morphography
简明释义
n. 形态描绘学;描述地貌学;形态论
英英释义
Morphography is the study and description of the form and structure of organisms, particularly in relation to their morphological characteristics. | 形态学是对生物体的形态和结构进行研究和描述,特别是与其形态特征有关的研究。 |
单词用法
同义词
反义词
| 同质性 | The homogeneity of the samples made it easier to analyze the results. | 样本的同质性使得分析结果变得更加简单。 | |
| 一致性 | Achieving uniformity in the production process is crucial for quality control. | 在生产过程中实现一致性对质量控制至关重要。 |
例句
1.The chemical composition and micro-structure of the coating were examined with XRD and the morphography of the coating was analyzed with SEM.
用X射线衍射仪(XRD)对膜层的化学组成及结构进行了表征,用扫描电子显微镜(SEM)对膜层的形貌进行了分析。
2.The chemical composition and micro-structure of the coating were examined with XRD and the morphography of the coating was analyzed with SEM.
用X射线衍射仪(XRD)对膜层的化学组成及结构进行了表征,用扫描电子显微镜(SEM)对膜层的形貌进行了分析。
3.The study of plant structures often involves detailed analysis through morphography, which helps in understanding their development.
植物结构的研究通常涉及通过形态学进行详细分析,这有助于理解它们的发展。
4.Researchers employed morphography to document the changes in species over generations.
研究人员使用形态学记录物种在几代人中的变化。
5.The artist's latest exhibition features works inspired by morphography in nature.
这位艺术家的最新展览展示了受自然中形态学启发的作品。
6.In digital art, morphography can be used to create intricate designs that evolve over time.
在数字艺术中,形态学可以用来创造随着时间演变的复杂设计。
7.The field of linguistics utilizes morphography to analyze the structure of words and their meanings.
语言学领域利用形态学分析单词的结构及其含义。
作文
Morphography, a term that may not be familiar to many, refers to the study and description of the forms and structures of organisms. This concept is particularly significant in the fields of biology and morphology, where understanding the physical characteristics of living beings is crucial. The word itself is derived from 'morpho', meaning form, and 'graphy', meaning writing or description. Therefore, morphography (形态学) serves as a vital tool for scientists and researchers who aim to classify and understand the diversity of life on Earth.In the realm of biology, morphography (形态学) plays an essential role in taxonomy, which is the science of naming, describing, and classifying organisms. By examining the morphological features of different species, scientists can identify similarities and differences that help them categorize organisms into various groups. For instance, the structure of leaves, flowers, and fruits can provide insights into the evolutionary relationships between plant species. In this way, morphography (形态学) not only aids in classification but also enhances our understanding of biodiversity.Moreover, morphography (形态学) is instrumental in studying developmental biology. Researchers investigate how organisms grow and develop, focusing on the changes in their forms over time. This aspect of morphography (形态学) provides valuable insights into the processes of evolution and adaptation. For example, by analyzing the morphological changes in a species over generations, scientists can infer how environmental factors influence its development. Such studies contribute to our understanding of natural selection and evolutionary theory.In addition to its applications in biology, morphography (形态学) also finds relevance in the field of paleontology. Paleontologists rely on the morphological characteristics of fossils to reconstruct ancient ecosystems and understand the history of life on Earth. By examining the shapes and sizes of fossilized remains, they can deduce how extinct organisms lived and interacted with their environment. This historical perspective is crucial for grasping the dynamics of evolution and extinction events throughout geological time.Furthermore, modern technologies have enhanced the study of morphography (形态学). With the advent of advanced imaging techniques such as 3D scanning and molecular imaging, researchers can analyze the morphology of organisms with unprecedented precision. These innovations allow for more detailed examinations of complex structures, leading to new discoveries in both living and extinct species. As a result, the field of morphography (形态学) continues to evolve, integrating new methodologies and technologies to deepen our understanding of biological forms.In conclusion, morphography (形态学) is a fundamental aspect of biological sciences that encompasses the study of the forms and structures of living organisms. Its applications range from taxonomy and developmental biology to paleontology, providing invaluable insights into the diversity and history of life on our planet. As technology advances, the potential for further exploration and understanding within the field of morphography (形态学) expands, promising exciting discoveries in the future.
形态学这个词可能对许多人来说并不熟悉,指的是生物体形状和结构的研究和描述。这个概念在生物学和形态学领域尤其重要,因为理解生物的物理特征至关重要。这个词本身源于“形态”,意为形状,以及“描写”,意为书写或描述。因此,morphography(形态学)作为科学家和研究人员分类和理解地球生命多样性的一个重要工具。在生物学领域,morphography(形态学)在分类学中发挥着至关重要的作用,分类学是命名、描述和分类生物的科学。通过检查不同物种的形态特征,科学家可以识别相似性和差异,从而帮助他们将生物分类到不同的组别。例如,叶子、花和果实的结构可以提供植物物种之间进化关系的见解。通过这种方式,morphography(形态学)不仅有助于分类,还增强了我们对生物多样性的理解。此外,morphography(形态学)在发育生物学的研究中也至关重要。研究人员调查生物如何生长和发展,重点关注它们形状随时间的变化。morphography(形态学)的这一方面提供了对进化和适应过程的宝贵见解。例如,通过分析一个物种在几代人中的形态变化,科学家可以推断环境因素如何影响其发展。这些研究有助于我们理解自然选择和进化理论。除了在生物学中的应用,morphography(形态学)在古生物学领域也找到了相关性。古生物学家依赖化石的形态特征来重建古生态系统并理解地球生命的历史。通过检查化石遗骸的形状和大小,他们可以推测灭绝生物的生活方式及其与环境的互动。这种历史视角对于掌握地球上进化和灭绝事件的动态至关重要。此外,现代技术增强了对morphography(形态学)的研究。随着3D扫描和分子成像等先进成像技术的出现,研究人员可以以前所未有的精确度分析生物的形态。这些创新使得对复杂结构的更详细检查成为可能,导致对活着和灭绝物种的新发现。因此,morphography(形态学)领域继续发展,整合新的方法和技术,以加深我们对生物形态的理解。总之,morphography(形态学)是生物科学的一个基本方面,涵盖了生物体形状和结构的研究。它的应用范围从分类学和发育生物学到古生物学,提供了对我们星球上生命多样性和历史的宝贵见解。随着技术的进步,morphography(形态学)领域进一步探索和理解的潜力不断扩大,未来承诺将带来令人兴奋的发现。
