反物质，宇宙的镜像世界

Group 1: Core Concepts of Antimatter - Antimatter is a mirror image of ordinary matter, where each particle has a corresponding antiparticle with opposite charge [2][3] - The discovery of antimatter dates back to the early 20th century, with significant milestones including the prediction of positrons by Paul Dirac in 1928 and the first observation of positrons by Carl Anderson in 1932 [3] - Recent advancements in antimatter research include the successful observation of antihydrogen-4 by Chinese scientists in 2024, marking a significant breakthrough in the field [3] Group 2: Research Objectives - One primary goal of antimatter research is to address the baryon asymmetry problem, which questions why the universe is predominantly composed of matter despite equal amounts of matter and antimatter being produced during the Big Bang [4] - Another objective is to test the applicability of physical laws to antimatter, particularly the equivalence principle of general relativity, which posits that all objects respond to gravity in the same way [5][6] - A third goal involves studying dark matter and its potential counterpart, "antidark matter," which could provide insights into the origins of observed antimatter in the universe [7] Group 3: Practical Applications - Antimatter has practical applications in medicine, particularly in positron emission tomography (PET), which utilizes positrons for high-precision imaging of metabolic processes in patients [8] - Research on antiprotons has been conducted to explore their effectiveness in cancer treatment, with findings suggesting that antiprotons can more efficiently destroy cancer cells while minimizing damage to healthy cells [9] - Antimatter also holds potential as a clean energy source, with energy density estimates indicating that it could be 10 billion times greater than traditional fossil fuels, making it a candidate for future energy solutions [10] Group 4: Future Prospects - Theoretical applications of antimatter in space travel suggest that antimatter propulsion systems could achieve speeds up to 15% of the speed of light, revolutionizing interstellar exploration [10] - Despite the challenges in producing and storing antimatter, ongoing research aims to overcome these obstacles, potentially leading to significant advancements in both energy and space travel technologies [10]