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Energy Outlook

30 January 2023
Energy Outlook 2023 considers the recent disruption to global energy supplies and associated impacts on global prices, and explores how this could affect the energy transition out to 2050
bp Energy Outlook 2023 edition

Core beliefs of Energy Outlook 2023

This year’s Outlook can be used to identify aspects of the energy transition that are common across the main scenarios. These trends help shape core beliefs about how the energy system may evolve over the next 30 years.

The carbon budget is running out. Despite the marked increase in government ambitions, CO2 emissions have increased every year since the Paris COP in 2015 (bar 2020). The longer the delay in taking decisive action to reduce emissions on a sustained basis, the greater are the likely resulting economic and social costs.
Government support for the energy transition has increased in a number of countries, including the passing of the Inflation Reduction Act in the US. But the scale of the decarbonization challenge suggests greater support is required globally, including policies to facilitate quicker permitting and approval of low-carbon energy and infrastructure.
Coastal road – aerial view
Fuel transportation tanker at sea – aerial view
The disruption to global energy supplies and associated energy shortages caused by the Russia-Ukraine war increases the importance attached to addressing all three elements of the energy trilemma: security, affordability, and sustainability.

The war has long-lasting effects on the global energy system. The heightened focus on energy security increases demand for domestically produced renewables and other non-fossil fuels, helping to accelerate the energy transition.
Pair of offshore rigs
The structure of energy demand changes, with the importance of fossil fuels declining, replaced by a growing share of renewable energy and by increasing electrification. The transition to a low-carbon world requires a range of other energy sources and technologies, including low-carbon hydrogen, modern bioenergy, and carbon capture, use and storage.
Oil demand declines over the outlook, driven by falling use in road transport as the efficiency of the vehicle fleet improves and the electrification of road vehicles accelerates. Even so, oil continues to play a major role in the global energy system for the next 15-20 years.
The prospects for natural gas depend on the speed of the energy transition, with increasing demand in emerging economies as they grow and industrialize offset by the transition to lower carbon energy sources, led by the developed world.
Solar panels in a field – aerial view
Biofuels crop being harvested
The recent energy shortages and price spikes highlight the importance of the transition away from hydrocarbons being orderly, such that the demand for hydrocarbons falls in line with available supplies. Natural declines in existing production sources mean there needs to be continuing upstream investment in oil and natural gas over the next 30 years.
The global power system decarbonizes, led by the increasing dominance of wind and solar power. Wind and solar account for all or most of the growth in power generation, aided by continuing cost competitiveness and an increasing ability to integrate high proportions of these variable power sources into power systems. The growth in wind and solar requires a significant acceleration in the financing and building of new capacity.
The use of modern bioenergy – modern solid biomass, biofuels and biomethane – grows rapidly, helping to decarbonize hard-to-abate sectors and processes.
Low-carbon hydrogen plays a critical role in decarbonizing the energy system, especially in hard-to-abate processes and activities in industry and transport. Low-carbon hydrogen is dominated by green and blue hydrogen, with green hydrogen growing in importance over time. Hydrogen trade is a mix of regional pipelines transporting pure hydrogen and global seaborne trade in hydrogen derivatives.  
Hydrogen-fuelled truck
Carbon capture, use and storage plays a central role in enabling rapid decarbonization trajectories: capturing industrial process emissions, acting as a source of carbon dioxide removal, and abating emissions from the use of fossil fuels.

A range of methods for carbon dioxide removals – including bioenergy combined with carbon capture and storage, natural climate solutions, and direct air carbon capture with storage – will be needed for the world to achieve a deep and rapid decarbonization. 

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