Core Insights - The research team from the Dalian Institute of Chemical Physics has developed a novel core-shell structure hydrogen negative ion electrolyte and successfully constructed the first prototype hydrogen negative ion battery, marking a significant advancement in this field [1][2] Group 1: Research Development - The research on hydrogen negative ion conduction began in 2018, leading to the introduction of a "lattice distortion suppression of electronic conduction" strategy in 2023, resulting in a room-temperature ultra-fast hydrogen negative ion conductor [2] - The team created a new composite hydride with low electronic conduction and high stability by coating unstable trihydride cerium with barium hydride thin layers, which exhibits rapid hydrogen negative ion conduction at room temperature along with excellent thermal and electrochemical stability [2] Group 2: Battery Performance - The prototype hydrogen negative ion battery was assembled using sodium aluminum hydride as the positive electrode and hydrogen-poor dihydride cerium as the negative electrode, achieving a discharge capacity of 984 mAh/g and maintaining 402 mAh/g after 20 charge-discharge cycles [2] - The team successfully built a stacked battery that increased the voltage to 1.9 volts, demonstrating the feasibility of powering electronic devices, such as lighting a yellow LED [2] Group 3: Future Prospects - The hydrogen negative ion battery represents a new energy storage technology path, with potential applications in large-scale energy storage, hydrogen storage, mobile power sources, and special power supplies [2] - The research team plans to focus on the development and optimization of core materials for hydrogen negative ion batteries, aiming to expand application scenarios and provide strong technical support for green energy development in China [2]

Core Insights - The research team from Dalian Institute of Chemical Physics has made significant progress in the development of a new type of hydrogen negative ion prototype battery, which was published in the prestigious journal "Nature" [1][2] - Hydrogen negative ion batteries represent a novel energy storage technology with potential applications in large-scale energy storage, hydrogen storage, mobile power sources, and special power sources [1] Group 1: Research and Development - The hydrogen negative ion battery operates similarly to widely used lithium-ion batteries, utilizing the movement of hydrogen negative ions to store and release energy [1] - Previous challenges in developing hydrogen negative ion batteries included the lack of electrolyte materials that could meet high ionic conductivity, low electronic conductivity, excellent thermal stability, and good electrochemical stability [1] - The research team initiated the study of hydrogen negative ion conduction in 2018 and proposed a strategy in 2023 to suppress electronic conduction through lattice distortion, leading to the development of a room-temperature superfast hydrogen negative ion conductor [1] Group 2: Prototype Battery Assembly - Utilizing the newly developed hydrogen negative ion electrolyte material, the team assembled a prototype battery using sodium aluminum hydride as the positive electrode and hydrogen-poor cerium dihydride as the negative electrode [2] - This assembly marks a significant transition from the conceptual stage to experimental validation of hydrogen negative ion batteries by Chinese researchers [2]

Core Insights - The research team from Dalian Institute of Chemical Physics has made significant advancements in the development of a new type of hydrogen negative ion prototype battery, recently published in the journal "Nature" [1][2] - Hydrogen negative ion batteries represent a novel energy storage technology with potential applications in large-scale energy storage, hydrogen storage, mobile power sources, and special power sources [1] Group 1: Research and Development - The hydrogen negative ion battery operates similarly to widely used lithium-ion batteries, utilizing the movement of hydrogen negative ions to store and release energy [1] - Previous challenges included the lack of electrolyte materials that could meet high ionic conductivity, low electronic conductivity, excellent thermal stability, electrochemical stability, and compatibility with electrode materials [1] - The research team initiated the study of hydrogen negative ion conduction in 2018 and proposed a strategy in 2023 to suppress electronic conduction through lattice distortion, leading to the development of a room-temperature superfast hydrogen negative ion conductor [1] Group 2: Material Innovation - The team created a new core-shell structured composite hydride by coating the less stable trihydride cerium with low electronic conduction and high stability barium hydride, which exhibits rapid hydrogen negative ion conduction at room temperature along with excellent thermal and electrochemical stability [1] - Utilizing this new hydrogen negative ion electrolyte material, the team assembled a prototype battery using sodium aluminum hydride as the positive electrode and hydrogen-poor dihydride cerium as the negative electrode, marking a significant transition from conceptualization to experimental validation of hydrogen negative ion batteries [2]

Core Insights - The research team from Dalian Institute of Chemical Physics has made significant advancements in the development of hydrogen negative ion batteries, with their findings published in the prestigious journal "Nature" on September 17 [1] Group 1: Research Progress - The hydrogen negative ion battery represents a novel energy storage technology with potential applications in large-scale energy storage, hydrogen storage, mobile power sources, and special power sources [1] - The research team initiated the study of hydrogen negative ion conduction in 2018 and proposed a strategy in 2023 to suppress electronic conduction through lattice distortion, leading to the development of a room-temperature superfast hydrogen negative ion conductor [2] Group 2: Material Development - A new core-shell structured composite hydride was created using low electronic conduction and high stability hydrogen barium thin layers to coat less stable trihydride cerium, exhibiting rapid hydrogen negative ion conduction at room temperature along with excellent thermal and electrochemical stability [2] Group 3: Prototype Battery Assembly - Utilizing the newly developed hydrogen negative ion electrolyte material, the team assembled a prototype hydrogen negative ion battery using sodium aluminum hydride as the positive electrode and dihydride cerium as the negative electrode, marking a significant transition from conceptualization to experimental validation in hydrogen negative ion battery technology [4]