Meet the teenager who built a functional fusion reactor (with plasma) for school project
Cesare Mencarini, a 17-year-old Italian student in the UK, has achieved a remarkable feat: building a functional nuclear fusion reactor as part of his school project.
This accomplishment, believed to be the first of its kind in a school environment, has garnered significant attention from the scientific community, according to an Interesting Engineering report.
Nuclear fusion, which produces a very high energy yield and very low nuclear waste production, occurs when two light atoms bond together, or fuse, to make a heavier one.
Nuclear fusion is deemed the future of energy.
What makes his fusion reactor special?
Mencarini's reactor achieved plasma, the fourth state of matter, a crucial step in the fusion process. While his device couldn't replicate the immense pressure generated by the sun, it effectively used high voltage to heat atoms to the required temperatures.
Fusion power: A clean energy hopeful
Nuclear fusion, the process that powers the sun, holds immense promise as a clean and virtually inexhaustible energy source. If harnessed successfully, fusion could provide a sustainable solution to global energy needs.
Mencarini's reactor: A stepping stone
While Mencarini's reactor is a remarkable achievement, developing practical, large-scale fusion reactors remains a complex and ongoing challenge. Nevertheless, his accomplishment demonstrates the potential of young scientists and the importance of fostering innovation and curiosity in education.
The reactor explained:
What is plasma?
The reactor achieved plasma in June. Plasma is an electrically charged gas where electrons are no longer bound to atomic nuclei, created in laboratories by coaxing hydrogen nuclei to fuse into helium. This requires temperatures several times hotter than those inside the sun.
Key Components:
- Leybold Trivac E2 roughing pump: Achieves a minimum pressure of 8E-3 Torr.
- Pfeiffer TPH062 turbomolecular pump: Used for achieving fusion (future implementation).
- High-voltage feedthrough connected to a 5 kV power supply: Allows use in a school environment (limited to 2mA output).
- Grids: Allow experimentation with different configurations.
Safety first
Mencarini's teachers were initially concerned about the project's safety, a major consideration when dealing with high voltage and potential neutron radiation.
To convince his teachers of the safety of his invention, Mencarini has implemented a containment shell, emergency shutdown system, and radiation shielding as part of the system.
Future aspirations
Mencarini plans to pursue a degree in engineering and aspires to work at the University of Bristol's Interface and Analysis Centre.
Mencarini's report, titled "To build an Inertial Electrostatic Confinement Fusor for research purposes," goes into more detail about the specific type of reactor he built (Inertial Electrostatic Confinement Device) and its limitations.
These include:
- Benefits: Generates neutrons for applications like medical isotope creation.
- Purpose: Research, not sustainable electricity production (due to energy loss).
- Safety Risks: Potential for neutron radiation leaks and high-voltage hazards.
- Safety Measures: Containment shell, emergency shutdown system, and radiation shielding.
Mencarini's project serves as an example of a young scientist pushing boundaries and contributing to advancements in clean energy research.
Startups are at the forefront of this revolution, pioneering groundbreaking innovations such as cold fusion, superconducting magnets, laser-ignited capsules, and projectile fusion.
These innovations aim to address the critical challenges of sustaining fusion reactions and designing scalable reactors.
Nuclear Fusion: A Revolution in Energy Technology
Definition: A theoretical type of nuclear reaction that would occur at, or near, room temperature.
Potential: Could revolutionize energy production if successfully developed, but remains highly controversial and unproven.
• Superconducting Magnets
Use: Essential in creating the magnetic fields required to contain plasma in fusion reactors.
Advantage: Reduce energy loss and improve the efficiency of fusion reactions.
• Laser-Ignited Capsules
Technology: Uses high-powered lasers to compress and heat fuel to initiate fusion.
Impact: Could lead to more efficient and controlled fusion reactions.
• Projectile Fusion
Method: Utilises high-speed projectiles to generate the extreme conditions necessary for fusion.
Innovation: Offers an alternative to traditional magnetic confinement methods, potentially simplifying reactor designs.
Marcini's work, and similar advancements in fusion technology represent a pivotal moment in energy research, with the potential to revolutionize global power generation.
According to GlobalData, a leading data and analytics company, the integration of advanced fusion reactors into the global energy grid could pave the way for a cleaner, more efficient energy future.
GlobalData's latest report, Fusion Visionaries: Startups Shaping the Future of Energy, outlined the achievements of notable startups working on innovations in reactor design, materials science, and plasma control systems.
These efforts are enhancing the efficiency of fusion reactors and bringing us closer to achieving net positive energy output.
Expert insights
Kiran Raj, Practice Head of Disruptive Tech at GlobalData, notes: "The nuclear fusion sector is witnessing rapid growth, fueled by significant investments and the entry of new players. Startups are pioneering novel reactor designs, including compact spherical tokamaks and alternative magnetic confinement methods, while also navigating regulatory and safety challenges."
Vaibhav Gundre, Project Manager of Disruptive Tech at GlobalData, adds, "Diverse approaches such as cold fusion, high-temperature superconducting magnets, advanced laser technology, and innovative projectile fusion are being explored by startups in the pursuit of nuclear fusion as a clean energy source. As these innovations continue to develop, the dream of harnessing fusion energy may soon become a reality."
Rapid innovation
The surge in startup activity highlights a clear trend toward rapid innovation in nuclear fusion technology, driven by the urgent need to address the complexities of the global energy landscape.
These efforts could soon make the long-awaited dream of practical, scalable fusion energy a reality, fundamentally transforming how the world generates and consumes power.
Advancements such as the one made by Mencarini mark a significant milestone in energy research, potentially revolutionising global energy landscape.