supercollider
简明释义
英[ˈsuːpərˌkɒlaɪdər]美[ˈsuːpərˌkɒlaɪdər]
n. 超级对撞机
英英释义
A supercollider is a type of particle accelerator that collides particles at extremely high energies to study fundamental physics. | 超对撞机是一种粒子加速器,以极高的能量碰撞粒子以研究基本物理学。 |
单词用法
同义词
| 粒子加速器 | 超对撞机用于研究基本粒子。 |
反义词
| 亚原子粒子 | Subatomic particles are the fundamental components of matter. | 亚原子粒子是物质的基本组成部分。 | |
| 简单碰撞器 | A simple collider can be used for basic experiments in particle physics. | 简单碰撞器可用于粒子物理学中的基本实验。 |
例句
1.Some officials say the superconducting supercollider is as important scientifically as the first human landing on the moon.
某些官员说,超导超级对撞机在科学上的重要性不亚于人类的第一次登月。
2.Some officials say the superconducting supercollider is as important scientifically as the first human landing on the moon.
某些官员说,超导超级对撞机在科学上的重要性不亚于人类的第一次登月。
3.The supercollider is used to explore the fundamental particles of the universe.
这个超对撞机用于探索宇宙的基本粒子。
4.Many groundbreaking discoveries in physics have been made possible by the supercollider technology.
许多物理学的重大突破都是通过超对撞机技术实现的。
5.Scientists at CERN are conducting experiments with the supercollider to understand dark matter.
CERN的科学家正在使用超对撞机进行实验,以理解暗物质。
6.The supercollider can accelerate particles to nearly the speed of light.
这个超对撞机可以将粒子加速到接近光速。
7.The construction of a new supercollider is planned to further research in particle physics.
计划建造一个新的超对撞机以进一步研究粒子物理学。
作文
The term supercollider refers to a highly advanced particle accelerator that is used in the field of physics to explore the fundamental components of matter. These massive machines are capable of propelling particles, such as protons, to incredibly high speeds and smashing them together. This process allows scientists to observe the resulting collisions and gather invaluable data about the particles created during these high-energy events. The most famous example of a supercollider is the Large Hadron Collider (LHC), located at CERN in Switzerland. It has made significant contributions to our understanding of the universe, including the discovery of the Higgs boson, a particle that gives mass to other particles.The importance of supercolliders in modern physics cannot be overstated. They serve as powerful tools for researchers seeking to answer some of the most profound questions about the nature of the universe. For instance, physicists use supercolliders to study the forces that govern particle interactions, which can lead to insights about the origins of the universe itself. By recreating conditions similar to those just after the Big Bang, scientists can investigate how matter and antimatter behave, helping to explain why our universe is predominantly composed of matter.In addition to fundamental research, supercolliders also have practical applications. The technologies developed for particle acceleration have found their way into various fields, including medicine. For example, particle beams generated by supercolliders are used in cancer treatment, specifically in proton therapy, which targets tumors more precisely while minimizing damage to surrounding healthy tissue.However, building and maintaining a supercollider is an enormous financial undertaking. Projects like the LHC require billions of dollars to construct and operate, leading to debates about funding priorities in science. Critics argue that the money spent on supercolliders could be better allocated to pressing issues such as climate change or public health. Proponents, on the other hand, contend that the knowledge gained from these experiments can lead to technological advancements that benefit society as a whole.Moreover, the international collaboration involved in operating a supercollider is a testament to the global nature of scientific inquiry. Thousands of scientists from different countries work together at facilities like CERN, sharing their expertise and resources to push the boundaries of what we know about the universe. This spirit of cooperation highlights the importance of science as a unifying force, transcending national borders and fostering a sense of shared purpose.In conclusion, supercolliders are not just machines; they are gateways to understanding the universe's mysteries. They provide a unique opportunity to probe the fundamental forces of nature and have far-reaching implications for both theoretical physics and practical applications. As we continue to explore the depths of particle physics, the role of supercolliders will remain crucial in unraveling the secrets of existence itself. The pursuit of knowledge through these remarkable devices exemplifies humanity's relentless quest to understand our place in the cosmos.
术语supercollider指的是一种高度先进的粒子加速器,广泛应用于物理学领域,用于探索物质的基本组成。这些巨大的机器能够将粒子(如质子)加速到极高的速度并相互碰撞。这个过程使科学家能够观察碰撞结果,并收集关于这些高能事件中产生的粒子的数据。最著名的supercollider例子是位于瑞士欧洲核子研究中心(CERN)的大型强子对撞机(LHC)。它在我们对宇宙的理解方面做出了重要贡献,包括发现了希格斯玻色子,这是一种赋予其他粒子质量的粒子。supercollider在现代物理学中的重要性不容小觑。它们作为研究人员寻求回答一些关于宇宙本质的深刻问题的强大工具。例如,物理学家使用supercolliders研究控制粒子相互作用的力量,这可以导致对宇宙起源的洞察。通过重现与大爆炸后类似的条件,科学家可以研究物质和反物质的行为,帮助解释为什么我们的宇宙主要由物质组成。除了基础研究外,supercolliders也有实际应用。为粒子加速开发的技术已经进入多个领域,包括医学。例如,supercolliders产生的粒子束用于癌症治疗,特别是在质子疗法中,它能够更精确地针对肿瘤,同时最大限度地减少对周围健康组织的损害。然而,建设和维护一个supercollider是一项巨大的财务投入。像LHC这样的项目需要数十亿美元来建造和运营,导致关于科学资金优先级的辩论。批评者认为,花费在supercolliders上的资金可以更好地分配给气候变化或公共健康等紧迫问题。另一方面,支持者则认为,从这些实验中获得的知识可以导致有利于整个社会的技术进步。此外,运营supercollider所涉及的国际合作是科学探究全球性质的证明。来自不同国家的数千名科学家在像CERN这样的设施中共同工作,分享他们的专业知识和资源,以推动我们对宇宙的认识。这种合作精神突显了科学作为一种团结力量的重要性,超越国界,培养共同的目标感。总之,supercolliders不仅仅是机器;它们是理解宇宙奥秘的门户。它们提供了独特的机会来探测自然的基本力量,并对理论物理和实际应用都有深远的影响。随着我们继续探索粒子物理的深度,supercolliders的角色将继续在揭示存在的秘密中发挥关键作用。通过这些非凡设备追求知识的过程体现了人类对理解我们在宇宙中位置的无尽追求。
