reduce the production of laser weapons and parts for electric cars to one second
A team of researchers from China has achieved a technological leap that could alter the energy base of sectors as diverse as electric vehicles, advanced radars or even new generation defense systems. At a time when speed, thermal stability and on-chip integration have become strategic priorities for industry and militaries alike, China claims to have found an unexpectedly fast path to producing one of the most critical components in modern electronics. An industrial leap. China has presented an advance that fundamentally disrupts the production of dielectric storage capacitors, a critical component for hybrid electric vehicles, radar systems, advanced electronics and, especially, directed energy weapons. Two teams from the Metal Research Institute of the Chinese Academy of Sciences have achieved reduce the manufacturing process of these devices just one second thanks to a technique flash annealing capable of heating and cooling materials at 1,000 ºC per second, forming crystalline films on silicon wafers in a single step. In other words, what previously required between three minutes and an hour now happens literally in the blink of an eye, without loss of energy density or thermal stability, and maintaining stable performance. up to 250 ºCa range that covers, for example, from the inside of a hybrid vehicle to the depths of oil exploration. The advance also offers a scalable industrial path towards on-chip storage devices, a goal long pursued by the electronics industry. A new class of capacitors. Dielectric capacitors stand out because they can charge and discharge energy with extreme suddenness, generating current peaks essential for systems that depend on instantaneous reactions. The new crystalline films created by the Chinese team not only achieve energy densities comparable to those of much slower methods, but they maintain less than 3% degradation even at 250 ºC. This guarantees its operation in severe conditions, from automotive electronics subjected to constant heat to sensors and energy exploitation equipment underground. Researchers say in your work that the rapid solidification obtained by heating by electromagnetic induction and immediately cooling in liquid nitrogen fixes the crystalline structure in a high energy state that multiplies the capacity storage, reaching 63.5 J/cm³, values higher than traditional techniques such as firing in a muffle furnace or rapid thermal tempering. This combination of extreme speed, stability and density opens the door to design leaps in multiple industrial sectors. Strategic implications. As we said, the most delicate, and potentially transformative, impact is found in the military terrain: Emerging technology offers a direct solution to one of the bottlenecks of directed energy weapons, such as high-powered lasers, which require fast, stable flows of electricity to maintain sustained fire, repeated pulses, and minimal reload times. The ability to generate intense electrical pulses from denser, more heat-resistant, mass-produced capacitors with faster times drastically reduced makes this technology a key enabler for ship-borne lasers, anti-drone systems, energy saturation weapons or ground-based air defense platforms. In a scenario where thermal autonomy, stress resistance and the ability to withstand repeated thermal cycles are essential, these new dielectric films offer a decisive advantage compared to previous generations of materials. Although they still depend on improvements to close the gap with lithium batteries in total capacity, their superiority in instantaneous power is exactly what modern laser systems require. World projection. The promise of producing advanced capacitors in a second It represents a disruptive change for industries that, until now, assumed long and expensive processes to achieve similar levels of quality. The ability to extend the procedure to other ferroelectric materials and to apply the method on wafer-scale pellets makes this development in a milestone with direct implications for defense microelectronics, aeronautics and the energy sector. China thus obtains a path towards strategic components that are difficult to replicate in the short term in other countries, consolidating an industrial advantage in dual technologies whose relevance will only grow in the coming decades. For the directed energy weapons (considered the next big leap in anti-missile defense, anti-drone and anti-hypersonic platforms) this evolution in capacitors could be equivalent to missing link– Fast, robust, compact and, for the first time, truly scalable storage. Image | CCTV (via X) In Xataka | It is called Crazy Li and it is capable of cutting metal or causing blindness: China has developed an unprecedented combat laser In Xataka | China has made a science fiction dream come true: an electromagnetic cannon capable of reaching 3,000 shots per minute
