submicroscopic

简明释义

英[ˌsʌbmaɪkrəˈskɒpɪk]美[ˌsʌbmaɪkrəˈskɑːpɪk]

adj. 亚微观的

英英释义

单词用法

同义词

反义词

例句

1.Magnetic fluid is a new magnetic material which is stable colloidal suspensions of submicroscopic susceptibilities, yet is fluid-like in behavior.

磁流体是一种新型的磁材料，它是一种含有均匀分布的铁磁性微粒的稳定的胶状悬浮液，同时仍具有液体的流动性。

2.Around the visible gold and microscopic gold particles submicroscopic gold can usually be found under a SEM.

扫描电镜分析结果表明，在可见金及显微金周围容易发现次显微金。

3.The music instrument classification generally used the conception and method of macroscopic and submicroscopic in the West music system for long time.

长期以来，在西方音乐体系里较多习用宏观分类法和微观分类法这一对乐器分类观念和方法。

4.A submicroscopic aggregate of organic and inorganic molecules in colloidal solution.

有机分子和无机分子在胶体溶液中的亚微观集合体。

5.Ores have been highly oxidized, and gold is mainly present as free submicroscopic gold.

矿石氧化程度高，金主要呈游离态次显微金形式存在。

6.The anatomical, microscopic and submicroscopic structure of Botia superciliaris's hepato-pancreas was studied by using applied anatomy, histology and electron microscope technique.

应用解剖学、组织学和透射电镜技术对中华沙鳅肝胰脏解剖结构、显微结构、亚显微结构进行了研究。

7.Researchers are using advanced microscopes to explore submicroscopic 亚显微的 features of materials.

研究人员正在使用先进的显微镜探索材料的亚显微的特征。

8.The study of viruses requires a focus on their submicroscopic 亚显微的 structure.

病毒研究需要关注它们的亚显微的结构。

9.Understanding submicroscopic 亚显微的 interactions is crucial for developing effective drugs.

理解亚显微的相互作用对开发有效药物至关重要。

10.In nanotechnology, scientists often work with submicroscopic 亚显微的 particles to create new materials.

在纳米技术中，科学家经常处理亚显微的颗粒以创造新材料。

11.The submicroscopic 亚显微的 world is filled with organisms that cannot be seen with the naked eye.

在亚显微的世界中充满了肉眼无法看到的生物。

作文

In the world of science, particularly in the fields of biology and chemistry, understanding the structure and behavior of matter is crucial. One term that often comes up in discussions about the smallest components of our universe is submicroscopic, which refers to entities that are smaller than a micrometer and cannot be seen with an optical microscope. These submicroscopic particles include atoms, molecules, and even smaller subatomic particles like electrons and protons. The study of these tiny components is essential for grasping how matter interacts at a fundamental level.To comprehend the significance of submicroscopic entities, one must first appreciate the limitations of our observational tools. Traditional optical microscopes can only magnify objects up to about 1000 times, which means they are unable to visualize anything smaller than a single cell. However, advancements in technology have led to the development of electron microscopes, which can magnify objects up to a million times or more. This allows scientists to explore the submicroscopic realm, revealing intricate details about cellular structures, viral particles, and molecular interactions.The implications of studying submicroscopic structures are vast. For instance, in medicine, understanding the submicroscopic details of viruses and bacteria can lead to the development of targeted treatments and vaccines. By examining the way these pathogens interact with human cells at a submicroscopic level, researchers can design drugs that effectively inhibit their ability to replicate or invade healthy cells.Moreover, materials science heavily relies on knowledge of submicroscopic properties to engineer new materials with specific characteristics. For example, nanotechnology, which operates at the scale of submicroscopic particles, has revolutionized various industries by enabling the creation of materials that are lighter, stronger, and more efficient. These innovations can be found in everything from electronics to renewable energy solutions.However, exploring the submicroscopic world also presents challenges. The behavior of submicroscopic particles often defies classical physics, leading to phenomena that can seem counterintuitive. Quantum mechanics, which governs the behavior of particles at this scale, introduces concepts such as superposition and entanglement, which challenge our traditional understanding of reality. As scientists delve deeper into the submicroscopic realm, they must grapple with these complexities and expand their theoretical frameworks.In conclusion, the study of submicroscopic entities is not just an academic exercise but a vital pursuit that underpins many scientific advancements. From medical breakthroughs to technological innovations, understanding the submicroscopic world allows us to unlock the mysteries of nature and harness its potential for the betterment of society. As we continue to refine our tools and techniques for observing the submicroscopic, the possibilities for discovery are boundless, promising a future where our understanding of the universe is deeper and more profound than ever before.

在科学领域，尤其是在生物学和化学领域，理解物质的结构和行为至关重要。一个经常出现在关于我们宇宙最小组成部分讨论中的术语是submicroscopic，它指的是小于微米且无法通过光学显微镜看到的实体。这些submicroscopic粒子包括原子、分子，甚至更小的亚原子粒子如电子和质子。研究这些微小组件对于掌握物质在基本层面上的相互作用至关重要。要理解研究submicroscopic实体的重要性，首先必须欣赏我们观察工具的局限性。传统的光学显微镜最多只能放大约1000倍，这意味着它们无法可视化比单个细胞更小的东西。然而，技术的进步导致了电子显微镜的发展，它可以将物体放大到一百万倍或更多。这使科学家能够探索submicroscopic领域，揭示细胞结构、病毒颗粒和分子相互作用的复杂细节。研究submicroscopic结构的影响是巨大的。例如，在医学中，理解病毒和细菌的submicroscopic细节可以导致针对性治疗和疫苗的开发。通过检查这些病原体与人类细胞在submicroscopic水平上的相互作用，研究人员可以设计有效抑制其复制或入侵健康细胞的药物。此外，材料科学在工程具有特定特性的材料时也严重依赖于对submicroscopic属性的知识。例如，纳米技术在submicroscopic粒子尺度上运作，已经通过使材料更轻、更强和更高效而彻底改变了各个行业。这些创新可以在从电子产品到可再生能源解决方案的方方面面找到。然而，探索submicroscopic世界也带来了挑战。这些submicroscopic粒子的行为往往违背经典物理学，导致看似反直觉的现象。量子力学支配着这一尺度上粒子的行为，引入了如叠加态和纠缠等概念，这些概念挑战了我们对现实的传统理解。当科学家深入探讨submicroscopic领域时，他们必须应对这些复杂性并扩展他们的理论框架。总之，对submicroscopic实体的研究不仅仅是一项学术活动，而是一项重要的追求，它支撑着许多科学进展。从医学突破到技术创新，理解submicroscopic世界使我们能够解开自然的奥秘，并利用其潜力造福社会。随着我们不断完善观察submicroscopic的工具和技术，发现的可能性是无穷无尽的，承诺着一个我们对宇宙的理解比以往任何时候都更深刻、更深远的未来。