millimicron

简明释义

英[ˈmɪlɪˌmaɪkrɒn]美[ˈmɪlɪˌmaɪkrɑːn]

n. 毫微米

复 数 m i l l i m i c r o n s

英英释义

单词用法

同义词

反义词

例句

1.It took the lead in introducing from Sweden Texcote millimicron garment treatment technology and has made leisure garments with wholly new functions.

并率先引入瑞典德高纳米服装处理技术，制造出具有全新功能的休闲服装产品。

2.Objective to study the cytotoxicity of millimicron brucite fiber dust in vitro.

目的研究纳米级水镁石纤维粉尘的体外细胞毒性。

3.Conclusion The cytotoxicity of millimicron brucite fiber was obviously stronger than common brucite fiber, but much weaker than quartz dust.

结论纳米级水镁石纤维粉尘具有明显的细胞毒性，其细胞毒作用较普通水镁石纤维粉尘强，较石英粉尘弱。

4.It took the lead in introducing from Sweden Texcote millimicron garment treatment technology and has made leisure garments with wholly new functions.

并率先引入瑞典德高纳米服装处理技术，制造出具有全新功能的休闲服装产品。

5.In semiconductor manufacturing, the precision of layers is often measured in millimicrons to ensure optimal performance.

在半导体制造中，层的精度通常以毫微米为单位进行测量，以确保最佳性能。

6.A typical virus might measure around 100 to 300 millimicrons in diameter.

一种典型的病毒直径可能在100到300毫微米之间。

7.The resolution of this microscope can distinguish features down to 10 millimicrons.

这台显微镜的分辨率可以区分到10毫微米的特征。

8.The wavelength of visible light ranges from about 400 to 700 nanometers, which is equivalent to 4000 to 7000 millimicrons.

可见光的波长范围大约在400到700纳米，这相当于4000到7000毫微米。

9.Optical instruments must be calibrated to detect changes as small as a few millimicrons.

光学仪器必须校准，以检测小至几毫微米的变化。

作文

In the realm of science and technology, precision is paramount. One of the lesser-known units of measurement that plays a crucial role in various scientific fields is the millimicron. The term millimicron refers to one-millionth of a millimeter, or equivalently, one-billionth of a meter. This incredibly small unit is often used in fields such as nanotechnology, materials science, and semiconductor manufacturing, where measurements at the atomic or molecular level are essential. Understanding the significance of the millimicron is vital for anyone involved in cutting-edge research and development. For instance, in the semiconductor industry, the size of transistors has shrunk dramatically over the years, with current technologies measuring components in the range of tens of millimicrons. This miniaturization allows for more powerful and efficient electronic devices, enabling advancements in computing, telecommunications, and consumer electronics. The implications of working at the millimicron scale extend beyond mere size reduction. At this scale, quantum effects become significant, leading to new physical phenomena that can be harnessed for innovative applications. Researchers are constantly exploring materials and structures at the millimicron level to develop new technologies, such as quantum dots for displays, advanced sensors, and novel energy solutions. Moreover, the study of materials at the millimicron scale requires sophisticated tools and techniques. Scanning tunneling microscopy (STM) and atomic force microscopy (AFM) are examples of powerful imaging methods that allow scientists to visualize and manipulate materials at the atomic level. These technologies have revolutionized our understanding of material properties and behaviors, paving the way for breakthroughs in various industries.In addition to its applications in technology, the concept of millimicron also finds relevance in biology and medicine. For example, in the field of nanomedicine, drug delivery systems are being designed to operate at the millimicron scale, allowing for targeted therapies that can minimize side effects and improve treatment efficacy. Understanding the interactions between nanoparticles and biological systems is crucial for developing safe and effective medical treatments. In conclusion, the millimicron is more than just a unit of measurement; it represents a frontier of scientific exploration and innovation. As we continue to push the boundaries of what is possible at the nanoscale, the importance of understanding and utilizing the millimicron cannot be overstated. From enhancing electronic devices to revolutionizing medical treatments, the potential applications are vast and varied, promising a future where technology and science work hand-in-hand to solve some of the world's most pressing challenges.

在科学和技术领域，精确度至关重要。一个在各个科学领域中起着关键作用但鲜为人知的测量单位是millimicron。该术语millimicron指的是一百万分之一毫米，或者等同于十亿分之一米。这种极小的单位通常用于纳米技术、材料科学和半导体制造等领域，在这些领域，原子或分子级别的测量至关重要。理解millimicron的重要性对于任何参与前沿研究和开发的人来说都是至关重要的。例如，在半导体行业，晶体管的尺寸在过去几十年中大幅缩小，目前的技术测量组件的范围在几十个millimicrons之间。这种微型化使得电子设备更加强大和高效，推动了计算机、电信和消费电子产品的进步。在millimicron尺度上工作的影响不仅仅是尺寸的减少。在这个尺度上，量子效应变得显著，导致可以被用于创新应用的新物理现象。研究人员不断探索millimicron水平的材料和结构，以开发新技术，例如用于显示的量子点、高级传感器和新型能源解决方案。此外，在millimicron尺度上研究材料需要复杂的工具和技术。扫描隧道显微镜（STM）和原子力显微镜（AFM）是一些强大的成像方法，使科学家能够在原子级别上可视化和操纵材料。这些技术彻底改变了我们对材料特性和行为的理解，为各个行业的突破铺平了道路。除了在技术中的应用，millimicron的概念在生物学和医学中也具有相关性。例如，在纳米医学领域，药物递送系统被设计为在millimicron尺度上运行，从而允许靶向治疗，最小化副作用并提高治疗效果。理解纳米颗粒与生物系统之间的相互作用对于开发安全有效的医疗治疗至关重要。总之，millimicron不仅仅是一个测量单位；它代表了科学探索和创新的前沿。随着我们继续推动纳米尺度上可能性的边界，理解和利用millimicron的重要性不容小觑。从增强电子设备到彻底改变医疗治疗，其潜在应用广泛而多样，预示着一个技术与科学携手解决世界上最紧迫挑战的未来。