The Global Energy Perspective 2023 models the outlook for demand and supply of energy commodities across a 1.5°C pathway, aligned with the Paris Agreement, and four bottom-up energy transition scenarios. These energy transition scenarios examine outcomes ranging from warming of 1.6°C to 2.9°C by 2100 (scenario descriptions outlined below in sidebar “About the Global Energy Perspective 2023”). These wide-ranging scenarios sketch a range of outcomes based on varying underlying assumptions—for example, about the pace of technological progress and the level of policy enforcement. The scenarios are shaped by more than 400 drivers across sectors, technologies, policies, costs, and fuels, and serve as a fact base to inform decision makers on the challenges to be overcome to enable the energy transition. In this article, we examine key bottlenecks that may need to be overcome for the energy transition, as well as the opportunities they could bring.
As economies recover from the recent energy crisis, there is opportunity to reflect on the progress of the energy transition. For example, 2023 saw strong growth in the build-out of multiple low-carbon technologies for energy production and consumption. Despite uncertainties including price spikes, volatility, and security of supply, the uptake in solar photovoltaic (PV), electric vehicles (EVs), and electric heat pumps was higher than ever before, and the expansion of wind capacity in 2022 was the third highest on record (after 2020 and 2021), despite significant challenges in the industry, particularly in offshore wind. Five low-carbon technologies are projected to be critical for the energy transition: solar, wind, EVs, heat pumps, and green hydrogen. These belong to a larger family of climate technologies needed to deliver a deep decarbonization of the whole economy.
Yet, going forward, multiple bottlenecks need to be overcome for the continued growth of these low-carbon energy technologies. While concerted action would be needed to address these bottlenecks, the growth trajectory of these important technologies could offer major opportunities for investment and innovation—and overcoming the hurdles would help keep the energy transition on track.
Progress has been made over the last decade
The last decade has seen the net-zero transition gain momentum. There has been a significant increase in governmental and corporate commitments for decarbonization. The Paris Agreement has been adopted by 196 parties, representing 98 percent of greenhouse gas (GHG) emissions, and more than 80 countries have integrated net-zero objectives into law or policy documents.1 More than 700 companies have integrated net-zero objectives into their strategies, and low-carbon investments increased every year by around 20 percent since 2013, reaching $1.6 trillion in 2022.2
However, despite this progress, more must be done to reach key climate goals. With the current rate of global emissions, the carbon budget required for a 1.5°C pathway is projected to be depleted before 2030, and temperatures are projected to rise by 2.3°C by 2050 in the Current Trajectory scenario. Accelerating the uptake of low-carbon energy technologies and reducing emissions is therefore a key priority for the energy transition.
More must be done to control rising temperatures
Over the last decade, key low-carbon energy technologies such as wind and solar power, have grown their share in the energy mix from 1 percent to 3 percent in 2022.
Solar PV has seen cost reductions of 90 percent, while costs have dropped by 60 percent for onshore wind and by 70 percent for offshore wind. Efficiency has also improved by 25 percent for solar PV and 45 percent for onshore wind.1
These technologies have also seen rapid scale-up, with an annual growth of 53 percent, 21 percent, and 9 percent CAGR between 2013 and 2022 for EV sales, solar capacity additions, and total wind capacity additions, respectively.
However, to meet current global net-zero commitments, the speed at which wind and solar generation needs to scale has to grow fourfold (from 2 percentage point increase between 2012-2022 to 8 percentage point increase in 2022-2032). Under the Achieved Commitments scenario, around a third of the energy mix needs to come from low-carbon energy sources by 2032, with growth needing to come from both new and legacy low-carbon energy sources.
Five low-carbon technologies are projected to be critical for the energy transition
To reduce emissions and increase the pace of decarbonization, the rapid scale-up of several key low-carbon energy technologies may be necessary. In particular, electrification is key to reducing emissions, which will require both switching end-use demand to electricity (for example, EVs and heat pumps, and green hydrogen for hard-to-abate sectors like heavy transport and industry), as well as generating low-carbon power, such as solar and wind.
Our analysis shows that five key technologies are projected to be major drivers of the energy transition: solar, wind, EVs, heat pumps, and green hydrogen. Together, they could be responsible for more than half of emission abatement, beyond energy efficiency and demand reduction levers. The bottom-up energy transition scenarios in this analysis project a strong scale-up globally of these five key technologies in the next decade:
- installed solar capacity is projected to grow by three to four times;
- installed wind capacity is projected to grow two- to threefold;
- the share of EVs in total passenger car sales is projected to grow by two to five times;
- the number of installed heat pumps is projected to grow by three to seven times; and
- installed electrolyzer capacity is projected to grow 5 to 27 times.
Overcoming bottlenecks may be critical for scaling up key technologies
Scaling up these technologies at the necessary pace to keep in step with global net-zero commitments is projected to require significant effort, including the expansion of supply chains, which could pose major challenges. We stress-tested different scenarios for these five key electrification technologies by assessing them across six potential bottlenecks that could restrict their growth, with the aim to better understand the following questions:
- Materials: Will there be sufficient availability of key materials, such as lithium, steel, and copper, to facilitate all new clean energy technologies?
- Manufacturing and labor: Is there adequate manufacturing or assembly capacity and labor to meet the forecasted growth in clean energy technology?
- Land: Will there be enough land available for wind and solar generation, for example?
- Infrastructure: Will the required infrastructure, such as grid transmission and distribution (T&D) for solar, EV charging infrastructure (EVCI), and hydrogen pipelines and fueling stations, be built or expanded fast enough to meet the anticipated growth?
- Cost competitiveness: Will these technologies be able to compete with conventional and alternative technologies in terms of cost, especially in the context of concerns about energy prices and affordability for households and commercial consumers and the competitiveness of industries?
- Investments: Is a sufficient amount of capital mobilized to finance the energy transition and invest in the low-carbon energy technologies across different regions, including in emerging economies?
All five technologies could face bottlenecks
All five energy technologies in this analysis could face bottlenecks in scaling up. For three in particular (green hydrogen, EVs, and wind), the identified bottlenecks were judged to pose high risks to successful scale-up.
In our assessment, the identified bottlenecks were classified as high, medium, or low/limited risk of becoming constrained. Medium risk refers to a situation where bottlenecks were identified, but potential unlocks or historic examples were also identified that demonstrate ramp-up is conceivable. High-risk bottlenecks, on the other hand, are identified bottlenecks for which no unlocks are available to address the issue yet.
For instance, for EVs, under the Achieved Commitments scenario, we identified potential bottlenecks in three of the six dimensions examined, one of which (materials) was high risk given the significant gap in projected lithium supply. For wind, in the same scenario, potential bottlenecks were identified in five dimensions, with materials, again, posing a high risk. And for green hydrogen, bottlenecks were identified in five of the six dimensions examined under all four scenarios, with at least two being high risk in all scenarios.
Scaling up the five key electrification technologies would require significant effort
In our energy transition scenario that would achieve existing climate commitments, two-thirds of the potential bottlenecks assessed run a risk of delaying the path to net-zero commitments. Around a quarter of these potential bottlenecks are classified as high risk, without unlocks identified to date.
All technologies are expected to be constrained by material and infrastructure bottlenecks, if left unaddressed. Overall, the biggest bottlenecks affecting all five technologies are expected to be the availability of key materials, especially lithium for EVs, iridium for green hydrogen electrolyzers, and rare earth elements, including dysprosium and terbium, for wind.1 Infrastructure could also become a significant bottleneck, including power grids for renewable energy sources (RES), hydrogen distribution and fueling networks, and, to lesser extent, EV charging networks.
The biggest bottlenecks in scaling wind are expected to be materials scarcity, local land regulations, and speed of investments. The highest-risk bottleneck is projected to be in materials—specifically the supply of rare earth metals for magnets, with severe imbalances in magnets for predominantly offshore wind expected by the end of this decade. Medium-risk bottlenecks could arise in land, infrastructure, and investment. Onshore wind is not expected to be constrained by land on a global level, but for some countries, due to land characteristics (such as mountains or islands) or regulations (slow permitting and minimum distance to built environments), land could be scarce.
In power T&D infrastructure, grid build-out would need to double until 2050 to meet commitments, which represents a slowdown compared to the pace of growth in the past five decades. However, execution at grid operators could be at risk due to a lack of technical personnel and slower pace of investments. Investments in wind generation have recently slowed down due to the pressure on returns as a result of increased interest rates and higher material and building costs, which could put future investments at risk.
The major bottlenecks for solar PV scale-up are projected to center on materials scarcity. Copper and tin are the most critical materials and will constitute the main bottleneck of solar PV development in most scenarios. However, unlocks are available, as supply could ramp up (especially for tin). The other medium-risk bottleneck facing solar is in infrastructure, which faces similar challenges concerning grid build-out as wind for large-scale developments.
Green hydrogen is projected to face significant risks across all bottlenecks assessed. In materials, the supply of iridium would need to ramp up to meet demand expectations. However, this lack of supply could in part be unlocked by changing from electrolyzers based on proton exchange membrane technology to other technologies. In manufacturing, around 130–345 gigawatts (GW) of electrolyzer capacity could be required to meet green hydrogen demand in 2030, of which 246 GW has been announced to date. However, only 2 GW is currently operational, and a final investment decision has been made for only another 7 GW (less than 5 percent of required capacity). For infrastructure, new fueling stations, transport capacity (pipelines and shipping), and storage terminals are needed. Green hydrogen is also expected to struggle to be cost competitive with blue or grey hydrogen before 2030 in most geographies, putting all scenarios relying on major green hydrogen expansion at risk.
Heat pump costs would need to come down to be competitive with gas-based alternatives. For most regions, although the total cost of ownership (TCO) for heat pumps is getting close to cost-competitiveness in 2030, it still remains more expensive than natural gas-based heating without subsidies. In manufacturing, heat pump demand growth is expected to be met by expanding current production capacity, but might fall short in faster scenarios, as these would require the opening of new production capacity in the short term.
Battery material is expected to be the key constraint to accelerated EV growth, but unlocks are available. Material availability is expected to be sufficient up to the Current Trajectory scenario, but Further Acceleration and Achieved Commitments scenarios would require material substitutions or other levers to meet goals. Shifting from nickel, manganese, cobalt-based batteries to manganese-based batteries could help in this regard. Other risks include manufacturing, where adjusted supply capacity may be sufficient to balance the lithium-ion battery market in 2030 up to the Further Acceleration scenario. Regarding cost competitiveness, the TCO of EVs is expected to be competitive with internal combustion engines by 2025 in most regions (including subsidies), and could become cheaper into the future, however, in the Further Acceleration and Achieved Commitments scenarios, material shortages are expected to delay the TCO crossover point.
Significant investment may be needed for scale-up
An orderly net-zero energy transition would require additional investments in order to enable a much faster ramp-up of new technologies.
By 2030, $4 trillion of additional investments could be needed per year compared to 2020 to reach net zero (such that total investments represent around 9 percent of global GDP by 2030 compared to around 7 percent today). This is $2 trillion more compared to the Current Trajectory scenario. On average, this also implies reallocating $1 trillion that is spent on high-emission assets per year today to clean energy assets and infrastructure until 2050.
Unlocks are available, but would require concerted action
Although the identified bottlenecks pose major risks for a successful, fast, and orderly energy transition, there are also multiple unlocks that are available today to resolve them and thus mitigate the risks of a delayed transition. When assessing these unlocks, we found that they can help address 11 out of the 16 bottlenecks. While concerted action would be necessary to implement these unlocks, they could also represent significant opportunities for investment and innovation. To overcome bottlenecks in each of the six dimensions while seizing the associated opportunities, the following actions may be needed:
- Materials: To overcome the important bottlenecks associated with materials, there is an opportunity to invest in various initiatives that could increase supply and decrease demand for critical materials, such as investment into expanding sustainable supply. Action could be taken to fast-track technologies with lower intensity of critical materials (for example, electrolyzer material switches), and increase recycling rates, process efficiencies, and logistics. Regarding tin, other semiconductor packaging could be considered to manage demand.
- Manufacturing and labor: Investing in initiatives to increase economies of scale and decrease costs for key energy transition technologies could be key. This could include public–private partnerships to accelerate the ramp-up of manufacturing capacity and improve resilience. Regional coordination would also be important to ensure economies of scale to lower unit costs.
- Land: Land development could be an important consideration for decision makers. There could be integration opportunities, such as rooftop solar and partnerships with food producers for agrivoltaics. Integrated land use planning could help guide RES development to suitable locations. Regulations could be reviewed by decision makers to ensure they will allow the scale-up of RES to meet targets. Finally, governments could engage citizens in the landscape integration of new RES projects. Overall, there may also be a continued need to accelerate project approval timelines to match the ambitions set in many geographies.
- Infrastructure: Stakeholders could invest in repurposing existing infrastructure and developing new infrastructure. They could assess current infrastructure shortcomings ahead of the energy transition, in contrast to existing grid T&D mechanisms in many countries where investment in the grid only takes place when there is a specific request from end users, creating significant delays compared to investing ahead. Stakeholders could also review systems and encourage investments ahead of bottlenecks (for example, in power grids), repurpose existing infrastructure where possible (for example, gas pipelines for hydrogen blending), and encourage the development and adoption of flexibility and demand-side response by industry and households.
- Cost competitiveness: Stakeholders could endeavour to accelerate the electrification of society to speed up the learning curve and increase the cost-competitiveness of low-carbon technologies. Shifting fossil subsidies and support to energy transition technologies in line with net-zero commitments could be a key step, while at the same time ensuring that competitiveness of (critical) industries is maintained to avoid economic harm. Finally, governments could consider how low-income households can be supported to invest in new and ultimately cheaper technologies and ensure affordability.
- Investments: Stakeholders can track investments and look for opportunities to facilitate investments. They could incentivize involvement from public and private institutions to make investments accessible to a wider range of consumers, guide investments to ensure critical technologies across sectors and regions are developed, and guide investments to net present value-negative areas where additional de-risking is needed.
Implementing these unlocks could be critical to ensuring the rapid scaling of key technologies to enable a fast and orderly energy transition and meet pressing climate goals.
To request access to the data and analytics related to our Transition bottlenecks and unlocks, or to speak to our team, please contact us.