micromorphology

简明释义

英[/ˌmaɪkroʊmɔːrˈfɑːlədʒi/]美[/ˌmaɪkroʊmɔːrˈfɑːlədʒi/]

n. 微观形态学

英英释义

单词用法

同义词

反义词

例句

1.Objective: To study the micromorphology and genetics of the muscular tissue from the female cadaver of Xi Han Dynasty discovered in Lianyungang in 2002.

前言：目的：对2002年于连云港出土的西汉女尸肌肉组织进行镜下形态学和遗传学研究。

2.The influence of organobentonite on sedimentation ratio, viscosity, thixotropy, film conductivity and micromorphology of the copper based conductive paint is investigated.

研究了有机膨润土防沉剂对铜系导电涂料的沉降率、黏度、触变性、涂层导电性及显微形态的影响。

3.The thermal behavior, crystalline morphology and micromorphology of the composite were tested and analyzed .

对复合材料进行热性能、结晶形态及微观形态测试分析。

4.The experimental equipment of vibrational induction for dynamically full vulcanization was designed and used to measure and analyze the property and micromorphology of thermoplastic vulcanite (TPV).

在开发设计的振动诱导动态全硫化实验装置上，对热塑性硫化橡胶(TPV)的性能与微观形态进行了测试与分析。

5.A study of 3 Ceratoides species for their flowering habit, daily flowering dynamic change, fertility, and stigma micromorphology shows that the male flowers of c.

研究驼绒藜属3种植物开花规律、开花日动态、结实率及柱头微形态。

6.Micromorphology and fine structure in laser hardened layer of grey cast iron have been investigated with scanning electron microscope and high-voltage transmission electron microscope.

用扫描和高压透射电子显微镜研究了灰铸铁激光硬化层微区组织形貌和精细结构。

7.The mechanism of the interfacial reactions between diamond disk and granite during vertical spindle grinding was studied by tracking their surface glossiness, micromorphology and compositions.

通过跟踪不同加工阶段的花岗石表面光泽度、微观形貌以及组分变化特征，研究垂直轴磨削过程中金刚石磨盘与花岗石界面的作用机制。

8.The micromorphology of main kinds of degradated purple soils in the hilly area, Sichuan Basin, have been revealed by contrasting with normal soils and trace researching in the same site.

采用比较研究法和辅以定点追踪观测，研究了四川盆地丘陵区几种主要紫色土退化的微形态特征。

9.Micromorphology analysis by SEM is performed on the film of triphenyl phosphite formed on A3 steel.

用扫描电镜(SEM)分析了亚磷酸三苯酯在A3钢表面所成膜的微观形貌特征。

10.By studying the micromorphology of bone, scientists can learn about the health and lifestyle of ancient populations.

通过研究骨骼的微观形态学，科学家可以了解古代人群的健康和生活方式。

11.The study of soil micromorphology helps us understand the small-scale structures that influence plant growth.

土壤微观形态学的研究帮助我们理解影响植物生长的小尺度结构。

12.Researchers are using micromorphology to examine the texture of rocks at a microscopic level.

研究人员正在使用微观形态学来检查岩石在显微级别上的纹理。

13.The micromorphology of pollen grains can provide insights into climate change over millennia.

花粉颗粒的微观形态学可以提供关于千年气候变化的洞见。

14.In archaeology, micromorphology is used to analyze ancient sediments for clues about past human activities.

在考古学中，微观形态学用于分析古代沉积物，以获取关于人类过去活动的线索。

作文

Micromorphology is a fascinating field of study that delves into the minute structures and textures of materials, particularly soils and sediments. By examining these small-scale features, researchers can uncover significant information about the environmental conditions and processes that shaped them. The term micromorphology (微观形态学) refers to the detailed study of the microscopic characteristics of materials, which often reveals insights that are not apparent at a larger scale. In this essay, I will explore the importance of micromorphology in various scientific disciplines, its applications, and the techniques used to analyze microscopic structures.One of the primary fields where micromorphology plays a critical role is archaeology. Archaeologists utilize micromorphology to analyze soil samples from excavation sites, helping them understand past human activities and environmental changes. For instance, by studying the microstructures of soil, researchers can identify areas of human habitation, agricultural practices, and even the impact of natural disasters on ancient communities. This microscopic analysis can provide a wealth of information that complements traditional archaeological methods, allowing for a more comprehensive understanding of historical contexts.In addition to archaeology, micromorphology is also essential in the field of geology. Geologists examine the micromorphological features of rocks and sediments to interpret the geological history of an area. By analyzing grain size, shape, and arrangement, scientists can infer the processes that led to the formation of specific rock types and sedimentary layers. For example, the presence of certain microfossils within sediment samples can indicate past environmental conditions, such as temperature and salinity, offering clues about climate change over geological time scales.Furthermore, micromorphology has significant implications in environmental science, particularly in soil health and land management. Understanding the microstructural characteristics of soil can help scientists assess its fertility and capacity to retain water. This knowledge is crucial for sustainable agricultural practices, as it guides farmers in making informed decisions about soil management and crop selection. By employing micromorphology, researchers can develop strategies to enhance soil quality and promote biodiversity, ultimately leading to healthier ecosystems.The techniques used in micromorphology are diverse and continually evolving. One common method is thin section microscopy, where soil or sediment samples are sliced into thin sections and examined under a microscope. This technique allows for detailed observation of microstructures, including pore spaces, mineral composition, and organic matter. Additionally, scanning electron microscopy (SEM) provides high-resolution images of surface textures and morphology, enabling researchers to analyze materials at the nanoscale. These advanced imaging techniques have revolutionized the field of micromorphology, providing unprecedented insights into the microscopic world.In conclusion, micromorphology (微观形态学) is an invaluable tool across various scientific disciplines, offering insights into the past and present conditions of our environment. Its applications in archaeology, geology, and environmental science demonstrate the importance of understanding microscopic structures to address broader questions about human history, geological processes, and ecological health. As technology continues to advance, the field of micromorphology will undoubtedly expand, providing new opportunities for discovery and innovation. By embracing this intricate study of the microscopic world, we can better appreciate the complexity of the materials that make up our planet and the intricate relationships that sustain life.

微观形态学是一个迷人的研究领域，它深入探讨材料，特别是土壤和沉积物的微小结构和纹理。通过研究这些小尺度特征，研究人员可以揭示出关于塑造它们的环境条件和过程的重要信息。术语micromorphology（微观形态学）指的是对材料微观特征的详细研究，这往往揭示出在较大尺度上并不明显的见解。在这篇文章中，我将探讨micromorphology在各个科学学科中的重要性、其应用以及用于分析微观结构的技术。micromorphology发挥关键作用的主要领域之一是考古学。考古学家利用micromorphology分析来自挖掘现场的土壤样本，帮助他们理解过去人类活动和环境变化。例如，通过研究土壤的微观结构，研究人员可以识别出人类居住区、农业实践甚至自然灾害对古代社区的影响。这种微观分析可以提供丰富的信息，补充传统的考古方法，从而使我们对历史背景有更全面的理解。除了考古学，micromorphology在地质学领域也至关重要。地质学家研究岩石和沉积物的微观形态特征，以解释某个地区的地质历史。通过分析颗粒大小、形状和排列，科学家可以推断出导致特定岩石类型和沉积层形成的过程。例如，沉积样本中某些微化石的存在可以指示过去的环境条件，如温度和盐度，为地质时间尺度上的气候变化提供线索。此外，micromorphology在环境科学中也具有重要意义，特别是在土壤健康和土地管理方面。了解土壤的微观结构特征可以帮助科学家评估其肥力和保持水分的能力。这一知识对于可持续农业实践至关重要，因为它指导农民就土壤管理和作物选择做出明智的决策。通过采用micromorphology，研究人员可以制定提高土壤质量和促进生物多样性的策略，最终导致更健康的生态系统。在micromorphology中使用的技术多种多样，并且不断发展。一种常见的方法是薄片显微镜法，其中土壤或沉积物样本被切割成薄片，然后在显微镜下观察。这种技术允许详细观察微观结构，包括孔隙空间、矿物组成和有机物。此外，扫描电子显微镜（SEM）提供了表面纹理和形态的高分辨率图像，使研究人员能够在纳米尺度上分析材料。这些先进的成像技术彻底改变了micromorphology领域，提供了前所未有的微观世界洞察。总之，micromorphology（微观形态学）是各个科学学科中一种无价的工具，提供了有关我们环境的过去和现在条件的见解。它在考古学、地质学和环境科学中的应用证明了理解微观结构对解决有关人类历史、地质过程和生态健康的更广泛问题的重要性。随着技术的不断进步，micromorphology领域无疑会扩展，为发现和创新提供新的机会。通过拥抱这一复杂的微观世界研究，我们可以更好地欣赏构成我们星球的材料的复杂性以及维持生命的微妙关系。