无线电能催化碳–碳键断裂原理的研究

Study on the Principle of Carbon-Carbon Bond Fracture Originated from Wireless Power Catalysis

特斯拉是一个被埋没的天才,他的无线电能传输设想一直不被世人所知,直到一百年后才逐步认识并得以实现。今天人们在享受无线电能传输技术所发展的一系列科学应用的同时,也设想将无线电能传输理论应用到化学领域,于是产生了一个新的设想——无线电能催化。无线电能催化利用了频率协同作用和共振原理,用具有吸波性质的材料为催化剂,使得有机高聚物中的碳(sp3)–碳(sp3)单键发生选择性断裂,从而使大分子量分子裂解为小分子量分子,从而可以实现对高聚物的清洁裂解。若将这一理论应用在实际生产中,将可能产生潜在重要价值,特别是在新能源化学方面,因而无线电能催化作为一个新的学科交叉理论有待于更进一步的探索并期望得到突破和发展。

Tesla is a buried genius whose idea of radio transmission remained unknown until 100 years later. Today, while enjoying a series of scientific applications developed by radio energy transmission technology, people also imagine the application of radio energy transmission theory to the field of chemistry, so a new idea—radio energy catalysis was born. Wireless energy catalysis utilizes the principle of frequency synergy and resonance, and uses materials with absorbing properties as catalysts to selectively break carbon (sp3)-carbon (sp3) single bonds in organic polymers, thereby causing that the large molecular weight molecules are split into small molecular weight molecules, so that the clean cleavage of high polymers can be achieved. If this theory is applied in actual production, it may produce potentially important value, especially in new energy chemistry. Therefore, wireless energy catalysis as a new interdisciplinary theory needs to be further explored and is expected to achieve breakthroughs and development.