ETC: Net zero by 2050 is possible

Sustainable energy

Two new reports released by the Energy Transitions Commission (ETC) analyze the feasibility of achieving a net-zero greenhouse gas emissions (GHG) economy by 2050 and the actions required in the next decade to put this target within reach.

Clean electrification will be at the heart of this transformation enabled by the rapidly falling costs of renewable energy, with a complementary role for clean hydrogen technology in sectors that are difficult or impossible to electrify.

Making Clean Electrification Possible

The report Making Clean Electrification Possible: 30 years to electrify the global economy sets out why it is essential but also feasible and affordable to multiply the size of the global power system by five, while shifting to renewable-based electricity provision. The parallel report Making the Hydrogen Economy Possible: Accelerating clean hydrogen in an electrified economy sets out the complementary role for clean hydrogen and how a combination of private-sector collaboration and policy support can drive the initial ramp up of clean hydrogen production and use to reach 50 million tonnes by 2030.

Net zero by 2050 is possible

The Paris climate accord committed the world to limiting global warming to less than a 2°C increase from pre-industrial levels — and striving for no more than a 1.5°C rise in the planet’s average temperature. For this objective to be reached, the world needs to achieve net-zero GHG emissions by around mid-century. The ETC states that achieving a net-zero GHG emissions economy within the next 30 years is technically and economically feasible.

Renewables deployment to multiply by 2030

Electricity could represent up to 70% of final energy demand by 2050, versus 20% today, with total electricity use expected to grow as much as 5 times in the coming decades. Transitioning to clean electricity as the main source of final energy represents the cheapest and most efficient way to decarbonize the economy. The rapidly falling costs of renewables and storage solutions make it possible to achieve the required massive expansion of clean power systems at low cost, according to the reports.

However, wind and solar must increase from today’s 10% of total electricity generation to about 40% by 2030, and over 75% by 2050. Annual wind and solar installations must therefore grow by 5-7 times by 2030, and more than 10 times by 2050. They must also be accompanied by the parallel deployment of other zero-carbon generation technologies (like hydro and nuclear), flexibility solutions, storage and power networks to deliver zero-carbon power systems at scale.

The ETC states that this is undoubtedly within reach if clear national strategies for decarbonization are put in place and appropriate power market design unlocks private financial flows. Investments in renewable power, primarily wind and solar, will represent the vast majority (around 80%) of total investments required to achieve a net zero economy. Over $80 trillion of investment will be required globally over the next 30 years (ca. $2.5 trillion per annum on average). This includes investment in renewable generation to support both direct and indirect electrification, in addition to investment in electricity grid infrastructure. Whilst large, this represents less than 1.5% of global GDP and is manageable in the current macroeconomic environment.

Clean hydrogen for decarbonization

Clean hydrogen will play a complementary role to decarbonize sectors where direct electrification is likely to be technologically very challenging or prohibitively expensive, such as in steel production and long-distance shipping. A net zero GHG emissions economy by mid-century will likely need to use about 500 to 800 million tonnes of clean hydrogen per annum, a 5-7 fold increase compared to hydrogen use today. Green hydrogen, produced via the electrolysis of water, is likely to be the most cost-competitive and therefore the major production route in the long-term, due to falling renewable electricity and electrolyser equipment costs. It could account for approximately 85% of total production by 2050. However, blue hydrogen, produced from natural gas with carbon capture (with 90%+ capture rates) and low methane leakage (<0.05%), will play an important role in transition and in some specific very low-cost gas locations.

Bringing clean hydrogen costs down

The report highlights how critical rapid ramp-up of production and use in the 2020s is to unlock cost reductions (bringing clean hydrogen costs below $2/kg) and to make mid-century growth targets achievable. However, even once clean hydrogen becomes cheaper than grey hydrogen, using hydrogen in different industry and transport sectors will often still impose a “green cost premium” compared to current high-carbon technologies. Public policy is therefore essential to drive uptake of clean hydrogen at pace. Policymakers will also need to anticipate growing hydrogen transport and storage needs. In total, 85% of investments required to ramp-up hydrogen production is for renewable electricity provision (included in the renewables investment above). Additionally, ca. $2.4 trillion ($80 billion per annum) will be required between now and 2050 for hydrogen production facilities and transportation & storage.

Critical milestones to be reached by 2030 to put 2050 targets within reach

With regards to power, the ETC recommends that developed countries should achieve grid emissions intensity below 30gCO2/kWh by the mid-2030s and developing countries by the mid-2040s.

Meanwhile, public policy needs to pull forward clean hydrogen demand in the 2020s to drive production volumes up (reaching 50 million tonnes by 2030). This requires a rapid decarbonization of hydrogen production for already existing uses and accelerated technology development, piloting and early adoption of hydrogen in other key sectors with lower levels of technology readiness but large potential demand, like steel, shipping and synthetic aviation fuels.

The Energy Transitions Commission (ETC) is a coalition of more than 45 leaders from global energy producers, energy industries, financial institutions and environmental advocates – including ArcelorMittal, Bank of America, BP, Development Research Center of the State Council of China, EBRD, HSBC, Iberdrola, Ørsted, Shell, Longi Solar, Tata Group, Volvo Group and the World Resources Institute among others.