In the field of controlled nuclear fusion,WHY China once again taken the lead?

It is reported that the world’s first full-scale high-temperature superconducting tokamak device has been built in China! It is the “Honghuang 70“ tokamak designed, developed, and constructed by the Energy Pinnacle Company and built by the China National Nuclear Corporation Fifth Company. The completion of the world’s first full-scale high-temperature superconducting nuclear fusion device in China marks a significant advancement in human-controlled nuclear fusion. This milestone achievement will open up new possibilities for future energy development, leading us towards an era of infinite energy. The “Honghuang 70“ tokamak device by China’s Energy Pinnacle Company represents the pinnacle of technology and innovation, and its birth will change the world’s energy landscape, challenging our traditional understanding of energy. Is this true? Dear viewers! Welcome back to our channel! I am delighted to share and discuss the following topics with the audience: 1. What profound impact will the completion of this full-scale high-temperature superconducting nuclear fusion device have on the future of global energy? 2. How to address the various technical challenges faced during the fusion process, especially in plasma control? 3. How does the Energy Pinnacle Company’s AI plasma operation control system improve fusion efficiency? In the field of energy innovation, China once again leads the world. The successful completion of the world’s first full-scale high-temperature superconducting tokamak device—“Honghuang 70“ not only signifies a significant advancement in China’s nuclear fusion technology but also brings profound implications for the global energy landscape. This achievement heralds that we may be standing on the threshold of an era of infinite energy. Nuclear fusion is a powerful way of releasing energy in the universe. It involves the merging of two lighter atomic nuclei to form a heavier nucleus, releasing a large amount of energy in the process. This process naturally occurs in the sun and other stars, serving as their primary source of light and heat. Compared to another famous nuclear reaction—nuclear fission, nuclear fusion has several unique advantages. Firstly, theoretically, under the same mass conditions, nuclear fusion can produce more than four times the energy compared to nuclear fission. This is mainly because during fusion reactions, a portion of the mass involved in the combination of atomic nuclei is converted into energy according to Einstein’s mass-energy equivalence formula E=mc², and the proportion of mass converted during fusion is higher than during fission. It is based on this principle that we can understand why the power of a hydrogen bomb is much greater than that of an atomic bomb. During the explosion of a hydrogen bomb, a series of carefully arranged nuclear fusion reactions occur internally, rather than just nuclear fission. The conventional explosives in a hydrogen bomb first compress materials containing light elements such as deuterium or lithium to extreme temperatures and pressures, triggering fusion reactions. Once initiated, these fusion reactions generate immense energy, releasing a more intense glare and heat than an atomic bomb. However, the nuclear fusion reactions in a hydrogen bomb are uncontrollable. All of its energy is rapidly released in an extremely short time, resulting in catastrophic consequences. Therefore, scientists have been exploring the possibility of achieving controlled nuclear fusion reactions. If this reaction can be successfully controlled, humanity will have access to almost limitless, clean, and efficient new energy sources.