century, over four in ten adults reported that
they would find it difficult or very difficult to judge the advantages and disadvantages of different treatment
options, decide how to protect themselves from illness using information from the mass media, or find
information on how to handle mental health problems.
Complicating matters, individuals acquire and lose proficiency in different skills over time
depending on their usage and external constraints, and rapidly evolving environmental and social
conditions change the set of skills and level of proficiency demanded. Lifelong learning systems that
are responsive to changing circumstances can ensure that individuals are proficient in the range of skills
needed to support economic growth and social cohesion. However, although proficiency in accessing,

 17
comprehending, and evaluating texts, and critically reasoning with mathematical content are vital skills for
navigating information-rich environments, 18% of adults in OECD countries do not reach baseline levels
of proficiency in all these skills.
Attitudes and dispositions drive individuals’ motivation to use their skills in ways that enhance
personal and societal well-being. They also boost the effectiveness with which skills are deployed. For
example, young people who agreed or strongly agreed that looking after the environment was important
to them were 16 percentage points more likely to save energy for environmental reasons. Worryingly,
inequalities in attitudes and dispositions mirror inequalities in skills proficiency. For example, socio-
economically disadvantaged young people are 25 percentage points less likely to reach baseline levels of
proficiency in science than their more advantaged peers.
Reducing the social cost of policy action by ensuring adequate upskilling and reskilling efforts, as
well as providing assistance for populations negatively affected by climate change mitigation
policies, is critical to ensure continued support of action to halt environmental degradation. For
every 1% increase in unemployment, the percentage of adults who report prioritising the environment over
the economy declines by 1.7%.
Whether individuals use their skills for positive or negative transformations of their environment
depends on their attitudes and dispositions. Attitudes and dispositions are key enablers of skills
investments. Skills do not translate into meaningful action without the will to act. For example, individuals
with higher levels of education are more likely to be aware of the dangers associated with environmental
degradation. Across OECD countries, 73% of individuals with a tertiary qualification, 66% with a secondary
qualification and 63% of those without secondary qualifications report perceiving climate change as a
threat. Similarly, individuals with tertiary-level qualifications are considerably more likely than those without
tertiary-level qualifications to indicate that they would be willing to compromise their current lifestyle for the
benefit of the environment.
Despite the importance of ensuring that individuals have both the skills and the will to act, as many
as seven out of ten young people do not master the emotional, behavioural and cognitive
dimensions of environmental sustainability. They are thus less likely to engage in actions aimed at
promoting environmental sustainability as present consumers and future citizens of the world.
Moreover, despite the increasing awareness of the importance of considering ethical aspects in
artificial intelligence (AI) development and the critical role AI professionals play in economies and
societies, in 12 out of the 14 countries with available information, less than 1% of online vacancies
seeking professionals with AI skills in 2022 mentioned aspects related to ethics in AI.
Whereas investing in skills is paramount to empowering communities to cope with adverse
circumstances, it is equally important to put support systems in place to help communities
overcome the stress and difficulties they may encounter as a result of the profound
transformations unleashed by the green and digital transition. In the long term, successful adaptation
requires careful consideration of the direct and indirect consequences of dealing with significant social and
economic upheavals. Identifying populations that lack proficiency in skills that will grow in importance and
developing effective policy responses to support them in building proficiency is critical to building system-
level resilience since the outcomes of social, digital and environmental transformations will be defined by
the actions and behaviours of all individuals, including individuals with lower levels of proficiency.
Individuals from socio-economically disadvantaged backgrounds are less likely to gain proficiency
in a range of skills during formal education, develop attitudes and dispositions that can support
the twin digital and green transition, and reduce their vulnerability to environmental and
technological changes. Identifying vulnerability due to a lack of proficiency in skills key to a just, inclusive
and sustainable twin transition and reducing it through adequate policy action is critical to improving both
equity in outcomes and overall well-being.

18 
Infographic 1. Key facts and figures
Education is key to raise awareness of
climate change threats
Disadvantaged youths are less likely to
master environmental sustainability
% of adults who perceive climate change as a threat % of 15-year-old students who reach foundational levels of competence
in environmental sustainability
On average across OECD countries, adults with tertiary-level
qualifications are more likely to perceive climate change as a
threat than those without secondary education.
Disadvantaged students are less likely to reach foundational
levels of science proficiency, be aware and care about the
environment, and engage in pro-environmental actions.
Adults without secondary
education
Tertiary-educated
adults
63%
73%
Attitudes towards artificial intelligence
differ by educational attainment
% of adults reporting that AI will be mostly helpful or harmful
over the next 2 decades
55% of tertiary-educated adults reported that AI would be
mostly helpful, while only 39% of non-tertiary-educated
adults said the same.
On average across OECD countries, 81% of girls said that
failing makes them afraid they do not have enough talent,
but only 65% of boys feel the same.
Mostly helpful Mostly harmful
Low socio-economic status High socio-economic status
0
10
20
30
40
50
60
Tertiary-educated adults Non-tertiary-educated adults
Many adults find it difficult to act on
health information in the media
% of adults who report finding it difficult to protect themselves from
health risks using information in the media
Health literacy is critical for people to make use of the large
amount of information available online in order to protect
their health and the well-being of their communities.
0 10 20 30 40 50 60
Austria
Czech Rep.
Norway
Israel
Slovak Rep.
Hungary
Germany
Overconfidence in reading skills is a
challenge for many countries
% of 15-year-olds who are low-achieving and believe they
can read and understand difficult text
0 10 20 30 40 50
Colombia
Mexico
Greece
US
France
Korea
Japan
Girls have a greater fear of failure than
boys in all OECD countries
% of 15-year-old students who are afraid that failing may mean that
they do not have enough talent
Boys
Girls
0 20 40 60 80 100
Japan
UK
France
OECD
US
Türkiye
Germany
0 10 20 30 40 50 60 70
Korea
Canada
Spain
OECD
Mexico
Costa Rica
Slovak Rep.

 19
This chapter reflects on lessons from the COVID-19 pandemic that can
guide reforms in skills policies to strengthen resilience and promote the twin
green and digital transition. These reforms should be seen in the context of
ongoing environmental degradation and the complexity of information
landscapes driven by rapid technological developments. The chapter first
defines resilience and then stresses that promoting system-level resilience
through effective skills policies requires empowering individuals with a wide
range of skills at varying levels of proficiency. The chapter also stresses
that attitudes and dispositions are key enablers of skills development and
effective skills use. Finally, the chapter highlights the importance of
embedding skills policies in the context of comprehensive policy efforts and
of monitoring the economic and social consequences of policy actions.
1 Overview

20 
1.1. Introduction
The coronavirus (COVID-19) pandemic and policy actions aimed at containing its spread had a
profound impact on societies and economies around the world. They are a reminder that societies
can profoundly reorganise themselves if there is urgency, but also that sound policy interventions are
critical to channelling the actions of economic and social actors. At the same time, the pandemic highlighted
how major interventions necessary to reduce a threat – such as viral spread – can create new challenges
for communities and societies. For example, however necessary they were, the closure of schools and all
non-essential businesses during the pandemic came with high psychological, economic, and social costs.
Building system-level resilience and reorganising societies to meet the defining challenges of our time
– climate change, environmental degradation and technological developments in how information is used
and exchanged (the twin green and digital transition) – requires comprehensive interventions to ensure
that future economic growth is both sustainable and inclusive.
Skills policies play a key role in supporting the twin green and digital transition, contributing to
system-level as well as individual resilience. In the absence of adequate investments in education and
training, efforts to ensure that economic growth and development occur within the limits of planetary
boundaries might not be successful and/or lead to short- and medium-term losses of labour market
opportunities. Similarly, without adequate investments in education and training, digital transformations
might be delayed or reduced, and existing innovations might lower social welfare.
Climate change and technological developments in information and communication exchange are
the defining challenges of our time. Globally, July 2023 was the hottest month on record (NASA, 2023[1]).
In particular, in that month, the global average surface temperature was 0.72°C warmer, and the global
average sea surface temperature was 0.51°C warmer than the 1991-2020 average (Copernicus Climate
Change Service, 2023[2]). Between 2017 and 2021, individuals in OECD countries, on average, had to
endure 14 additional days of strong heat stress exposure compared to the period between 1981 and 2010
(IEA/OECD, 2022[3]). Rising temperatures are fuelling weather extremes, wildfires, biodiversity loss and
natural disasters, leading to food and water insecurity, economic disruption, poor health, conflict and
migration.
At the same time, progress in artificial intelligence (AI) and, in particular, the onset of generative
AI is such that, in some areas, its output has become indistinguishable from that of humans. This
suggests that OECD economies may be on the brink of an AI revolution, which could fundamentally change
the workplace (OECD, 2023[4]) and society at large. Estimates suggest that ChatGPT, the chatbot released
in November 2022 by OpenAI, was the fastest-growing consumer application in history after it reached
100 million monthly active users in January 2023, just two months after its launch (Reuters, 2023[5]). The
use of generative AI has far-reaching implications for knowledge production and exchange: it is being
increasingly leveraged in research to expedite the innovation cycle, reduce publication timelines and
promote inclusivity in science by aiding individuals in expressing their ideas fluently, thereby broadening
the diversity of scientific perspectives. However, these models can worsen information problems in online
spaces, in part because large language models produce very convincing text that may be inaccurate and,
in part, because they reduce the time and effort needed to generate fake and harmful content (van Dis
et al., 2023[6]).
The speed of climate change and recent technological innovation is not matched by the speed of
change in education and skills policies. Promoting environmental sustainability requires a profound
rethinking of production and consumption, with important consequences for labour markets and the
demand for skills. The current scale and pace of investments in skills policies are inadequate to significantly
reduce the likelihood of going beyond tipping points, leading to irreversible and severe changes in the
climate system (OECD, 2022[7]), to successfully adapt to changing environmental conditions, and to
leverage technological innovations such as AI and robotics to improve labour market opportunities and
conditions. As AI and robotics are being increasingly deployed in a range of industries, many of the tasks

 21
currently performed by individuals will become automatable, leading to the emergence of new jobs, the
disappearance of some jobs and the transformation of many others (Lassébie and Quintini, 2022[8]).
Yet, as new job profiles and skills requirements emerge, on average across OECD countries, only
around four in ten adults participate in formal or non-formal learning for job-related reasons (OECD,
2021[9]). This hampers the ability of workers to reallocate from sectors and occupations that will shrink into
sectors that will grow in the near future. Moreover, across OECD countries, only three in ten young people
possess at least baseline levels of the cognitive, attitudinal and behavioural dimensions of environmental
sustainability competence and only seven in ten reach baseline levels in all foundation skills that are key
in information-rich societies – reading, mathematics and science – by age 15. Training opportunities that
respond to emerging labour market needs and efforts to facilitate their uptake can promote a just and
inclusive green and digital transition. In turn, education systems that equip young people not only with skills
but also with the attitudes needed to manage change can ensure that the green and digital transition is
sustainable in the longer term.
Successfully building resilience through skills policies also depends on ensuring that skills development is
promoted among the most vulnerable. The pandemic highlighted that social justice and equity
considerations aside, the high level of interconnectedness in modern societies means that the level of
vulnerability of societies is often tied to the actions of the least informed. It also made clear that in
order for societies to reap the benefits of investments in skills development, a renewed emphasis should
be put on equipping individuals with a set of beliefs, attitudes and dispositions that are aligned with
long-term individual and social welfare.
The term “resilience” was originally used in physics and engineering to characterise the ability of materials
to resume their original shape or condition after being subjected to a shock, i.e. a sudden change in
circumstances (Treloar, 1975[10]). The term was later adopted to refer to an individual’s or system’s ability
to overcome adversity and display positive adjustment (Daniel, Wassell and Campbell, 2002[11]; Howard,
Dryden and Johnson, 1999[12]). In this context, resilience refers to the phenomenon where individuals
who have faced adverse experiences exhibit lower levels of vulnerability than initially anticipated.
The goal is to understand the factors contributing to this resilience, including when, how and why it
manifests (Luthar, 2003[13]; Masten and Powell, 2003[14]; Rutter, 2006[15]).
External shocks cannot be altered in the realm of inorganic materials. However, in human societies, the
probability of external shocks occurring can be influenced. Consequently, building resilience involves
mitigating the impact of adverse events but also reducing the likelihood of such events happening
in the first place. Furthermore, individuals can adapt to their surroundings, which means that if
circumstances change over the long term, they can strive to achieve a new equilibrium through adaptation.
In the context of this report, resilience refers to the ability of societies to reorganise themselves in order to:
1) limit future environmental degradation and safeguard information exchange; 2) adapt to current and
foreseen environmental conditions and level of technological development; and 3) adapt to structural
changes in labour markets that will result from the adoption of new technologies and from efforts to reach
climate neutrality. Critically, resilience entails ensuring that such transformations do not create new
forms of labour market and social vulnerability.
1.2. Towards a sustainable and inclusive twin green and digital transition
Estimates suggest that, compared to those born in the 1960s, on average around the world,
children born at the onset of the COVID-19 pandemic in 2020 may experience 6.8 times more
heatwaves during their lifetimes (Luten, Ryan and Wakefield, 2021[16]). However, limiting global warming
to 1.5 C above pre-industrial levels could reduce this additional exposure to heatwaves by 45% (Global
Commission on Adaptation, 2019[17]). Given this outlook, it is critical to not only establish ambitious

22 
strategies to mitigate global warming but also to empower future generations by providing them with the
necessary skills to adapt to evolving environmental conditions and make decisions that foster sustainable
growth.
Decoupling economic growth from emissions growth and addressing the extent to which energy extraction
and human production generate pollutants and create a loss of biodiversity is within the grasp of our
societies. However, decarbonising the economy will profoundly impact labour markets worldwide in the
coming years and decades. The green transition could boost economic growth, but the speed and
efficiency with which the transition will occur depends on individuals having the right set of skills to sustain
and power green innovations. Moreover, and equally important, unless all individuals have the right set of
skills, labour market transformations due to the transition to net-zero emissions could create social tensions
and ultimately derail or at least slow down progress towards a new growth paradigm that does not depend
on environmental degradation. Education and training systems can support resilience by ensuring
that most people possess the right skills needed to adapt to existing environmental changes, to
create the technologies that will propel the green transition, to work in the new jobs that will be
created as a result of the green transition and to adopt behaviours better aligned with the
achievement of environmental objectives.
Human action also drives the quality of the information landscape. Throughout history, technological
innovations have profoundly impacted individuals’ capacity to acquire, use and exchange information.
From the invention of writing to the printing press, from the advent of the Internet to the onset of generative
AI, technological developments have facilitated new possibilities for individuals to connect and interact with
others. At the same time, alongside benefits arising from cheaper and faster information exchange,
societies have had to develop ways to adapt to such technological advances. For instance, the advent of
the printing press and the subsequent proliferation of printed materials facilitated the dissemination of
misinformation and thus posed a challenge in terms of ensuring the accuracy and reliability of information.
Developments in social media and AI are creating similar problems.
Information is critical to enable individuals to make informed decisions. Technology plays a fundamental
role not only in giving people access to information but increasingly in directly extracting and generating
the information that is exchanged. During the pandemic, information allowed individuals to safeguard their
health and the well-being of others. However, the pandemic also demonstrated that unless people have
adequate levels of skills to access, filter, assess and process information, exposure to misleading,
inaccurate, and false information can lead communities to experience worse rather than improved
outcomes.
Communication is key in today’s interconnected world. Of the estimated 8 billion people who lived
in the world at the end of 2022, about 5 billion were connected to the Internet (World Bank, 2021[18]).
The Internet dramatically increased the amount of information that is accessible and exchanged around
the world. But quantitative increases in the amount of information that is available on line have not
necessarily been accompanied by increases in the quality of such information, and the emergence of
generative AI systems is changing yet again how information is extracted and generated. To reap the
benefits of emerging information societies, countries need to have an adequate pool of individuals who
possess the skills to develop, adapt and maintain AI applications since these underpin how information is
collected, used and exchanged. In addition, countries need to ensure that, whether on or off line,
populations have the full set of skills that allow them to integrate new technologies into their work and
everyday lives to improve their productivity and well-being.
1.3. Skills for a resilient green and digital transition
Reorienting the economy so that economic growth occurs within planetary boundaries and ensuring that
rapid technological developments do not create new social and economic vulnerability may change the set

 23
of tasks individuals will have to perform. Such change is likely to require individuals to rely on a renewed
set of skills in their work and everyday life. As a result, education and training systems will have to adapt
to align skills development opportunities with emerging skills needs in labour markets and society more
widely. Emerging skills needs that are critical to build system-level resilience to the green and digital
transition at the population level require:
• Focusing efforts to improve information-processing skills among low-proficiency adults.
Skills such as literacy, numeracy and digital literacy allow individuals to access, analyse, interpret,
summarise, organise, store, retrieve and communicate information. The emergence of knowledge-
rich societies in which value rests on the ability to gather, use and exchange information effectively
means that individuals without at least baseline levels of proficiency in information-processing skills
will increasingly be at risk of economic and social exclusion. Increases in the complexity of the
information landscape result in more information becoming available from a variety of sources,
heightening the need for all individuals to be able to analyse, interpret, and organise information.
Similarly, the growth of job profiles resulting from the green transition in service industries and
industries with a high technological content increases the demand for workers who possess skills
to effectively manage quantitative and narrative information.
• Prioritising the acquisition of socio-emotional and communication skills for all. Skills such
as the capacity to collaborate with others, manage emotions, persevere in difficult circumstances
and effectively communicate with diverse groups enable individuals to effectively navigate their
social environments and make responsible decisions. These skills are critical to building a resilient
green and digital transition because these are uniquely human skills and, therefore, not easily
automatable even with advances in AI in the near future. Moreover, the collective effort needed to
promote the green transition rests on the capacity of communities to negotiate conflict and pool
collective expertise to solve complex systemic problems.
• Raising awareness about the role of metacognitive skills. Metacognitive skills refer to the
ability to think about and regulate one’s own thinking processes, monitor and evaluate one’s own
learning and understanding, and plan, set goals, and adjust strategies to meet those goals. There
is increasing evidence of the role played by heuristics, biases and cognitive profiles in shaping
decision making. Metacognitive skills are critical if individuals are to regulate their behaviour. In the
face of uncertainty induced by climate change and technological developments, metacognitive
skills allow individuals to recognise the role of heuristics and biases in shaping decision making
and make more informed use of knowledge and information. Metacognitive skills, in fact, empower
individuals by helping them characterise knowledge and knowledge generation processes and can
help individuals effectively work alongside others – whether humans or machines. They help
individuals and communities solve complex problems and develop reasonable risk mitigation
strategies both at individual and societal levels.
1.4. Adapting investments in skills development to a changing context
The speed and complexity of changes associated with green and digital transition require profound
transformations in how education systems equip young people with the skills, as well as the knowledge
and attitudes, to thrive in the future. At the same time, they require adults to continuously adapt to match
new labour market and social demands through a renewed commitment to adult education and training in
all its forms – including formal, non-formal and informal learning.
Recognising the range of skills individuals have and valuing the potential of individuals to become
proficient in different domains widens the scope for greater participation in training programmes.
Skills can be acquired through experience and lost through lack of use. Therefore, the level of skills of
workers is not just about individual workers; it is also a reflection of how production processes are

24 
structured and whether individuals have been given the opportunity to build their skills or not. Recognising
the potentially wide range of skills and levels of proficiency workers possess can, in turn, motivate both
employers and employees to invest in skills development: workers because they are empowered in their
capacity to acquire skills, and employers because they can see the potential returns associated with
investments in skills development.
One step for skills policies to promote resilience and a lifelong learning culture, as well as support the
green and digital transitions, is to advocate for a change in how workers are classified. Workers in blue-
collar occupations are generally referred to as being “unskilled” or “low-skilled” and managers
and professionals as “high-skilled”. However, high and low are adjectives that classify skills depending
on the level of proficiency, not the type of skills individuals possess. This means that, for example, a blue-
collar worker may have high levels of fine motor and problem-solving skills and low levels of programming
skills, whereas the opposite may be true of a professional. The fact that certain skills may be more relevant
than others in specific contexts – and therefore yield a comparative advantage and are therefore in high
demand – says as much about the context individuals operate in as about the skills individuals possess.
Standard characterisations of manual workers as being “unskilled” or “low-skilled” and
professionals as being “high-skilled” reduce the incentives individuals with different occupations
have to invest in lifelong learning. Manual workers may be led to believe that acquiring proficiency
in a wider range of skills is beyond their capacity, and professionals may be led to believe that they
do not need to invest further in skills development. As such, they limit the scope of skills policies and
potentially create labour market inefficiencies. This characterisation arises from a traditional view of skill
acquisition focused solely on educational qualifications acquired through formal schooling. To an extent,
this is due to the fact that educational qualifications are the only information available in labour force or
other social surveys used to map and study labour markets. At the same time, because of historical
developments in education systems, focusing on educational qualifications in most contexts has the
unintended consequence of leading to a hierarchical vision of education systems in which academically
oriented programmes command a higher status than vocationally oriented programmes.
Effectively promoting system-level resilience first requires identifying emerging skills needs and
prioritising investments to ensure that support reaches those vulnerable to changing conditions.
Second, it requires identifying what proficiency benchmarks in a given skill individuals need to reach to be
able to behave at work and in everyday life in ways that align with the achievement of such objectives.
Third, it requires policy makers to ensure that individuals are able to progressively reach such benchmarks
as labour market and social arrangements evolve, prioritising skills investments to meet the demands of
vulnerable populations.
Promoting a culture of lifelong learning goes hand in hand with fostering equal access to education
and training opportunities (OECD, 2023[19]). Lifelong learning opportunities should be created to fulfil the
needs of a diverse set of individuals. Policy makers should create flexible education and training
opportunities that take into account individuals’ unique barriers to participation (including lack of time or
financial resources, caring responsibilities, lack of prerequisites, lack of knowledge about opportunities)
and target groups in greatest need of support. Examples of efforts aimed at empowering individuals and
reducing financial barriers to participation include individual learning accounts – such as the French
Compte Personnel de Formation (OECD, 2019[20]) – or vouchers, coupons provided to individuals or
companies to cover direct training costs, as for example, the Bildungsprämie in Germany (OECD, 2021[21]).
Pre-apprenticeship programmes can facilitate the integration of migrants into regular vocational education
and training (VET) programmes, such as the case of Integrationsvorlehre in Switzerland (OECD, 2023[22]).
Flexible measures have been used in Denmark to allow learners who already fulfil specific requirements
to skip parts of their VET programme, thus shortening the length of training significantly and increasing
motivation to learn during the programme (Ministry of Children and Education, n.d.[23]).

 25
This report maps the distribution of skills that are key for the twin green and digital transition
across and within countries and for different population groups. Mapping these skill distributions can
assist in the formulation of effective skills policies aimed at reducing vulnerability to emerging threats.
Specifically, the report identifies populations with limited proficiency in key skills (such as information-
processing skills), thereby enabling targeted investments in policies to address the limited proficiencies.
By addressing the vulnerability of the identified populations, broader local and global communities can also
benefit from reduced vulnerability.
1.5. The role of attitudes and dispositions
Decisions concerning the skills individuals and societies invest in, whether such skills are
mobilised, and the goals pursued through their use depend on the attitudes and dispositions
individuals hold and the values societies prioritise. Attitudes and dispositions play a pivotal role in
driving individuals’ motivation to utilise their skills and enhance how effectively skills are used. For instance,
recognising the importance of promoting environmental sustainability is essential to motivating individuals
to integrate sustainable practices into their daily lives as consumers. Attitudes are also critical if individuals
are to consider strategies to enhance environmental sustainability in their workplaces and apply scientific
knowledge to develop solutions in this domain. It is noteworthy that many skills that can contribute to
environmental sustainability can equally be utilised for environmental degradation, with the divergence
solely determined by the type of activity workers are engaged in and, to some extent, even their own
attitudes and dispositions. For example, proficiency in physics and chemistry can be used to develop ways
to reduce system-level dependency on energy generated through fossil fuels or, by contrast, to devise new
ways to extract fossil fuels from natural reserves. Similarly, the technical skills required to develop AI
systems that may propagate false information endangering public health can also be employed to facilitate
health promotion and the adoption of preventive measures. Individuals’ choices in utilising their skills
depend on their attitudes and dispositions.
Equipping all individuals with skills is a necessary – but not a sufficient – condition to facilitate the
green and digital transition. Attitudes and values are also essential. Societies must nurture in
generations, new and old, not only a sound understanding of the challenges arising from climate change,
environmental degradation and technological advancements in information exchange but also a deep
appreciation for the fragility and intricacy of physical and digital ecosystems. Similarly, new attitudes and
dispositions are needed if societies are to adapt to new digital environments. This is especially the case
given very recent advances in generative AI systems and their potential to profoundly reshape information
ecosystems.
Education and skills policies are crucial in tackling challenges associated with the green and digital
transition and building resilience at the individual, community and system levels. Education and
training systems should accompany skills development with the development of attitudes and dispositions
that can sustain the effective use of skills. Attitudes and dispositions are key enablers of skills investments.
Skills do not translate into meaningful action without the will to act.
1.6. The green transition and how skills policies can promote resilience
Reorienting the economy to create an environmentally sustainable future requires the adoption of
environmentally sustainable production and consumption practices. Skills policies can promote system-
level resilience by:
1. strengthening the environmental sustainability competence of individuals

26 
2. ensuring that achieving ambitious climate objectives does not lead to labour market
vulnerability
3. developing the range of skills and attitudes needed to adapt to new environmental
conditions.
1.6.1. Strengthen the environmental sustainability competence of individuals
Environmental sustainability competence comprises the knowledge, skills, attitudes and values that are
critical to promoting environmental sustainability. It enables individuals to tackle environmental challenges,
adopt practices in their work and everyday life that promote environmental sustainability, be ready to work
in future green jobs and be environmentally thoughtful consumers. Yet, this report finds that on average,
across OECD countries, only 31% of 15-year-old students have baseline levels across all key dimensions
of environmental sustainability competence, meaning that they achieve at least a baseline level of science
proficiency; have an awareness of climate change and global warming; care for the environment; have
environmental self-efficacy; and are engaged in behaviour to promote environmental sustainability.
Furthermore, large disparities exist in the extent to which education systems and societies equip children
with environmental sustainability competence. In particular, 21% of socio-economically disadvantaged
youths, but 46% of their more advantaged peers, had mastered the foundation skills and mindsets they
will need to find employment in the new green economy and to act for environmental sustainability as
consumers. Although science proficiency is the key information-processing skill underpinning the capacity
of individuals to contribute to and thrive in a low-carbon economy, attitudinal and dispositional components
of environmental sustainability are powerful drivers of engagement in environmentally sustainable
behaviours together with knowledge and skills. Worryingly, inequalities in attitudes and dispositions mirror
inequalities in science proficiency – such as in the case of socio-economic inequalities – or are wider than
inequalities in science proficiency – such as in the case of inequalities between genders. Given the key
role played by emotional, attitudinal and behavioural dimensions of environmental sustainability
competence and the fact that these dimensions can be acquired through repeated exposure to role models
and long-term socialisation, environmental protection should be made a shared cultural and social norm.
Investing in building environmental sustainability competence among young people and adults should thus
be comprehensive and entail:
• Ensuring that the appreciation and protection of the environment is taught and nurtured
from an early age and continued over the life course. Education systems should promote more
equitable learning of environmental competence to make sure that today’s marked socio-economic
divide in environmental sustainability competence between students with a high and low
socio-economic status is mitigated. Although this requires whole-of-society efforts between
parents, the education system and other social institutions, the education system can promote
early childhood education and care programmes that aim at teaching children environmental
sustainability competence from the early years. Such efforts should be the foundation upon which
education systems then continue to support the acquisition of environmental sustainability
competence. Furthermore, since many adults remain ill-informed about the threats arising from
climate change and environmental degradation, environmental awareness among adults should
be expanded through sensitisation campaigns about the threats of climate change and the
importance of adopting behaviours that reduce environmental degradation.
• Empowering teachers and trainers to support the acquisition of environmental
sustainability competence. Initial teacher training programmes and professional development
modules should be reviewed and updated to ensure that teachers are aware of the importance of
integrating aspects related to the development of environmental sustainability competence in the
curriculum and have the pedagogical and content knowledge needed to do so. Such programmes
should be regularly updated to integrate new knowledge and information on environmental

 27
challenges and on the effectiveness of different approaches to promote the development of
environmental sustainability competence in the classroom.
• Promoting the development of environmental sustainability throughout the lifecycle. The
understanding of the impact of human actions on the environment, key environmental phenomena
and possibilities to promote environmental protection have evolved dramatically in the recent past.
Efforts in the early years should be complemented by the opportunity to update their environmental
sustainability competence later in life, as well as programmes tailoring individuals already in the
labour market who did not benefit from any training in environmental sustainability early on.
Whenever possible, adult training systems and sensitisation campaigns should build on early
interventions by providing individuals with up-to-date information on environmental degradation. At
the same time, efforts should be made to identify individuals who did not benefit from early
interventions while in school and provide tailored programmes aimed at supporting their acquisition
of the knowledge, skills, attitudes, and values that are critical to promoting environmental
sustainability via training programmes. Furthermore, as environmental degradation has worsened,
many individuals who were sceptic about the urgency of climate action have realised the need to
develop and sustain initiatives to protect the environment. New generations who are working
towards protecting the environment can be powerful agents of change, mobilising prior generations
and helping them establish a new environmental consciousness and awareness.
1.6.2. Ensure that achieving ambitious climate objectives does not lead to labour market
vulnerability
Ambitious climate mitigation policies will be needed to limit climate change and halt environmental
degradation. Although these policies are essential to avert environmental collapse, they will affect labour
markets and the demand for skills in the next decade. Building system-level resilience requires minimising
the economic and social cost of the green transition, so anticipating possible unintended effects of efforts
aimed at decarbonising economies on labour markets is critical to putting in place adequate policy
responses. This report considers the effects of policies in countries in the European Union as a case study
to consider how policies will have to adapt to ensure that the skills workers possess are aligned with the
skills that will be demanded in the economy. The case of the European Union is instructive because of the
ambition of the policy package being implemented, the number of jurisdictions being affected and the
availability of timely data. Projections indicate that reducing greenhouse gas emissions in the
European Union by 55% by 2030 through the European Union’s Fit for 55 policy package can be achieved
without a decrease in overall labour market opportunities and, in fact, with a small gain in employment.
However, according to OECD projections the policy is projected to result in overall lower employment for
blue-collar workers. Minimising labour market mismatches arising from the policies is, therefore, critical to
reducing delays and transition costs for individuals and businesses. Moreover, because evidence suggests
that whenever in a country unemployment increases, public support for environmental action decreases,
reducing the social and economic costs associated with the implementation of climate change mitigation
policies is critical to guarantee sustained public support for such policies. Supporting workers in localities
particularly affected by downsizing activities that generate high levels of CO2 emissions through labour
market and social policies is critical. In this regard, ensuring the effective and inclusive implementation of
policies aimed at reducing greenhouse gas emissions entails:
• Coupling climate change mitigation policies with technological adoption to facilitate a green
transition that promotes employment growth. Thanks to technological adoption and diffusion,
projections indicate that climate change mitigation policies can be achieved while still promoting
sectoral and employment growth. Successfully achieving decarbonisation, as well as economic
and job growth, depends on ensuring the adoption of digital technologies and on improvements in
labour productivity related to technology use. Many of the skills projected to increase in demand
between 2019 and 2030 relate to the development and use of digital tools and applications or to

28 
interpersonal communication, management and leadership. By contrast, many of the skills
projected to decline in demand relate to using tools and machinery. This is because the
implementation of Fit for 55 is expected to accelerate the existing trend, leading to a structural
reallocation of employment opportunities from blue-collar and manual jobs to jobs in the service
economy.
• Considering the distributional implications of policies aimed at reducing greenhouse gas
emissions. The modelling results indicate that although overall employment is projected to grow
between 2019 and 2030, even under the implementation of ambitious initiatives to reduce
greenhouse gas emissions, employment is projected to shrink considerably in some sectors and
for some workers. In particular, the employment of blue-collar workers is projected to shrink, and
in some sectors, such as mining coal and lignite, it is projected to shrink by as much as 90%.
Because the distribution of workers in different sectors and occupations differs across countries as
well as across regions, within most countries, some countries/localities will be especially hard hit
by job losses. The geographical distribution of workers by sector and occupation should be
evaluated in the development of adequate policy responses aimed at facilitating their redeployment
in sectors and occupations for which labour demand will increase. In fact, in the case of the
European Union the Recommendation on ensuring a fair transition towards climate neutrality was
adopted in 2022 to take into account the distributional implications of the transition. The
Recommendation invites EU member states to adopt measures to address the employment and
social aspects of climate, energy and environmental policies, encouraging the adoption of actions
to support people most affected by the green transition for instance by stimulating the creation of
quality jobs and facilitating access to safe working conditions protecting health and safety in the
context of this green transition (Council of the European Union, 2022[24]). The Recommendation
also puts a focus on education and training measures, inviting EU member states to integrate the
employment and social aspects of the green transition in the development and implementation of
relevant national strategies (Council of the European Union, 2022[24]). Other proposals concentrate
on fairness of tax-benefit and social protection systems and on ensuring access to affordable
essential services and housing for people and households most affected by the green transition.
The effects of policies aimed at decarbonising economies should be adequately and continually
monitored to ensure that policies aimed at supporting displaced workers are timely and tailored to
these workers’ needs. Minimising transition costs (including economic costs and reduced overall
well-being) requires organising social protection to support groups of individuals for which viable
labour market transitions are not feasible or are too costly to be implemented and organising
training for those for whom such transitions are available. In particular, anticipation efforts should
consider the profile of displaced workers in order to facilitate their redeployment in sectors for which
labour demand is projected to grow, with the aim of anticipating the intensity of training needs and
organise both upskilling and reskilling efforts to reduce mismatches and facilitate inter-sectoral and
inter-occupational mobility. Alongside the development of learning opportunities that are
responsive to emerging needs, efforts should be made to improve the accessibility of such
opportunities for diverse groups of learners. Even in the absence of the additional demands arising
because of labour market changes induced by the green transition, participation in adult learning
opportunities is low, particularly among many of those who would most benefit from taking part in
lifelong learning. Efforts should reduce the effects of external barriers (for example, time, cost, lack
of information, architecture) and internal barriers (for example, lack of motivation, lack of
prerequisite skills) to participation.
• Investing in career guidance and working with employers to develop new hiring practices.
Career guidance and educational orientation programmes can assist individuals of all ages in
making well-informed educational, training and occupational choices and in managing their
careers. At the same time, formal educational qualifications remain a key criterion guiding
employers in hiring decisions. Although this may be changing due to the large and persistent skills

 29
shortages employers face in some sectors, skills-based hiring will have to become more
widespread and accepted if the deployment of workers across sectors and occupations following
engagement in training courses is to be successful. Although qualifications and degrees from initial
education and training will continue to play a key role, alternative credentials (including digital
badges, micro-credentials, nano credentials, minor awards, etc.) will be critical to ensure that more
adults engage in adult learning opportunities and to provide more adequate information on workers’
skills and proficiencies to prospective employers.
• Investing in adequate labour market and skills data. Existing data collection instruments in
many OECD countries are not well suited to mapping economic activities and employment
distribution. Most of the literature overcomes these limitations by using data from the United States
and assuming that the skills required of different occupations in different countries match the skills
content estimated in the United States using the O*NET database. However, since an important
effect of the green transition will be the reorganisation of production to reach green objectives and
the fact that countries might follow different trajectories, it will be important to ensure that adequate
data will be collected to support evidence-based policy making. In particular, highly detailed
sectoral and occupational data are needed to identify how aligned with green objectives different
labour market opportunities are.
1.6.3. Develop the range of skills and attitudes needed to adapt to new environmental
conditions
Despite the most ambitious mitigation efforts, a certain degree of climate change is already inevitable due
to past emissions. Therefore, it will be necessary to implement a variety of adaptation policies to reduce
the vulnerability of individuals and societies to the impacts of climate change and environmental
degradation. Events such as wildfires, extreme temperatures and flooding can disrupt skills acquisition
directly by forcing the closure of schools and increasing absenteeism but also indirectly by reducing the
potential of individuals to learn when they are in class and to achieve their full potential during high-stakes
exams. Socio-economically disadvantaged children and adults are more likely to suffer the negative
consequences of adverse environmental conditions. This is because they are often more exposed to poor
environmental conditions and lack the resources to invest in adaptation technologies or protective
behaviours. Promoting the successful adaptation of learning systems to climate change entails:
• Preparing learning environments for extreme temperatures and weather events. Education
and training systems should develop emergency protocols to protect students and staff during
extreme weather events and ensure the continuity of instruction during such events. This can
include measures such as installing emergency generators, establishing evacuation plans and
providing training on safety and how to respond to emergencies. Schools and training institutions
should also reduce their carbon footprint and increase their resilience to extreme weather events,
saving on operating costs and repair work. Designing workplaces to ensure adequate
environmental conditions is also key to promoting workers’ safety, productivity and effective use of
skills.
• Considering the differential effects of environmental conditions on the acquisition of skills
and on inequalities in skills development. Reorganising when and where learning takes place
may help reduce overall exposure and thus mitigate the largest effects on cognition. Ensuring that
classrooms have cooling devices or good ventilation can also attenuate the overall effects of
extreme temperatures on cognition. Furthermore, because socio-economically disadvantaged
groups are often more exposed to worse environmental conditions and have less access to
mitigation technologies, investments should prioritise the reduction of the impact of environmental
conditions on inequalities in learning conditions and conditions during high-stakes testing.

30 
• Accompanying investments in adaptation infrastructures with a focus on the full set of skills
needed for successful adaptation. Infrastructural investments in adaptation should be
accompanied by investments in building the full set of skills individuals need to be resilient to
extreme weather events. Skills policies could include a focus on the skills necessary to keep safe
under extreme weather events as well as physical skills such as the ability to swim without
assistance and the ability to ride bicycles. Even though education systems in many OECD
countries have prioritised the acquisition of cognitive skills and the transmission of knowledge, the
green and digital transition requires a greater balance between investments in academic domains
and physical education (OECD, 2019[25]). Partnerships with not-for-profit organisations could be
promoted to ensure more individuals possess skills that will be needed to be safe during extreme
weather events and achieve personal autonomy, safety and well-being.
• Ensuring that public support for sustainable investments following extreme weather events
translates into long-term change. Whereas education programmes can easily reach young
people with the aim of equipping them with environmental sustainability competence and the skill
set needed to adapt to climate change, adults are harder to reach. Public information campaigns
and initiatives aimed at empowering individuals with the knowledge and skills needed to adapt to
new environmental challenges should build on public interest and support for actions prioritising
the environment in the aftermath of natural disasters. Governments should provide clear and
consistent messaging to the public about the need for sustainable investments in the wake of
extreme weather events, explaining the link between climate change and extreme weather events
and highlighting the importance of long-term sustainable investments. Sustainability plans should
outline specific measures to address climate change and promote sustainable investments. They
should be developed in collaboration with a wide range of stakeholders, including the public, and
regularly updated to reflect changing circumstances.
1.7. The digital transition and how skills policies can promote resilience
Recent technological innovations have profoundly changed how information is collected, stored, used,
generated and exchanged. Supporting further technological innovations while ensuring that technological
developments enhance the economic well-being of broad populations rather than only a few, and
addressing the possible negative effects of new technologies on health, well-being and social cohesion
requires:
1. identifying emerging skills needs to more effectively operate in information-rich societies
and work alongside emerging generative AI systems
2. promoting health literacy to protect communities from infodemics
3. supporting language learning to facilitate interlinguistic communication
4. strengthening a wider set of skills and attitudes AI professionals need to be able to develop
ethical and trustworthy AI systems.
1.7.1. Identify emerging skills needs to more effectively operate in information-rich
societies and work alongside emerging generative AI systems
With the rise of social media, the decline of traditional news outlets and advances in the capabilities of AI
technologies, particularly generative AI, there has been a proliferation of information available to individuals
around the world. However, quantitative increases in the amount of information available have yet to be
accompanied by increases in the trustworthiness of such information and in an understanding of how best
individuals can use the power of new technologies in making use of information and data to improve their
productivity and personal well-being. On the one hand, new technologies are leading to an increase in the

 31
amount of false or misleading information individuals are routinely exposed to and a decrease in how much
individuals trust institutions. The ease with which information can be produced and shared is also leading
to information overload on the part of potential users because many lack the ability to effectively manage
information flows. As a result, some individuals feel overwhelmed, and others unwillingly and unknowingly
spread false or misleading information. The ability to evaluate the quality of information and the ability to
seek, retrieve and propagate relevant information rests on a range of cognitive and metacognitive skills,
knowledge, as well as attitudes and dispositions. On the other hand, AI has the potential to profoundly
impact all industries and occupations that rely on data and information, automating a wide range of tasks
currently performed by humans. Many of today’s political and social tensions arising in response to the
automation of tasks made possible by advances in AI revolve around the questions of whether technologies
will substitute or complement workers, give rise to better or worse labour market conditions, and ultimately
whether they will be associated with an increase or a decrease in labour market opportunities. Ensuring
that all individuals possess the full range of skills and attitudes to effectively deal with technological
advances in how information is shared and used entails:
• Integrating media literacy programmes in education and training programmes. Media literacy
education should become part of national curricula starting in primary school years and continuing
in secondary and tertiary academic and vocationally oriented programmes. Students could also be
trained in lateral reading, the process of comparing untrusted information to other, more trusted
sources. Studies have found that lateral reading interventions can be useful in improving
information handling. Giving people the opportunity to deliberate has been found to positively
impact truth discernment. If people can follow a quick evaluation of a headline with the opportunity
to re-evaluate, they show less belief in false news.
• Reorganising learning so that young people develop an understanding of the different ways
in which knowledge is acquired. Teachers can introduce students to different ways of developing
knowledge, such as inductive and deductive reasoning, discuss how epistemic beliefs can
influence scientific thinking, and encourage young people to explore scientific concepts through
inquiry so that they can gain a deeper understanding of how scientific knowledge is constructed.
Collaborative learning can also help young people develop more sophisticated epistemic beliefs
by exposing them to different perspectives and ways of thinking. Finally, group work can also help
students develop communication skills and improve their ability to articulate their own beliefs. Such
efforts could be strengthened by programmes aimed at prompting individuals with media literacy
information before they engage in social media or other online sources that might expose them to
misleading or false information.
• Including the development of metacognitive skills as part of learning objectives. More focus
should be placed on developing metacognitive and critical thinking skills: individuals’ actions and
behaviours are shaped by cognitive biases, which can be transitory (for example, due to fatigue)
or permanent (for example, because of framing effects). Individuals should be educated about the
role cognitive biases play in decision making, and their metacognitive skills should be promoted to
limit the harmful effects of such biases. Teachers play an important role in developing students’
awareness of their own skills and abilities, as well as their critical thinking skills. It is crucial to
encourage teachers to teach critical thinking in different subjects and help young people develop
an awareness of their own skills and limitations. Embedding critical thinking in all subjects is
considered more beneficial than generic critical thinking interventions. For example, teachers could
choose questions and tasks that put more emphasis on particular forms of reasoning and connect
this reasoning to real-world use in and outside their fields. Individuals should also develop the
ability to recognise the information context they are exposed to, for example, what the type of
moderation specific platforms use, their policies if users break the terms of service and their policies
on content removal.

Inteligencia Artificial

Related slideshows

More Related Content

Similar to Inteligencia Artificial

Similar to Inteligencia Artificial (20)

More from 20minutos

More from 20minutos (20)

Recently uploaded

Recently uploaded (20)

Inteligencia Artificial