China’s EAST Reactor: Advancing Magnetic Fusion Technology

China’s EAST Reactor: Advancing Magnetic Fusion Technology

Sub: Sci

Sec: Nuclear

Why in News

• On January 20, 2025, Chinese scientists successfully maintained plasma at a temperature of 100 million degrees Celsius for 1,066 seconds in the Experimental Advanced Superconducting Tokamak (EAST) reactor. This breakthrough is significant for the progress of ITER (International Thermonuclear Experimental Reactor), a global nuclear fusion megaproject that has faced delays and cost overruns.

Nuclear Fusion:

• Nuclear fusion occurs when two atomic nuclei fuse, releasing a tremendous amount of energy.
• Unlike nuclear fission, which generates harmful radioactive waste, fusion is considered a clean and sustainable energy source.
• Achieving sustained nuclear fusion could revolutionize global energy production by providing an abundant and environmentally friendly power source.

Challenges in Achieving Nuclear Fusion:

• The Tritium Problem: Deuterium-tritium fusion is the most feasible reaction due to its lower temperature requirement compared to deuterium-deuterium fusion.
• Deuterium is abundant in seawater, but tritium is scarce and must be produced artificially in heavy-water reactors in Canada, India, and South Korea.
• The Temperature Barrier: To achieve fusion, the required temperature exceeds 100 million degrees Celsius, which is significantly higher than the Sun’s core temperature (15 million degrees Celsius).

Tokamak Technology: Achieving Magnetic Confinement

• A tokamak is a doughnut-shaped (toroidal) reactor where a plasma state is achieved by heating deuterium gas to extreme temperatures.
• Inside EAST, magnetic fields created by superconducting electromagnets confine the plasma and keep it from touching the reactor walls.
• EAST is the only tokamak in the world with both toroidal and poloidal magnetic fields, enhancing its ability to maintain plasma stability.
• 2016: Sustained high-confinement plasma at 50 million degrees Celsius for 60 seconds.
• 2017: Extended the plasma duration to 100 seconds.
• 2023: Set a world record by maintaining high-confinement plasma for 403 seconds.
• 2025: Surpassed its previous record by sustaining plasma for 1,066 seconds, demonstrating improved stability and efficiency.
• EAST does not yet produce electricity as it has not achieved ignition, meaning the fusion process is not yet self-sustaining.
• ITER and other fusion projects aim to achieve a net energy gain, where the energy output exceeds the energy input.

Alternative Fusion Technologies:

• Stellarator: A stellarator is a type of nuclear fusion device designed to confine hot plasma using complex, twisted magnetic fields to sustain controlled nuclear fusion reactions.
  • Magnetic Confinement: Utilizes external magnets arranged in a helical configuration to create a twisted magnetic field, effectively confining the plasma without the need for inducing electric currents within the plasma itself.
• Laser-inertial fusion: It is also known as inertial confinement fusion (ICF), is a method where nuclear fusion reactions are initiated by rapidly compressing and heating small fuel pellets using high-energy laser beams.
  • Fuel Pellet Compression: A small spherical pellet containing deuterium and tritium is targeted by multiple high-powered laser beams from all directions.
  • The intense laser energy compresses the pellet to extremely high densities and temperatures, creating conditions necessary for nuclear fusion to occur.
  • The National Ignition Facility (NIF) in the US achieved fusion ignition in 2022, a milestone not yet reached by tokamak reactors.

International Thermonuclear Experimental Reactor (ITER):

• ITER is one of the most ambitious energy projects in the world today.
• In southern France, 35 nations are collaborating to build the world’s largest tokamak, a magnetic fusion device that has been designed to prove the feasibility of fusion as a large-scale and carbon-free source of energy based on the same principle that powers our Sun and stars.
• The ITER Members China, the European Union, India, Japan, Korea, Russia and the United States have combined resources to conquer one of the greatest frontiers in science.
• As signatories to the ITER Agreement, concluded in 2006, the seven Members will share of the cost of project construction, operation and decommissioning.
• They also share the experimental results and any intellectual property generated by the fabrication, construction and operation phases.

Hydrogen and Its Isotopes:

• Protium: The most common isotope, consisting of one proton and no neutrons. It is stable and constitutes the majority of hydrogen found naturally.
• Deuterium: Contains one proton and one neutron in its nucleus. Accounts for approximately 0.0156% of natural hydrogen. Used in nuclear fusion research, as a tracer in scientific studies, and in heavy water moderated fission reactors.
• Tritium: Consists of one proton and two neutrons. Radioactive with a half-life of about 12.32 years, decaying into helium-3. Produced in nuclear reactors and utilized in fusion research, as well as in self-luminous devices.