inkMacSystemFont, "Helvetica Neue", "PingFang SC", "Hiragino Sans GB", "Microsoft YaHei UI", "Microsoft YaHei", Arial, sans-serif; text-indent: 0px; caret-color: rgb(255, 0, 0); line-height: 20.3636px; text-align: justify; box-sizing: border-box !important; word-wrap: break-word !important; outline: none 0px !important;">"Microbubble implosion" concept map. Image courtesy of Osaka University

inkMacSystemFont, "Helvetica Neue", "PingFang SC", "Hiragino Sans GB", "Microsoft YaHei UI", "Microsoft YaHei", Arial, sans-serif; text-indent: 0px; caret-color: rgb(255, 0, 0); line-height: 20.3636px; text-align: justify; box-sizing: border-box !important; word-wrap: break-word !important; outline: none 0px !important;">A team led by Prof. Takashi Murakami of the Institute of Laser Science at Osaka University in Japan announced that they have discovered a new particle acceleration mechanism called “microbubble implosion”: the outside of hydrogen compounds that contain micro-sized bubbles (spherical voids) When irradiating an ultra-high intensity laser, the bubble emits ultra-high-energy hydrogen ions (protons) at the moment of contraction to atomic size.

inkMacSystemFont, "Helvetica Neue", "PingFang SC", "Hiragino Sans GB", "Microsoft YaHei UI", "Microsoft YaHei", Arial, sans-serif; text-indent: 0px; caret-color: rgb(255, 0, 0); line-height: 20.3636px; text-align: justify; box-sizing: border-box !important; word-wrap: break-word !important; outline: none 0px !important;">In this mechanism, positively-charged ions fill the bubble with electrons of super-high temperature of 100 billion degrees Celsius, thereby generating a strong negative electrostatic force and accelerating toward the center of the bubble. Countless ions accelerate and collide at high speeds at the singularity of the center of the sphere. Theoretically, they can achieve high-density compression comparable to that of the white dwarf in a nanoscale, extremely small space of only tens of atoms. If the substance is compressed to an unprecedentedly high density, a cube-sized substance can weigh more than 100 kilograms.

inkMacSystemFont, "Helvetica Neue", "PingFang SC", "Hiragino Sans GB", "Microsoft YaHei UI", "Microsoft YaHei", Arial, sans-serif; text-indent: 0px; caret-color: rgb(255, 0, 0); line-height: 20.3636px; text-align: justify; box-sizing: border-box !important; word-wrap: break-word !important; outline: none 0px !important;">In addition, the researchers found that the bubbles repeatedly shrink and swell in tens of femtosecond cycles. When they shrink to the nanometer size and reach the maximum compression, they emit high-energy protons, which are as novel as the “nano pulsars”.

inkMacSystemFont, "Helvetica Neue", "PingFang SC", "Hiragino Sans GB", "Microsoft YaHei UI", "Microsoft YaHei", Arial, sans-serif; text-indent: 0px; caret-color: rgb(255, 0, 0); line-height: 20.3636px; text-align: justify; box-sizing: border-box !important; word-wrap: break-word !important; outline: none 0px !important;">If a conventional accelerator is used, the acceleration distance of high-energy particles needs several tens to several hundreds of meters. This amazing physical phenomenon of nano-scale positive charge radiation has been discovered for the first time. In this phenomenon, the decisive action is the exact opposite of the big bang, namely the specific movement of charged ions to a point in space and the hypervelocity collision at about half the speed of light. This is completely different from all of the acceleration principles, which have been discovered and predicted so far, in nature.

inkMacSystemFont, "Helvetica Neue", "PingFang SC", "Hiragino Sans GB", "Microsoft YaHei UI", "Microsoft YaHei", Arial, sans-serif; text-indent: 0px; caret-color: rgb(255, 0, 0); line-height: 20.3636px; text-align: justify; box-sizing: border-box !important; word-wrap: break-word !important; outline: none 0px !important;">The significance of this research result is that by studying the phenomenon of nanometer and femtosecond phenomena that are extremely small and extremely short, they not only help clarify some incomprehensible mysteries in space physics, such as the interplay of high-energy particles in stars and the universe. The origin is also expected to serve as a small neutron source for nuclear fusion reactions in medical and industrial applications.

inkMacSystemFont, "Helvetica Neue", "PingFang SC", "Hiragino Sans GB", "Microsoft YaHei UI", "Microsoft YaHei", Arial, sans-serif; text-indent: 0px; caret-color: rgb(255, 0, 0); line-height: 20.3636px; text-align: justify; box-sizing: border-box !important; word-wrap: break-word !important; outline: none 0px !important;">The research results were published on the 15th in the British online magazine Scientific Reports.