ultramicroscopy

简明释义

英[ˌʌltrəmaɪˈkrɒskəpi]美[ˌʌltrəmaɪˈkrɑskəpi]

[光] 超显微术

英英释义

单词用法

同义词

反义词

例句

1.With ultramicroscopy, it should be possible to accomplish the same in one hour.

使用超显微技术，应该可以在一小时内完成相同的操作。

2.With ultramicroscopy, it should be possible to accomplish the same in one hour.

使用超显微技术，应该可以在一小时内完成相同的操作。

3.The team applied ultramicroscopy in their study of nanomaterials to improve their properties.

该团队在纳米材料研究中应用了超显微镜技术以改善其特性。

4.The researchers used ultramicroscopy to analyze the fine structures of the cell membrane.

研究人员使用超显微镜技术分析细胞膜的微细结构。

5.Using ultramicroscopy, the scientists discovered new patterns in the arrangement of molecules.

科学家们使用超显微镜技术发现了分子排列中的新模式。

6.In the field of biology, ultramicroscopy has revolutionized our understanding of cellular processes.

在生物学领域，超显微镜技术彻底改变了我们对细胞过程的理解。

7.With ultramicroscopy, scientists can observe materials at a resolution that was previously unattainable.

通过超显微镜技术，科学家可以观察到以前无法达到的分辨率的材料。

作文

In the realm of scientific exploration, few tools have revolutionized our understanding of the microscopic world as much as ultramicroscopy. This advanced imaging technique allows scientists to observe and analyze structures at a scale previously thought impossible. With the ability to visualize objects at the atomic level, ultramicroscopy has opened new avenues in various fields, including biology, materials science, and nanotechnology.The term ultramicroscopy refers to the use of sophisticated methods that surpass traditional microscopy limits, enabling researchers to see beyond the capabilities of light microscopes. While conventional microscopes are limited by the diffraction of light, ultramicroscopy employs techniques such as electron microscopy and scanning tunneling microscopy, which utilize electrons or other particles to achieve much higher resolutions.One of the most significant impacts of ultramicroscopy is in the field of biology. For instance, understanding cellular structures and their functions requires insights at the nanometer scale. By utilizing ultramicroscopy, biologists can visualize organelles and proteins in unprecedented detail, leading to breakthroughs in our comprehension of cellular processes. This level of detail is crucial for developing targeted therapies in medicine, as it allows scientists to see how drugs interact with specific cellular components.Moreover, in materials science, ultramicroscopy plays a pivotal role in the development of new materials with unique properties. Researchers can investigate the arrangement of atoms within materials, revealing how these arrangements affect their physical and chemical characteristics. This knowledge is essential for designing stronger, lighter, and more efficient materials for various applications, from aerospace engineering to electronics.The advent of ultramicroscopy has also significantly impacted nanotechnology. As we delve deeper into the nanoscale, the ability to manipulate and analyze materials at this level becomes increasingly important. Ultramicroscopy provides the tools necessary to explore the behavior of nanoparticles and their interactions, paving the way for innovations in drug delivery systems, sensors, and energy storage devices.However, the journey of ultramicroscopy is not without challenges. The complexity of the technology requires significant expertise and investment, making it accessible primarily to well-funded research institutions. Additionally, the interpretation of data obtained through ultramicroscopy can be intricate, necessitating skilled scientists to analyze and draw meaningful conclusions from the images produced.In conclusion, ultramicroscopy represents a significant leap forward in our ability to observe and understand the microscopic world. Its applications span various disciplines, providing invaluable insights that drive innovation and discovery. As technology continues to advance, it is likely that ultramicroscopy will evolve further, offering even greater capabilities and contributing to our quest for knowledge in the natural sciences. Ultimately, the impact of ultramicroscopy on research and industry cannot be overstated, as it enables us to unlock the mysteries of the universe at the smallest scales, fostering advancements that will shape the future of science and technology.

在科学探索的领域中，少数工具像超显微镜一样彻底改变了我们对微观世界的理解。这种先进的成像技术使科学家能够观察和分析以前认为不可能的结构。通过在原子级别上可视化物体，超显微镜为生物学、材料科学和纳米技术等多个领域开辟了新的途径。超显微镜一词是指使用超越传统显微镜限制的复杂方法，使研究人员能够看到光学显微镜能力之外的东西。虽然传统显微镜受到光的衍射限制，但超显微镜采用电子显微镜和扫描隧道显微镜等技术，利用电子或其他粒子实现更高的分辨率。超显微镜最显著的影响之一是在生物学领域。例如，理解细胞结构及其功能需要在纳米尺度上的洞察。通过利用超显微镜，生物学家可以以前所未有的细节可视化细胞器和蛋白质，从而导致我们对细胞过程理解的突破。这种细节水平对于开发医学中的靶向疗法至关重要，因为它使科学家能够看到药物如何与特定细胞组件相互作用。此外，在材料科学中，超显微镜在新材料的开发中发挥着关键作用。研究人员可以调查材料中原子的排列，揭示这些排列如何影响其物理和化学特性。这种知识对于设计强度更高、重量更轻、效率更高的各种应用材料（从航空航天工程到电子产品）至关重要。超显微镜的出现也对纳米技术产生了重大影响。当我们深入纳米尺度时，以这种水平操纵和分析材料的能力变得越来越重要。超显微镜提供了探索纳米颗粒及其相互作用所需的工具，为药物传递系统、传感器和储能设备等创新铺平了道路。然而，超显微镜的旅程并非没有挑战。这项技术的复杂性需要大量的专业知识和投资，使其主要向资金充足的研究机构开放。此外，通过超显微镜获得的数据的解释可能很复杂，需要熟练的科学家分析并从生成的图像中得出有意义的结论。总之，超显微镜代表了我们观察和理解微观世界的重大飞跃。它的应用跨越多个学科，提供了推动创新和发现的宝贵洞察。随着技术的不断进步，超显微镜可能会进一步发展，提供更大的能力，并为我们在自然科学领域的知识追求做出贡献。最终，超显微镜对研究和工业的影响不容小觑，因为它使我们能够在最小的尺度上解锁宇宙的奥秘，促进塑造科学和技术未来的进步。