submicron
简明释义
n. 亚微细米
adj. 亚微细粒的
英英释义
Referring to particles or structures that are smaller than one micron (1 micrometer), typically used in scientific and industrial contexts. | 指小于一个微米(1微米) 的颗粒或结构,通常用于科学和工业领域。 |
单词用法
亚微米过滤 | |
亚微米测量 | |
亚微米分辨率 | |
亚微米制造 | |
悬浮中的亚微米颗粒 | |
亚微米涂层 | |
亚微米结构 | |
亚微米设备 |
同义词
反义词
| 微米 | 颗粒的大小以微米为单位测量。 | ||
| 宏观 | 在宏观经济学中,我们研究整体经济。 |
例句
1.When the characteristic size reach micron, submicron degree, overcoming the "limit" binding in order to increase the integration of device.
当特征尺寸进入到微米、亚微米量级时,需要克服“极限”束缚,增加器件的集成度。
2.With deep submicron technology, crosstalk noise becomes more and more serious.
随着深亚微米技术,串扰噪声问题越来越严重。
3.The classifier can be used for classifying powders of micron or submicron size.
结果表明,该超细粉分级机可用于微米或亚微米级的粉体分级。
4.This paper introduces a novel submicron etching technology for emitter window.
介绍了一种新的亚微米发射极窗口刻蚀工艺。
5.In this article, deep submicron lithography and nano processing are reviewed.
本文综述了深亚微米光刻和纳米光刻技术。
6.It is difficult for traditional measuring methods to attain the level of submicron error.
传统的球度测量方法很难达到亚微米级的测量准确度。
7.The study found that submicron 亚微米 droplets can significantly affect climate models.
研究发现<submicron>亚微米submicron>水滴可以显著影响气候模型。
8.The manufacturing process requires a cleanroom environment to control submicron 亚微米 particle contamination.
制造过程需要一个洁净室环境来控制<submicron>亚微米submicron>颗粒污染。
9.In semiconductor fabrication, controlling submicron 亚微米 features is crucial for device performance.
在半导体制造中,控制<submicron>亚微米submicron>特征对器件性能至关重要。
10.The new filter technology is capable of trapping submicron 亚微米 contaminants from the air.
新型过滤技术能够捕获空气中的<submicron>亚微米submicron>污染物。
11.Researchers are studying the behavior of submicron 亚微米 particles in various chemical reactions.
研究人员正在研究<submicron>亚微米submicron>颗粒在各种化学反应中的行为。
作文
In the field of materials science and engineering, the term submicron refers to particles or structures that are smaller than one micron in size. This scale is crucial for various applications, especially in nanotechnology, where manipulating materials at the atomic or molecular level can lead to significant advancements. Understanding submicron technology is vital for developing new materials with enhanced properties, such as increased strength, lighter weight, and improved chemical reactivity.One of the most significant areas where submicron materials are applied is in the production of semiconductors. In this industry, the miniaturization of components has led to the creation of faster and more efficient electronic devices. As the demand for smaller, more powerful gadgets continues to rise, engineers and scientists are constantly exploring submicron fabrication techniques to meet these needs. For instance, transistors, which are the building blocks of modern electronics, have shrunk to sizes measured in nanometers, far below the submicron threshold.Moreover, submicron particles play a critical role in pharmaceuticals. Drug delivery systems that utilize submicron carriers can enhance the bioavailability of medications, allowing for more effective treatments with lower doses. By designing submicron drug delivery vehicles, researchers can ensure that drugs are released in a controlled manner, targeting specific areas within the body and minimizing side effects.In environmental science, submicron particles are also of great concern. Airborne submicron pollutants can penetrate deep into the lungs, posing serious health risks. Understanding the behavior and composition of these tiny particles is essential for developing strategies to mitigate air pollution and protect public health. Researchers use advanced analytical techniques to study submicron aerosols, which helps in formulating regulations and standards for air quality.Furthermore, the food industry has begun to explore submicron technologies to improve food safety and shelf life. For example, submicron emulsions can enhance the stability of food products, preventing separation and spoilage. By employing submicron techniques, manufacturers can create healthier, longer-lasting food options that appeal to consumers.In conclusion, the concept of submicron is integral to numerous fields, from electronics to pharmaceuticals, environmental science, and food technology. The ability to manipulate materials at this scale opens up a world of possibilities for innovation and improvement. As research progresses, we can expect to see even more applications of submicron technologies that will shape the future of various industries. Embracing these advancements will not only enhance our quality of life but also contribute to a more sustainable and efficient world.
在材料科学和工程领域,术语submicron指的是小于一个微米的颗粒或结构。这个尺度对于各种应用至关重要,尤其是在纳米技术领域,在原子或分子水平上操纵材料可以带来重大进展。理解submicron技术对于开发具有增强特性的材料至关重要,例如提高强度、减轻重量和改善化学反应性。submicron材料应用最重要的领域之一是半导体的生产。在这个行业中,组件的小型化导致了更快、更高效的电子设备的创建。随着对更小、更强大设备的需求不断上升,工程师和科学家们不断探索submicron制造技术以满足这些需求。例如,现代电子产品的基本构件——晶体管,其尺寸已经缩小到纳米级,远低于submicron的阈值。此外,submicron颗粒在制药中也发挥着关键作用。利用submicron载体的药物递送系统可以增强药物的生物利用度,从而允许更有效的治疗并降低剂量。通过设计submicron药物递送载体,研究人员可以确保药物以受控的方式释放,针对身体内的特定区域并减少副作用。在环境科学中,submicron颗粒同样令人关注。空气中的submicron污染物能够深入肺部,造成严重的健康风险。理解这些微小颗粒的行为和成分对于制定减轻空气污染和保护公众健康的策略至关重要。研究人员使用先进的分析技术来研究submicron气溶胶,这有助于制定空气质量的法规和标准。此外,食品行业也开始探索submicron技术,以改善食品安全和保质期。例如,submicron乳液可以增强食品产品的稳定性,防止分离和变质。通过采用submicron技术,制造商可以创造出更健康、保质期更长的食品选择,以吸引消费者。总之,submicron的概念在多个领域中都是不可或缺的,从电子学到制药、环境科学和食品技术。能够在这一尺度上操纵材料为创新和改进开辟了一片新天地。随着研究的进展,我们可以期待看到更多submicron技术的应用,这将塑造各个行业的未来。拥抱这些进步不仅会提升我们的生活质量,还将有助于创造一个更加可持续和高效的世界。
