impurity level

简明释义

杂质能级

英英释义

例句

1.Regular testing is required to monitor the impurity level 杂质水平 in water sources.

需要定期测试以监测水源中的impurity level 杂质水平。

2.High impurity levels 杂质水平 can negatively affect the performance of electronic components.

高impurity levels 杂质水平可能会对电子元件的性能产生负面影响。

3.The impurity level 杂质水平 in pharmaceutical products must be extremely low to ensure patient safety.

药品中的impurity level 杂质水平必须极低，以确保患者安全。

4.The manufacturer must ensure that the impurity level 杂质水平 in the final product meets industry standards.

制造商必须确保最终产品的impurity level 杂质水平符合行业标准。

5.A high impurity level 杂质水平 can lead to increased wear and tear on machinery.

高impurity level 杂质水平可能导致机械设备的磨损加剧。

作文

The concept of impurity level is crucial in various scientific fields, particularly in chemistry and materials science. It refers to the amount of unwanted substances present in a sample or material. Understanding the impurity level is essential for determining the quality and purity of a substance. For instance, in pharmaceuticals, the impurity level of a drug can significantly affect its efficacy and safety. Even trace amounts of impurities can lead to adverse reactions in patients, making it imperative for manufacturers to maintain stringent control over impurity levels. In the semiconductor industry, the impurity level of silicon wafers is critical for the performance of electronic devices. High impurity levels can disrupt the electrical properties of silicon, leading to malfunctioning components. Therefore, manufacturers invest heavily in purification processes to minimize impurity levels and ensure high-quality products. Environmental scientists also measure impurity levels in water and air samples to assess pollution and its impact on health. High impurity levels in drinking water can pose severe health risks, prompting regulatory agencies to set strict limits on acceptable impurity levels. By monitoring these levels, we can take necessary actions to protect public health and the environment. Moreover, the impurity level can also influence the physical properties of materials. For example, metals with high impurity levels may exhibit reduced strength and durability. This is particularly important in construction and manufacturing, where the integrity of materials is paramount. Engineers must consider the impurity level when selecting materials for specific applications to ensure safety and reliability. In conclusion, the impurity level is a fundamental concept that impacts various industries and fields of study. Whether in pharmaceuticals, electronics, environmental science, or materials engineering, understanding and controlling impurity levels is vital for ensuring quality, safety, and performance. As technology advances, the methods for measuring and reducing impurity levels will continue to evolve, helping us achieve higher standards in product development and environmental protection.

‘杂质水平’的概念在各个科学领域中至关重要，特别是在化学和材料科学中。它指的是样品或材料中存在的多余物质的数量。理解‘杂质水平’对于确定物质的质量和纯度至关重要。例如，在制药行业，药物的‘杂质水平’可以显著影响其功效和安全性。即使是微量的杂质也可能导致患者出现不良反应，因此制造商必须严格控制‘杂质水平’。 在半导体行业，硅晶圆的‘杂质水平’对电子设备的性能至关重要。高‘杂质水平’可能会干扰硅的电气特性，导致组件故障。因此，制造商在净化过程中投入大量资金，以最小化‘杂质水平’，确保产品的高质量。 环境科学家还会测量水和空气样本中的‘杂质水平’，以评估污染及其对健康的影响。饮用水中‘杂质水平’过高可能会带来严重的健康风险，这促使监管机构对可接受的‘杂质水平’设定严格限制。通过监测这些水平，我们可以采取必要措施来保护公众健康和环境。 此外，‘杂质水平’还会影响材料的物理特性。例如，‘杂质水平’过高的金属可能表现出强度和耐久性降低。这在建筑和制造业中特别重要，因为材料的完整性至关重要。工程师在选择特定应用的材料时，必须考虑‘杂质水平’，以确保安全性和可靠性。 总之，‘杂质水平’是一个影响各个行业和研究领域的基本概念。无论是在制药、电子、环境科学还是材料工程中，理解和控制‘杂质水平’对于确保质量、安全和性能至关重要。随着技术的进步，测量和减少‘杂质水平’的方法将继续发展，帮助我们在产品开发和环境保护中达到更高的标准。