interpenetrating network of samples
简明释义
交叉样本网
英英释义
A complex structure formed by multiple samples that are intricately intertwined or overlapping with one another, creating a network-like arrangement. | 由多个样本形成的复杂结构,这些样本彼此交错或重叠,形成一种网络状的排列。 |
例句
1.The interpenetrating network of samples allowed scientists to observe how changes in one element affected the entire structure.
这个交错样品网络使科学家能够观察到一个元素的变化如何影响整个结构。
2.Utilizing an interpenetrating network of samples can enhance the accuracy of our experimental results.
利用交错样品网络可以提高我们实验结果的准确性。
3.By analyzing the interpenetrating network of samples, we can gain insights into the interactions between various components.
通过分析这个交错样品网络,我们可以深入了解不同成分之间的相互作用。
4.The researchers created an interpenetrating network of samples to study the material's properties under different conditions.
研究人员创建了一个交错样品网络以研究材料在不同条件下的特性。
5.The team discovered that the interpenetrating network of samples had unique characteristics not found in isolated samples.
团队发现这个交错样品网络具有孤立样品中不存在的独特特性。
作文
In recent years, the concept of an interpenetrating network of samples has gained significant attention in various fields, particularly in materials science and biology. This term refers to a complex structure where different materials or biological entities coexist and interact at a microscopic level, creating a unique environment that enhances their properties and functionalities. Understanding this concept is crucial for developing new technologies and improving existing ones.For instance, in materials science, researchers are exploring the potential of interpenetrating networks of samples to create advanced composite materials. These materials consist of two or more distinct phases that are interwoven at the microscopic scale, allowing them to benefit from the strengths of each component. By carefully designing these networks, scientists can produce materials that are lighter, stronger, and more durable than traditional options. This innovation has applications in aerospace, automotive, and construction industries, where performance and safety are paramount.Similarly, in the field of biology, the idea of an interpenetrating network of samples can be observed in the study of cellular structures. Cells are not isolated entities; instead, they exist within a complex matrix of proteins, lipids, and other biomolecules that form a supportive environment. This extracellular matrix allows cells to communicate, share resources, and respond to external stimuli. By investigating how these networks function, researchers can gain insights into tissue engineering and regenerative medicine, potentially leading to breakthroughs in treating injuries and diseases.Moreover, the concept of an interpenetrating network of samples extends beyond physical materials and biological systems. It can also be applied to social sciences and data analysis. In these contexts, it refers to the interconnectedness of various data points or social phenomena. For example, when analyzing social networks, researchers may identify how different groups influence each other and how information spreads through these connections. Understanding these dynamics helps in addressing societal issues and developing effective interventions.The implications of studying interpenetrating networks of samples are vast. In technology, the development of smart materials that can adapt to their environment relies on understanding how different components interact within a network. In healthcare, the ability to manipulate cellular networks could lead to personalized medicine, where treatments are tailored to individual patients based on their unique biological networks.In conclusion, the concept of an interpenetrating network of samples represents a fundamental principle that transcends various disciplines. By recognizing the importance of interconnectedness and interaction, researchers and practitioners can harness the power of these networks to innovate and solve complex problems. As we continue to explore and understand these intricate relationships, the potential for advancements in science, technology, and society becomes increasingly promising.
近年来,‘交错样本网络’这一概念在材料科学和生物学等多个领域引起了广泛关注。这个术语指的是不同材料或生物实体在微观层面共存并相互作用的复杂结构,创造出一种独特的环境,从而增强它们的属性和功能。理解这一概念对开发新技术和改善现有技术至关重要。例如,在材料科学中,研究人员正在探索‘交错样本网络’在创造先进复合材料方面的潜力。这些材料由两种或多种不同相位在微观尺度上交织而成,使它们能够受益于每个组分的优点。通过精心设计这些网络,科学家可以生产出比传统选项更轻、更强和更耐用的材料。这一创新在航空航天、汽车和建筑行业具有应用价值,这些行业对性能和安全性要求极高。同样,在生物学领域,‘交错样本网络’的概念可以在细胞结构的研究中观察到。细胞不是孤立的实体;相反,它们存在于由蛋白质、脂质和其他生物分子构成的复杂基质中,这些基质形成了一个支持环境。这个细胞外基质使细胞能够交流、共享资源并响应外部刺激。通过研究这些网络的功能,研究人员可以深入了解组织工程和再生医学,可能会导致治疗伤害和疾病的突破。此外,‘交错样本网络’的概念不仅限于物理材料和生物系统。它也可以应用于社会科学和数据分析。在这些背景下,它指的是各种数据点或社会现象之间的相互联系。例如,在分析社交网络时,研究人员可能会识别不同群体如何相互影响以及信息如何通过这些连接传播。理解这些动态有助于解决社会问题并制定有效的干预措施。研究‘交错样本网络’的意义是巨大的。在技术方面,开发能够适应其环境的智能材料依赖于理解不同组分在网络内的相互作用。在医疗保健方面,操纵细胞网络的能力可能会导致个性化医学的发展,其中治疗方案根据患者独特的生物网络量身定制。总之,‘交错样本网络’的概念代表了一种超越各学科的基本原则。通过认识到相互联系和相互作用的重要性,研究人员和从业者可以利用这些网络的力量进行创新和解决复杂问题。随着我们继续探索和理解这些复杂关系,科学、技术和社会进步的潜力变得越来越光明。
相关单词
