1.5° PATHWAYS

Page 245

CHAPTER 6

6.1 INTRODUCTION

Bioenergy plays a key role in the energy transition compatible with meeting the 1.5°C climate goal (IRENA, 2021a). Direct use of biomass is important in end-use sector decarbonisation, while bioenergy coupled with CCS can produce negative emissions (see Chapter 1). The increased use of biomass to replace fossil fuels both as energy sources and as feedstocks for chemicals and other materials is also essential to IRENA’s 1.5°C Scenario. The modern and efficient use of biomass to produce energy has risen in recent years. But use will need to accelerate more rapidly if the levels of bioenergy in IRENA’s 1.5°C Scenario are to be achieved. Such an acceleration faces several challenges, including the higher cost of many bioenergy options compared with fossil fuels, the sustainability and availability of bioenergy feedstocks, the need for some new advanced technologies, and the establishment of extensive biomass supply chains, including those involving international trade in biomass commodities. While bioenergy plays a crucial role in climate change mitigation, there are also complex interactions in climate change adaptation, impacts and vulnerability. As the IPCC has pointed out, poorly implemented bioenergy can compound climate-related risks to biodiversity, water and food security, and livelihoods (IPCC, 2022a). At the same time, climate change itself can threaten the viability of energy crops or bioenergy plantations. A delicate balance will have to be found through an enabling policy framework delivering the necessary growth while minimising harmful environmental or socioeconomic impacts. This chapter explores in detail how bioenergy currently contributes to energy demand and can help to reduce GHG emissions in IRENA’s 1.5°C Scenario. It shows how the volumes of sustainable biomass feedstocks would need to expand and then considers the main challenges in scaling up use of biomass in key applications, including policy uncertainty, cost competitiveness, market access and technology readiness, and the policy options to overcome these. The chapter also considers the likely availability of sustainably sourced biomass feedstocks and issues relating to the sustainability of bioenergy and the wider bioeconomy.

245


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References

36min
pages 334-349

7.6 Case study: The European Union

2min
pages 332-333

Annex

3min
pages 350-352

7.5 Risk mitigation of supply shortages

9min
pages 325-331

7.2 What are critical materials?

1min
page 295

6.4 Availability of sustainable biomass feedstocks

12min
pages 274-281

6.5 Biomass sustainability

14min
pages 282-289

7.1 The role of critical materials in the energy transition

4min
pages 293-294

6.1 Introduction

1min
page 245

6.3 Scaling up bioenergy use in key applications: Opportunities, barriers and policies

29min
pages 258-273

5.3 Special focus: International trade of hydrogen and derivatives

14min
pages 234-241

5.1 Power system flexibility 5.2 Electrification of end-use

16min
pages 196-206

CHALLENGE

2min
pages 30-31

4.2 Priority action areas to scale up progress

41min
pages 165-189

Introduction

4min
pages 28-29

3.2 Policy baskets for a sensitivity analysis

16min
pages 121-129

3.1 Introduction

8min
pages 114-120

2.9 Policies for a just energy transition

8min
pages 108-111

Acknowledgements

1min
page 3

1.1 Introduction

0
page 32
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