heterogeneous structure

简明释义

异质结结构

英英释义

例句

1.Urban planners must consider the heterogeneous structure 异质结构 of neighborhoods when designing public spaces.

城市规划者在设计公共空间时必须考虑社区的异质结构 heterogeneous structure。

2.In materials science, a heterogeneous structure 异质结构 can lead to unique properties that can be exploited for new technologies.

在材料科学中，异质结构 heterogeneous structure可能导致独特的特性，可以用于新技术的开发。

3.The heterogeneous structure 异质结构 of the ecosystem means that different species interact in complex ways.

生态系统的异质结构 heterogeneous structure意味着不同物种以复杂的方式相互作用。

4.The research team discovered that the city's population had a heterogeneous structure 异质结构 with various ethnic groups contributing to its culture.

研究小组发现，这座城市的人口具有一个异质结构 heterogeneous structure，不同的民族群体为其文化做出了贡献。

5.The heterogeneous structure 异质结构 of the soil affects water retention and nutrient availability for plants.

土壤的异质结构 heterogeneous structure影响植物的水分保持和养分可用性。

作文

In the realm of science and engineering, the concept of a heterogeneous structure plays a pivotal role in understanding the complexity of materials and systems. A heterogeneous structure refers to a composition that consists of different components or phases, which can vary in properties such as size, shape, and material type. This diversity can be found in various contexts, from natural formations like soil and rock layers to engineered products like composite materials and multi-phase systems.One of the most compelling examples of a heterogeneous structure is found in concrete. Concrete is not a uniform material; it is composed of aggregates, cement, water, and sometimes additives. The aggregates can vary widely in size and type, leading to a heterogeneous structure that affects the strength, durability, and overall performance of the concrete. Engineers must understand this heterogeneous structure to optimize the mix design for specific applications, ensuring that the final product meets the required standards for construction.Similarly, in the field of biology, many organisms exhibit heterogeneous structures. For instance, human tissues are made up of various cell types, each contributing to the overall function of the organ. The heterogeneous structure of tissues allows for specialized functions, enabling organs to perform complex tasks efficiently. Understanding these structures is crucial for medical research and treatment development, as it provides insights into how diseases can affect different parts of the body differently.Moreover, the concept of heterogeneous structures extends beyond the physical sciences into social sciences as well. In sociology, communities often display heterogeneous structures characterized by diverse cultures, languages, and social norms. This diversity can lead to rich interactions and innovations but also poses challenges in terms of social cohesion and integration. Researchers studying heterogeneous structures in social contexts aim to understand how different groups interact and how their unique characteristics influence societal dynamics.The implications of heterogeneous structures are vast and significant. In technology, for example, the development of advanced materials often relies on the principles of heterogeneous structures. Engineers and scientists create materials with tailored properties by combining different substances, leading to innovations such as lightweight composites used in aerospace and automotive industries. These materials demonstrate enhanced performance due to their heterogeneous structures, which can be engineered to provide strength without adding excessive weight.In conclusion, the study of heterogeneous structures is essential across various fields, providing insights into the behavior and properties of complex systems. Whether in materials science, biology, or sociology, recognizing and analyzing the heterogeneous structures present in different contexts allows for better understanding and innovation. As we continue to explore and manipulate these structures, we unlock new possibilities and advancements that can significantly impact our world. Thus, embracing the complexity of heterogeneous structures is crucial for future developments in both science and society.

在科学和工程领域，异质结构的概念在理解材料和系统的复杂性方面发挥着关键作用。异质结构是指由不同组件或相组成的组合，这些组件或相在大小、形状和材料类型等性质上可能有所不同。这种多样性可以在各种背景中找到，从土壤和岩层等自然形成到复合材料和多相系统等工程产品。一个最引人注目的异质结构示例可以在混凝土中找到。混凝土不是一种均匀的材料；它由骨料、水泥、水和有时的添加剂组成。骨料的大小和类型可能各不相同，从而导致影响混凝土强度、耐久性和整体性能的异质结构。工程师必须理解这种异质结构，以优化特定应用的配方设计，确保最终产品符合建筑标准。同样，在生物学领域，许多生物体表现出异质结构。例如，人类组织由多种细胞类型组成，每种细胞都对器官的整体功能做出贡献。组织的异质结构使得器官能够有效地执行复杂的任务。理解这些结构对于医学研究和治疗开发至关重要，因为它提供了关于疾病如何以不同方式影响身体不同部分的见解。此外，异质结构的概念不仅限于自然科学，还扩展到社会科学。在社会学中，社区通常展现出由多样文化、语言和社会规范构成的异质结构。这种多样性可以导致丰富的互动和创新，但在社会凝聚力和整合方面也会带来挑战。研究者们在社会背景下研究异质结构，旨在理解不同群体如何互动以及他们独特特征如何影响社会动态。异质结构的影响是广泛而重要的。例如，在技术领域，先进材料的开发往往依赖于异质结构的原理。工程师和科学家通过结合不同物质来创造具有定制特性的材料，从而推动航空航天和汽车工业中使用的轻量级复合材料等创新。这些材料由于其可被设计的异质结构而展现出增强的性能，可以在不增加过多重量的情况下提供强度。总之，研究异质结构在各个领域都是至关重要的，为复杂系统的行为和性质提供了见解。无论是在材料科学、生物学还是社会学中，识别和分析不同背景中的异质结构使我们能够更好地理解和创新。随着我们继续探索和操纵这些结构，我们解锁了新的可能性和进步，这可以显著影响我们的世界。因此，拥抱异质结构的复杂性对于未来科学和社会的发展至关重要。