isomorphous

简明释义

英[ˌaɪsəʊˈmɔːfəs]美[ˌaɪsəˈmɔrfəs]

adj. [生物] 同形的；[晶体] 同晶的

英英释义

单词用法

同义词

反义词

例句

1.The results showed that Fe atoms embed the framework of FeAPO-5 molecular sieve by isomorphous substitution and the crystallinity of FeAPO-5 molecular sieve exhibited good and grains were uniform.

结果表明，铁原子通过同晶取代方式进入分子筛骨架，结晶度高，晶粒均匀。

2.The results showed that Fe atoms embed the framework of FeAPO-5 molecular sieve by isomorphous substitution and the crystallinity of FeAPO-5 molecular sieve exhibited good and grains were uniform.

结果表明，铁原子通过同晶取代方式进入分子筛骨架，结晶度高，晶粒均匀。

3.The micro-variation equivalent circuit method is used to analyse and study the circuit features of the multiple unit tubes with the isomorphous or heterogeneous structure systematically.

应用微变等效电路法，对具有同型和异型结构的两类复合管的电路特性，进行了比较系统的分析和研究；

4.The results show that isomorphous substitution occur in the diamonds and the vibrational spectra characteristics of the diamonds depend on the substitution of different elements.

结果表明，在天然金刚石中存在类质同象置换现象，其振动光谱特征随置换元素的不同而不同。

5.The language and communication between teachers and students are isomorphous, and imply the languages characteristic of dialogue and comprehension in many aspects.

语言和师生交往是同构的，师生之间的交往在许多方面都暗示出语言的对话及理解的特性。

6.The commutation near ring defined, it is proved that the near ring of an arbitrary near ring with its unit dimension is isomorphous with its commutation near ring.

定义了变换近环，然后证明了任意一个有单位元的近环与它的变换近环同构；任意一个无零因子近环与它的变换近环同。

7.Tourmaline is a kind of gem material with complex structure, composition and isomorphous substitution, which resuslt in diverse types and colors of this gem.

辐照处理是碧玺颜色改善很重要的一种方法。

8.The size of the wafer to wafer side said, the quality of LED is better than small chip. The price is proportional to the size of isomorphous.

晶片的大小以边长表示，大晶片LED的品质比小晶片的要好。价格同晶片大小成正比。

9.The price is proportional to the size of isomorphous.

价格同晶片大小成正比。

10.The two minerals are isomorphous 同构的, meaning they have the same crystal structure but different chemical compositions.

这两种矿物是同构的，意味着它们具有相同的晶体结构但化学成分不同。

11.In algebra, we often study isomorphous 同构的 groups to understand their properties better.

在代数中，我们经常研究同构的群，以更好地理解它们的性质。

12.The concept of isomorphous 同构的 relationships can be applied in various fields such as biology and chemistry.

在生物学和化学等多个领域中，可以应用同构的关系的概念。

13.The isomorphous 同构的 nature of these compounds allows them to substitute for one another in reactions.

这些化合物的同构的特性使它们能够在反应中相互替代。

14.We found that the two species of plants were isomorphous 同构的 in their genetic makeup.

我们发现这两种植物在遗传构成上是同构的。

作文

In the realm of chemistry and materials science, the term isomorphous refers to substances that share the same crystal structure but differ in their chemical composition. This concept is crucial for understanding how different materials can exhibit similar physical properties despite having distinct elemental makeups. For instance, the minerals calcite and aragonite are both forms of calcium carbonate, yet they crystallize in different structures. The isomorphous relationship between these two minerals illustrates how slight variations in atomic arrangements can lead to significant differences in their physical characteristics, such as hardness and solubility. The study of isomorphous materials extends beyond just minerals. In the field of metallurgy, engineers often explore isomorphous alloys, which are mixtures of metals that maintain a similar lattice structure. Such alloys can provide enhanced strength and durability, making them ideal for applications in aerospace and automotive industries. By understanding the principles of isomorphous relationships, scientists can design new materials with tailored properties to meet specific engineering challenges. Moreover, the concept of isomorphous extends into biology as well, particularly in the study of biomolecules. For example, certain proteins may have isomorphous structures even if they perform different functions within a cell. This similarity can be attributed to evolutionary processes where nature optimizes molecular designs for efficiency. Understanding these isomorphous relationships among proteins can lead to breakthroughs in drug design and biotechnology, as researchers can create molecules that mimic the structure of effective proteins to enhance therapeutic efficacy. In a broader sense, the idea of isomorphous relationships can be applied to various fields, including mathematics and computer science. In mathematics, isomorphous structures can help in understanding equivalences between different algebraic systems. For instance, two groups may be considered isomorphous if there is a one-to-one correspondence between their elements that preserves group operations. This concept aids mathematicians in classifying and analyzing complex systems by revealing underlying similarities. In conclusion, the term isomorphous encapsulates a fundamental principle that transcends multiple disciplines. Whether in the study of minerals, alloys, proteins, or abstract mathematical structures, recognizing isomorphous relationships allows scientists and researchers to draw parallels between seemingly disparate entities. This understanding not only enriches our knowledge of material properties but also fosters innovation across various scientific fields. As we continue to explore the intricate connections between different substances and structures, the significance of isomorphous relationships will undoubtedly play a pivotal role in advancing technology and improving our understanding of the natural world.

在化学和材料科学领域，术语同形异构指的是具有相同晶体结构但化学成分不同的物质。这个概念对于理解不同材料如何在元素组成上有所不同却表现出相似的物理特性至关重要。例如，方解石和文石都是碳酸钙的形式，但它们的晶体结构不同。方解石和文石之间的同形异构关系说明了原子排列的微小变化如何导致其物理特性（如硬度和溶解度）的显著差异。 同形异构材料的研究不仅限于矿物。在冶金学领域，工程师们经常探索同形异构合金，这些合金是保持相似晶格结构的金属混合物。这种合金可以提供增强的强度和耐久性，使其成为航空航天和汽车工业中理想的应用材料。通过理解同形异构关系的原理，科学家可以设计出具有特定性能的新材料，以应对具体的工程挑战。 此外，同形异构的概念也延伸到生物学，特别是在生物大分子的研究中。例如，某些蛋白质可能具有同形异构结构，即使它们在细胞中执行不同的功能。这种相似性可以归因于进化过程，在这一过程中，自然优化了分子设计以提高效率。理解这些蛋白质之间的同形异构关系可以导致药物设计和生物技术方面的突破，因为研究人员可以创建模仿有效蛋白质结构的分子，以增强治疗效果。 从更广泛的角度看，同形异构关系的思想可以应用于多个领域，包括数学和计算机科学。在数学中，同形异构结构有助于理解不同代数系统之间的等价性。例如，如果两个群体之间存在一一对应的关系，并且保持群体运算，则可以认为这两个群体是同形异构的。这个概念帮助数学家分类和分析复杂系统，通过揭示潜在的相似性。 总之，术语同形异构概括了一个跨越多个学科的基本原则。无论是在矿物、合金、蛋白质还是抽象数学结构的研究中，识别同形异构关系使科学家和研究人员能够在看似不同的实体之间建立联系。这种理解不仅丰富了我们对材料特性的知识，还促进了各个科学领域的创新。当我们继续探索不同物质和结构之间错综复杂的联系时，同形异构关系的重要性无疑将在推动技术进步和改善我们对自然世界的理解方面发挥关键作用。