chemically pore

简明释义

化学纯

英英释义

例句

1.The chemically pore 化学孔隙 structure of the catalyst significantly increased its efficiency in reactions.

催化剂的化学孔隙结构显著提高了其在反应中的效率。

2.In order to improve filtration, the scientists designed a membrane that would chemically pore 化学孔隙 at the molecular level.

为了改善过滤，科学家们设计了一种膜，可以在分子层面上化学孔隙。

3.By altering the chemical composition, we can chemically pore 化学孔隙 the surface of the polymer for better adhesion.

通过改变化学成分，我们可以化学孔隙聚合物表面，以获得更好的附着力。

4.The researchers discovered that the new material could chemically pore 化学孔隙 to enhance its absorption properties.

研究人员发现，新材料可以化学孔隙以增强其吸收性能。

5.The team focused on ways to chemically pore 化学孔隙 the ceramic material to improve its thermal properties.

团队专注于如何化学孔隙陶瓷材料，以改善其热性能。

作文

In the field of materials science, the term chemically pore refers to the creation or modification of tiny openings within a material's structure through chemical processes. This concept is crucial in various applications, including filtration, catalysis, and drug delivery systems. When we talk about chemically pore materials, we often refer to substances that have been engineered to possess specific porosity characteristics, allowing them to interact with other substances in unique ways.For instance, in the development of new filtration systems, scientists might design membranes that are chemically pore to allow only certain molecules to pass through while blocking others. This selective permeability is essential in many industries, such as water purification, where contaminants must be effectively removed without losing essential minerals. The ability to manipulate the size and distribution of these pores at a molecular level enhances the effectiveness of the filtration process.Moreover, in the realm of catalysis, chemically pore materials can serve as catalysts that facilitate chemical reactions. By providing a large surface area and specific pore structures, these materials can increase the rate of reactions by allowing reactants to access active sites more efficiently. Researchers are constantly exploring new ways to create chemically pore catalysts that can operate under various conditions, making them more versatile and effective in industrial processes.Drug delivery systems also benefit from the use of chemically pore materials. In this context, scientists design nanoparticles that can encapsulate drugs and release them in a controlled manner. The porosity of these nanoparticles is critical; it determines how quickly the drug can be released into the body and how effectively it can target specific cells. By fine-tuning the chemically pore properties of these materials, researchers can improve the efficacy of treatments and minimize side effects.The implications of utilizing chemically pore materials extend beyond just scientific applications; they also have significant environmental impacts. For example, the development of chemically pore materials for carbon capture technologies can help mitigate climate change by trapping carbon dioxide emissions from industrial processes. By enhancing the porosity of these materials, scientists aim to increase their efficiency in capturing greenhouse gases, thus contributing to a more sustainable future.In conclusion, the concept of chemically pore highlights the intersection of chemistry and material science, leading to innovations that can revolutionize various industries. From improving filtration systems to advancing drug delivery methods and addressing environmental challenges, chemically pore materials play a vital role in shaping our technological landscape. As research continues to evolve, the potential applications of chemically pore materials will likely expand, offering new solutions to complex problems in our world today.

在材料科学领域，术语化学孔指的是通过化学过程在材料结构内创建或修改微小开口的过程。这个概念在过滤、催化和药物传递系统等各种应用中至关重要。当我们谈论化学孔材料时，通常是指经过工程设计，具有特定孔隙特征的物质，使其能够以独特的方式与其他物质相互作用。例如，在新型过滤系统的开发中，科学家可能会设计出化学孔的膜，只允许某些分子通过，同时阻挡其他分子。这种选择性渗透性在许多行业中都是必不可少的，例如水净化，其中必须有效去除污染物而不损失必要的矿物质。在分子水平上操纵这些孔的大小和分布的能力增强了过滤过程的有效性。此外，在催化领域，化学孔材料可以作为催化剂，促进化学反应。通过提供较大的表面积和特定的孔结构，这些材料可以通过使反应物更有效地接触活性位点来提高反应速率。研究人员不断探索创造新的化学孔催化剂的方法，以便在各种条件下工作，使其在工业过程中更加多功能和有效。药物传递系统也受益于使用化学孔材料。在这种情况下，科学家设计纳米颗粒，可以封装药物并以控制的方式释放它们。这些纳米颗粒的孔隙度至关重要；它决定了药物释放到体内的速度以及如何有效地靶向特定细胞。通过微调这些材料的化学孔特性，研究人员可以提高治疗效果并最小化副作用。利用化学孔材料的影响不仅限于科学应用；它们对环境也有重大影响。例如，开发用于碳捕集技术的化学孔材料可以通过捕获工业过程中的二氧化碳排放来帮助减缓气候变化。通过增强这些材料的孔隙度，科学家旨在提高其捕获温室气体的效率，从而为实现更可持续的未来做出贡献。总之，化学孔的概念突显了化学与材料科学的交叉，导致了可以革新各个行业的创新。从改善过滤系统到推进药物传递方法，再到应对环境挑战，化学孔材料在塑造我们今天的技术格局中发挥着至关重要的作用。随着研究的不断发展，化学孔材料的潜在应用可能会扩展，为我们当今世界中复杂问题提供新的解决方案。