supercolliders

简明释义

[ˌsuːpərˈkɒlaɪdərz][ˌsuːpərˈkɒlaɪdərz]

n. 超级对撞机

英英释义

Supercolliders are large particle accelerators that collide particles at very high speeds to study fundamental physics, including the properties of matter and the forces that govern interactions between particles.

超对撞机是大型粒子加速器,以非常高的速度碰撞粒子,以研究基本物理学,包括物质的性质和支配粒子之间相互作用的力量。

单词用法

同义词

particle accelerators

粒子加速器

Particle accelerators are essential for conducting high-energy physics experiments.

粒子加速器对于进行高能物理实验至关重要。

colliders

对撞机

Supercolliders can collide particles at unprecedented energies, allowing scientists to explore fundamental questions of the universe.

超对撞机能够以空前的能量碰撞粒子,使科学家能够探索宇宙的基本问题。

反义词

subatomic particles

亚原子粒子

Subatomic particles are studied in various fields of physics.

亚原子粒子在物理学的多个领域中被研究。

non-collider experiments

非对撞实验

Non-collider experiments can provide insights into particle behavior without the need for high-energy collisions.

非对撞实验可以在不需要高能碰撞的情况下提供对粒子行为的见解。

例句

1.One of the primary motivations for building "supercolliders" is to try to produce this matter in the laboratory.

建造“超级对撞机”的基本动机之一就是试图在实验室中产生这种新的物质。

2.One of the primary motivations for building "supercolliders" is to try to produce this matter in the laboratory.

建造“超级对撞机”的基本动机之一就是试图在实验室中产生这种新的物质。

3.Funding for supercolliders is often a topic of debate among government officials.

超级对撞机的资金支持往往是政府官员讨论的话题。

4.The Large Hadron Collider is the most famous of all supercolliders.

大型强子对撞机是所有超级对撞机中最著名的。

5.Research conducted at supercolliders can lead to advancements in medical technology.

超级对撞机进行的研究可以推动医疗技术的进步。

6.The discovery of new particles often relies on experiments conducted in large facilities like supercolliders.

新粒子的发现往往依赖于在大型设施如超级对撞机中进行的实验。

7.Scientists are using supercolliders to explore the fundamental forces of nature.

科学家们正在利用超级对撞机探索自然的基本力量。

作文

The universe is a vast and complex system filled with mysteries that scientists strive to understand. One of the most fascinating tools in modern physics is the use of particle accelerators, particularly supercolliders. These advanced machines are designed to accelerate particles to incredibly high speeds and collide them together, allowing physicists to study the fundamental components of matter and the forces that govern their interactions. The term supercolliders refers specifically to the largest and most powerful types of particle colliders, which can achieve energies that were previously unimaginable. Supercolliders play a crucial role in advancing our knowledge of the universe. For instance, the Large Hadron Collider (LHC) at CERN in Switzerland is one of the most famous supercolliders in the world. It has been instrumental in confirming the existence of the Higgs boson, a particle that gives mass to other particles, thereby providing a key piece of the puzzle in the Standard Model of particle physics. The discovery of the Higgs boson not only validated decades of theoretical work but also opened new avenues for research into phenomena such as dark matter and the early moments of the Big Bang.The operation of supercolliders involves sophisticated technology and engineering. These facilities require extensive underground tunnels and complex detectors to capture the results of particle collisions. The data generated from these experiments is astronomical, requiring advanced computing resources to analyze and interpret. Researchers from all over the world collaborate at supercolliders, sharing their findings and insights, which fosters international cooperation in scientific research.However, the construction and maintenance of supercolliders come with significant financial and ethical considerations. Building such massive facilities requires billions of dollars in funding, and there is ongoing debate about how to allocate resources effectively in the scientific community. Critics argue that funds could be better spent on pressing global issues like climate change or public health. Supporters, however, contend that the knowledge gained from supercolliders can lead to technological advancements that ultimately benefit society.In addition to their scientific contributions, supercolliders also inspire curiosity and wonder about the nature of reality. They challenge our understanding of the universe and push the boundaries of human knowledge. As we continue to explore the smallest building blocks of matter, we learn more about the fundamental laws that govern everything from the tiniest particles to the vast cosmos. In conclusion, supercolliders are not just machines; they are gateways to understanding the universe. Through their innovative designs and groundbreaking research, they provide insights into the fundamental nature of matter and energy. While they pose challenges in terms of funding and ethical considerations, their potential to unlock the secrets of the universe makes them an invaluable asset to modern science. As we look to the future, the continued exploration of supercolliders will undoubtedly lead to new discoveries that could reshape our understanding of the universe and our place within it.

宇宙是一个广阔而复杂的系统,充满了科学家们努力理解的奥秘。在现代物理学中,粒子加速器的使用是最迷人的工具之一,特别是超级对撞机。这些先进的机器旨在将粒子加速到极高的速度并相互碰撞,从而使物理学家能够研究物质的基本组成部分及其相互作用的力量。术语超级对撞机专门指的是最大和最强大的粒子对撞机类型,它们可以达到以前无法想象的能量。超级对撞机在推动我们对宇宙的知识的进步中发挥着至关重要的作用。例如,位于瑞士CERN的大型强子对撞机(LHC)是世界上最著名的超级对撞机之一。它在确认希格斯玻色子的存在方面发挥了重要作用,这是一种赋予其他粒子质量的粒子,从而为粒子物理学标准模型中的关键部分提供了证据。希格斯玻色子的发现不仅验证了数十年的理论工作,还为研究暗物质及大爆炸早期时刻等现象开辟了新的途径。超级对撞机的运行涉及复杂的技术和工程。这些设施需要广泛的地下隧道和复杂的探测器来捕捉粒子碰撞的结果。从这些实验中生成的数据是天文数字,需要先进的计算资源来分析和解释。来自世界各地的研究人员在超级对撞机上合作,分享他们的发现和见解,从而促进了科学研究中的国际合作。然而,建设和维护超级对撞机伴随着重大的财务和伦理考虑。建造如此庞大的设施需要数十亿美元的资金,而且关于如何在科学界有效分配资源的辩论仍在继续。批评者认为,资金可以更好地用于应对气候变化或公共卫生等紧迫的全球问题。然而,支持者则主张,通过超级对撞机获得的知识可以导致最终惠及社会的技术进步。除了科学贡献之外,超级对撞机还激发了人们对现实本质的好奇心和敬畏感。它们挑战我们对宇宙的理解,并推动人类知识的边界。当我们继续探索物质的最小构件时,我们更多地了解了支配从最小粒子到浩瀚宇宙的基本法则。总之,超级对撞机不仅仅是机器;它们是理解宇宙的门户。通过其创新设计和开创性研究,它们提供了对物质和能量基本性质的洞察。虽然它们在资金和伦理考虑方面面临挑战,但它们解锁宇宙秘密的潜力使它们成为现代科学中不可或缺的资产。展望未来,继续探索超级对撞机无疑会导致新的发现,这些发现可能重塑我们对宇宙及我们在其中位置的理解。