microphotograph

简明释义

英[ˌmaɪkrəʊˈfəʊtəˌɡrɑːf]美[ˌmaɪkroˈfotəɡræf]

n. 缩影照片

复 数 m i c r o p h o t o g r a p h s

英英释义

单词用法

同义词

反义词

例句

1.Analyzing the microphotograph, it showed that the gel in the dough would become net structure after syneresis cracking.

通过显微照片分析，发现在粉团中的凝胶脱水收缩后成网状结构。

2.Tabletop chemistry takes a photogenic turn in this winning microphotograph by John Hart of the University of Colorado, who specializes in fluid dynamics.

桌面化学在这张获奖图片中进行了一次十分上镜的旋转。 图片作者是来自科罗拉多大学的JohnHart，专攻流体动力学。

3.Tabletop chemistry takes a photogenic turn in this winning microphotograph by John Hart of the University of Colorado, who specializes in fluid dynamics.

桌面化学在这张获奖图片中进行了一次十分上镜的旋转。 图片作者是来自科罗拉多大学的JohnHart，专攻流体动力学。

4.The scientist used a microphotograph to analyze the structure of the cell.

科学家使用微缩摄影分析细胞的结构。

5.The microphotograph showed the crystalline structure of the mineral sample.

这张微缩摄影展示了矿物样本的晶体结构。

6.The microphotograph revealed intricate details that were not visible to the naked eye.

这张微缩摄影揭示了肉眼无法看到的复杂细节。

7.In the lab, we captured a microphotograph of the bacteria to study its morphology.

在实验室，我们拍摄了一张微缩摄影以研究细菌的形态。

8.Researchers often rely on microphotographs to document their findings.

研究人员通常依赖微缩摄影来记录他们的发现。

作文

In the realm of scientific research and documentation, the term microphotograph refers to a photograph taken through a microscope, allowing for the detailed visualization of small specimens that are otherwise invisible to the naked eye. This technique has revolutionized various fields such as biology, materials science, and medicine by providing insights into structures at a microscopic level. The ability to capture images of tiny organisms or intricate cellular structures has greatly enhanced our understanding of life processes and material properties.The history of microphotograph dates back to the 19th century when the first microscopes were developed. Early scientists used these instruments to explore the unseen world, documenting their findings through sketches and rudimentary photographs. However, it was not until the advent of advanced photographic techniques that true microphotograph began to emerge. With the introduction of high-resolution cameras and specialized lenses, researchers could produce clear, detailed images of microorganisms, tissues, and other minute entities.One of the most significant applications of microphotograph is in the field of biology. Biologists utilize this technique to study the morphology and behavior of cells, tissues, and organisms. For instance, when investigating the structure of a plant cell, a microphotograph can reveal the arrangement of chloroplasts, cell walls, and other organelles, providing crucial information about its function and health. Similarly, in medical research, microphotographs of human tissues can aid in diagnosing diseases, understanding pathological changes, and developing treatment strategies.Moreover, microphotograph plays a vital role in materials science. Engineers and scientists examine the microstructure of metals, polymers, and composites to understand their properties and behaviors under different conditions. By analyzing microphotographs, they can identify defects, grain structures, and phase distributions, which are essential for improving material performance and durability.The process of capturing a microphotograph involves several steps. First, the specimen must be prepared, which may include slicing it into thin sections, staining it to enhance contrast, or mounting it on a slide. Once prepared, the specimen is placed under a microscope, where the researcher can adjust the focus and lighting to obtain the best possible image. Finally, the camera captures the microphotograph, which can then be analyzed, shared, or published in scientific journals.As technology advances, the field of microphotograph continues to evolve. Modern techniques such as digital imaging and computer-aided analysis have made it easier to obtain and interpret these images. Additionally, innovations like fluorescence microscopy allow scientists to visualize specific components within cells, further enhancing the capabilities of microphotograph in research.In conclusion, the significance of microphotograph extends far beyond mere documentation; it serves as a powerful tool for discovery and innovation. By enabling researchers to explore the microscopic world, it has opened new avenues in science and technology, ultimately contributing to our understanding of the universe at a fundamental level. Whether in biology, materials science, or medicine, the impact of microphotograph is profound, illustrating the beauty and complexity of life and matter that exists beyond our direct perception.

在科学研究和文献记录的领域中，术语微摄影指的是通过显微镜拍摄的照片，这种照片可以详细可视化小标本，而这些标本在肉眼下是不可见的。这种技术彻底改变了生物学、材料科学和医学等多个领域，通过提供对微观水平结构的深入了解，极大地增强了我们对生命过程和材料特性的理解。

微摄影的历史可以追溯到19世纪，当时第一台显微镜被开发出来。早期科学家使用这些仪器探索看不见的世界，通过素描和初步摄影记录他们的发现。然而，直到先进摄影技术的出现，真正的微摄影才开始出现。随着高分辨率相机和专用镜头的引入，研究人员能够拍摄出微生物、组织和其他微小实体的清晰、详细图像。

微摄影最重要的应用之一是在生物学领域。生物学家利用这一技术研究细胞、组织和生物体的形态和行为。例如，在研究植物细胞的结构时，微摄影可以揭示叶绿体、细胞壁和其他细胞器的排列，提供关于其功能和健康的重要信息。同样，在医学研究中，人类组织的微摄影可以帮助诊断疾病、理解病理变化并制定治疗策略。

此外，微摄影在材料科学中也发挥着至关重要的作用。工程师和科学家检查金属、高分子和复合材料的微观结构，以理解它们在不同条件下的特性和行为。通过分析微摄影，他们可以识别缺陷、晶粒结构和相分布，这对于提高材料性能和耐用性至关重要。

捕捉微摄影的过程涉及几个步骤。首先，必须准备标本，这可能包括将其切割成薄片、染色以增强对比度或将其固定在载玻片上。一旦准备好，标本就放置在显微镜下，研究人员可以调整焦距和照明，以获得最佳图像。最后，相机捕捉微摄影，然后可以进行分析、共享或在科学期刊上发表。

随着技术的进步，微摄影领域也在不断发展。现代技术如数字成像和计算机辅助分析使得获取和解释这些图像变得更加容易。此外，荧光显微镜等创新技术使科学家能够可视化细胞内的特定成分，进一步增强了微摄影在研究中的能力。

总之，微摄影的重要性远不止于简单的文献记录；它作为发现和创新的强大工具。通过使研究人员能够探索微观世界，它为科学和技术开辟了新的途径，最终有助于我们从根本上理解宇宙。无论是在生物学、材料科学还是医学领域，微摄影的影响都是深远的，展示了存在于我们直接感知之外的生命和物质的美丽与复杂性。