Controlled Thermonuclear Fusion Detailed Explanation
Temperature requirements
Temperature is a system consisting of the average kinetic energy of particles. After the sufficient temperature is reached, according to the Lawson criterion, the energy of accidental collisions occurring within the plasma is large enough to overcome the Coulomb barrier which might lead the particles to fuse together.
There are two effects that lower the actual temperature required. Some nuclei at the sufficient temperature would actually have much higher energy than 0.1 MeV, while others would be much lower. For most of the fusion reactions, nuclei in the high-energy tail of the velocity distribution matters. The second effect is quantum tunneling. The nuclei do not actually possess enough energy to overcome the Coulomb barrier fully. If they have the approximate required energy, they can tunnel through the remaining barrier.
Confinement
The key problem in achieving thermonuclear fusion is the confinement of the hot plasma. , the plasma cannot be in direct contact with any solid material in high temperature and therefore, has to be located in a vacuum. At high pressures, the plasma tends to expand and some force is required to act against it. This force can be the gravitation in stars, magnetic forces in magnetic confinement fusion reactors, or inertia.
Gravitational confinement
Gravitational force is capable of confining the fuel well enough to satisfy the Lawson criterion. The mass needed is massive that gravitational confinement can be found only in stars. In stars which satisfy the mass required, after the supply of hydrogen gets over in their cores, their cores (or a shell around the core) start fusing helium to carbon. In the heaviest stars (at least 8–11 solar masses), the process is continued until some of their energy is made by fusing lighter elements to iron. Iron has one of the highest binding energies. Thus reactions producing heavier elements are endothermic in nature. Therefore significant amounts of heavier elements are formed only in supernova explosions.
All the elements that are heavier than iron have some potential energy to release. The heavier elements can produce energy during the process of being split again back toward the size of the iron, in the process of nuclear fission happening at the end of element production. The energy which is released during nuclear fission is stored energy, probably stored even billions of years before, during stellar nucleosynthesis.
Magnetic confinement
Electrically charged particles follow magnetic field lines. This is applicable to fuel ions. A strong magnetic field can, therefore, trap the fusion fuel. The toroidal geometries of tokamaks, stellarators and open-ended mirror confinement systems are magnetic configurations that can be used.
The other ways to do this are;
• Inertial Confinement – rapid pulse is dispensed to achieve optimal conditions
• Electrostatic Confinement – the electrostatic field is used to confine ions
Why is this not practically possible?
Chain reactions are almost impossible to occur. Hence it’s much easier to control and stop them than fission reactions. So logically, it is better to tap into this source rather than using fission reactions.
Unfortunately, the possibility of harnessing this energy in the near future is very less. It might not be possible for at least two decades from now. A rather disturbing thought that now prevails is, in case this is not a foreseeable and assuring future, the number of resources spent on research could have been used for other renewable sources of energy.
FAQs on Controlled Thermonuclear Fusion
1. What is controlled thermonuclear fusion and why is it important in Physics for CBSE 2025–26?
Controlled thermonuclear fusion refers to the process where light atomic nuclei fuse at extremely high temperatures, releasing large amounts of energy, but under conditions that allow scientists to harness and manage this energy. It is important in Physics as it offers a potential method for generating virtually limitless and clean power, which aligns with the CBSE class 12 Physics curriculum focus on energy sources and atomic structure.
2. How does controlled thermonuclear fusion differ from uncontrolled thermonuclear fusion?
Controlled thermonuclear fusion occurs in an environment where the fusion reactions can be regulated and the energy output can be used constructively, such as in experimental reactors. Uncontrolled thermonuclear fusion happens explosively, as in hydrogen bombs or naturally in stars, where there is no mechanism to harness the released energy safely.
3. What are the main methods to achieve confinement in controlled thermonuclear fusion?
Main methods for confinement include:
- Magnetic confinement: Uses powerful magnetic fields to trap hot plasma, as seen in devices like tokamaks and stellarators.
- Inertial confinement: Involves compressing fuel pellets using high-energy laser or ion beams to achieve the temperatures and pressures required for fusion.
- Electrostatic confinement: Uses electrostatic fields to hold the plasma in place.
- Gravitational confinement: Naturally occurs in stars but is not practical for Earth-based reactors.
4. Why is achieving the necessary temperature critical for controlled thermonuclear fusion as per the CBSE syllabus?
Achieving very high temperatures is essential because only at these energy levels can atomic nuclei overcome the Coulomb barrier (electrostatic repulsion), enabling them to collide and fuse. This aligns with the syllabus focus on kinetic energy, nuclear forces, and reaction conditions in nuclear physics.
5. Explain the Lawson criterion and its significance in controlled fusion research.
The Lawson criterion specifies the minimum conditions (temperature, pressure, and confinement time) a plasma must satisfy for the net energy generated by fusion to exceed the energy used to maintain it. Its significance lies in guiding the design of fusion reactors and assessing their practicality according to the CBSE 2025–26 Physics syllabus.
6. What are the challenges in harnessing controlled thermonuclear fusion energy on Earth?
Major challenges include:
- Achieving and maintaining extremely high temperatures (millions of degrees Celsius).
- Maintaining stable plasma confinement without it touching reactor walls.
- Meeting the Lawson criterion for sustained, net-positive energy output.
- Developing materials that can withstand intense neutron flux and thermal stresses.
- The technical and economic feasibility of building large-scale reactors.
7. How does quantum tunneling facilitate fusion reactions at temperatures lower than the calculated threshold?
Quantum tunneling allows nuclei to fuse by 'tunneling' through the energy barrier rather than surmounting it completely. Some nuclei in the high-energy tail of the velocity distribution can undergo fusion even if their kinetic energy is slightly below the classical threshold, making fusion possible at practical laboratory temperatures.
8. Compare the roles of gravitational and magnetic confinement in thermonuclear fusion.
In stars, gravitational confinement from the immense stellar mass can hold plasma together for fusion. On Earth, we lack sufficient mass, so magnetic confinement is used, where magnetic fields restrain hot plasma in controlled reactor environments, as covered in the class 12 syllabus.
9. Why hasn't controlled thermonuclear fusion been realized for electricity generation yet?
Despite decades of research, controlled thermonuclear fusion hasn't been realized mainly due to technological barriers in achieving consistent plasma confinement, net energy gain, and material durability. The process is complex and costly, and it may take several more decades before becoming viable for electricity generation, as discussed in board exam trend analysis.
10. What real-world applications can be expected if controlled thermonuclear fusion becomes practical?
If achieved, controlled thermonuclear fusion could provide:
- A nearly unlimited and sustainable source of energy.
- Significantly reduced greenhouse gas emissions compared to fossil fuels.
- Less radioactive waste than current fission reactors.
- Enhanced energy security globally.
