polymorph

简明释义

英[ˈpɒlɪmɔːf]美[ˈpɑliˌmɔrf]

n. 多形体；多晶型物；同质异像体；多态生物，多态无机物；多型核细胞

英英释义

单词用法

同义词

反义词

例句

1.AIM the purpose is to establish a FTIR method for the assay of the chloramphenicol palmitate polymorph a.

目的：建立红外分光光度法测定棕榈氯霉素a晶型的方法。

2.Sertraline hydrochloride form VII may be produced by suspending sertraline chloride polymorph V in water, followed by filtration.

盐酸舍曲林晶形VII可通过将盐酸舍曲林多晶型物v悬浮在水中继而过滤来制备。

3.SSR molecular markers were widely applied in soybean researches due to its codominance, highly polymorph, abundance with random distribution in soybean genome, etc.

SSR分子标记因具有共显性、多态性丰富、在大豆基因组中分布广等众多优点而被广泛应用于大豆研究中。

4.Polymorph Self. You assume a new form.

变形自己：你得到一个新的外形。

5.Seal of Wrath applies to non damaging attacks causing it to break Polymorph.

神罚圣印作用于非伤害型攻击时会打破变形术。

6.Polymorph: mounted creatures will no longer remain mounted while polymorphed.

变形术：坐骑上的生物在被变羊后不会再保持骑乘状态。

7.The term polymorph refers to a substance that can exist in more than one form or crystal structure.

术语多形态指的是一种物质可以存在于多种形式或晶体结构中。

8.In programming, a class can be designed to have polymorph behavior, allowing methods to operate on different data types.

在编程中，一个类可以设计成具有多态行为，允许方法对不同数据类型进行操作。

9.The polymorph of the mineral can affect its properties and how it interacts with other materials.

矿物的多形态可以影响其特性以及与其他材料的相互作用。

10.Biologists study the polymorph of certain species to understand their evolutionary adaptations.

生物学家研究某些物种的多形态以了解它们的进化适应性。

11.The software uses polymorph techniques to handle various data inputs seamlessly.

该软件使用多态技术无缝处理各种数据输入。

作文

The concept of polymorph refers to the ability of a substance to exist in multiple forms or structures. In the field of chemistry, polymorph is often used to describe different crystalline forms of a compound that can exist under varying conditions. This phenomenon is not only fascinating but also has significant implications in various industries, particularly in pharmaceuticals, where the solubility and bioavailability of a drug can be affected by its crystalline form. For instance, the same active pharmaceutical ingredient can exhibit different therapeutic effects depending on its polymorphic form. In nature, polymorphism is quite common. Many minerals, for example, can crystallize in different forms. A well-known example is carbon, which can exist as both graphite and diamond. These two polymorphs have vastly different properties despite being composed of the same element. Graphite is soft and opaque, while diamond is hard and transparent. This stark contrast highlights how the arrangement of atoms can lead to different physical characteristics, underscoring the importance of understanding polymorphism in material science. In the realm of biology, polymorphism can also be observed in organisms. Certain species may exhibit different physical forms or morphs, depending on environmental factors or developmental stages. For example, some insects can display polymorphic traits where individuals may have different colors or sizes based on their habitat or availability of resources. This adaptability can be crucial for survival, allowing species to thrive in diverse environments. Moreover, polymorphism is significant in the study of genetics and evolution. The presence of multiple forms within a population can lead to genetic diversity, which is essential for natural selection. By studying polymorphic traits, scientists can gain insights into evolutionary processes and the mechanisms driving speciation. In conclusion, the term polymorph encapsulates a wide range of phenomena across different scientific disciplines. Whether in chemistry, biology, or materials science, understanding polymorphism provides valuable insights into the behavior and properties of substances and organisms. As research continues to uncover the complexities of polymorphism, we are likely to discover new applications and implications that can benefit various fields, from medicine to environmental science. The study of polymorphism not only enhances our scientific knowledge but also inspires innovation and progress in technology and industry.

“polymorph”这个概念指的是一种物质能够以多种形式或结构存在。在化学领域，“polymorph”常用于描述在不同条件下可以存在的化合物的不同晶体形态。这一现象不仅令人着迷，而且在各个行业中具有重要意义，特别是在制药行业，药物的溶解度和生物利用度可能会受到其晶体形式的影响。例如，相同的活性药物成分可能会根据其polymorph形式表现出不同的治疗效果。 在自然界中，“polymorph”现象相当普遍。许多矿物质，例如，可以以不同的形式结晶。一个众所周知的例子是碳，它可以以石墨和钻石的形式存在。这两种polymorph尽管由相同的元素组成，但具有截然不同的性质。石墨是柔软且不透明的，而钻石则坚硬且透明。这种鲜明的对比突显了原子的排列如何导致不同的物理特性，强调了理解polymorph在材料科学中的重要性。 在生物学领域，“polymorph”现象也可以在生物体中观察到。某些物种可能会根据环境因素或发育阶段表现出不同的物理形式或变种。例如，一些昆虫可以显示出polymorph特征，其中个体可能根据栖息地或资源的可用性具有不同的颜色或大小。这种适应能力对生存至关重要，使物种能够在多样化的环境中繁衍生息。 此外，polymorph现象在遗传学和进化研究中也具有重要意义。种群中多种形式的存在可以导致遗传多样性，而遗传多样性对于自然选择至关重要。通过研究polymorph特征，科学家可以深入了解进化过程及驱动物种形成的机制。 总之，术语“polymorph”涵盖了不同科学学科中的广泛现象。无论是在化学、生物学还是材料科学中，理解polymorph现象为我们提供了对物质和生物体行为及特性的宝贵见解。随着研究不断揭示polymorph现象的复杂性，我们可能会发现新的应用和影响，这将使各个领域受益，从医学到环境科学。研究polymorph现象不仅增强了我们的科学知识，还激励了技术和工业的创新与进步。