coiled filament

简明释义

螺旋形灯丝

英英释义

例句

1.The coiled filament in the incandescent lamp is responsible for its warm glow.

白炽灯中的螺旋状的细丝负责其温暖的光泽。

2.The light bulb contains a coiled filament, which produces light when heated.

灯泡中包含一个螺旋状的细丝，当加热时会发光。

3.During the experiment, we observed how the coiled filament reacted to different voltages.

在实验中，我们观察了螺旋状的细丝如何对不同电压作出反应。

4.The coiled filament in the toaster heats up quickly to toast the bread.

烤面包机中的螺旋状的细丝迅速加热以烤制面包。

5.In the manufacturing of 3D printers, a coiled filament is often used as the printing material.

在3D打印机的制造过程中，常常使用螺旋状的细丝作为打印材料。

作文

In the realm of science, particularly in biology and materials science, the term coiled filament refers to a structure that resembles a spiral or twisted thread. This concept is essential in understanding various biological processes and material properties. For instance, in the context of muscle fibers, the coiled filament plays a crucial role in muscle contraction. The myofilaments, which are composed of proteins such as actin and myosin, form a coiled structure that allows for efficient movement and force generation. When a muscle contracts, these filaments slide past each other, leading to the shortening of the muscle and the generation of force. Moreover, the coiled filament is not limited to biological systems; it is also found in synthetic materials. For example, many modern textiles utilize coiled filaments to enhance elasticity and durability. These filaments can be engineered to possess specific properties, making them suitable for various applications, from clothing to industrial materials. The coiling process allows for a greater degree of flexibility and resilience, which is essential in many practical uses. Understanding the significance of the coiled filament extends beyond just its physical characteristics. In the field of genetics, the coiled structure of DNA is another vital example. DNA molecules are composed of two strands that twist around each other, forming a double helix. This coiled configuration is crucial for the compact storage of genetic information within the cell nucleus. It also plays a significant role in the replication and transcription processes, ensuring that genetic information is accurately passed on during cell division. The implications of the coiled filament extend into nanotechnology as well. Researchers are exploring ways to manipulate coiled structures at the molecular level to create new materials with unique properties. By controlling the coiling of filaments, scientists can develop materials with enhanced strength, conductivity, or biocompatibility, opening up new avenues for innovation in various fields, including medicine and electronics. In conclusion, the concept of the coiled filament is multifaceted, spanning various disciplines from biology to materials science and beyond. Its importance cannot be overstated, as it underpins fundamental processes in living organisms and informs the design of advanced materials. As research progresses, the study of coiled filaments will likely lead to further breakthroughs, enhancing our understanding of both natural and synthetic systems. The versatility of the coiled filament demonstrates the interconnectedness of different scientific fields and highlights the importance of interdisciplinary approaches in solving complex problems. As we continue to explore the potential of coiled structures, we may uncover new applications and technologies that can significantly impact our daily lives and the world around us.

在科学领域，特别是在生物学和材料科学中，术语coiled filament指的是一种类似于螺旋或扭曲线的结构。这个概念对于理解各种生物过程和材料特性至关重要。例如，在肌肉纤维的背景下，coiled filament在肌肉收缩中发挥着关键作用。肌丝由肌动蛋白和肌球蛋白等蛋白质组成，形成一种卷曲的结构，使得运动和产生力量变得高效。当肌肉收缩时，这些丝状结构相互滑动，导致肌肉缩短并产生力量。此外，coiled filament不仅限于生物系统；它还出现在合成材料中。例如，许多现代纺织品利用卷曲的纤维来增强弹性和耐用性。这些纤维可以被设计成具有特定的性能，使其适用于从服装到工业材料的各种应用。卷曲过程允许更大的灵活性和韧性，这在许多实际用途上是必不可少的。理解coiled filament的重要性不仅限于其物理特性。在遗传学领域，DNA的卷曲结构是另一个重要的例子。DNA分子由两条链组成，它们相互缠绕，形成双螺旋。这种卷曲的构型对细胞核内遗传信息的紧凑存储至关重要。它还在复制和转录过程中发挥着重要作用，确保遗传信息在细胞分裂过程中准确传递。coiled filament的意义延伸到纳米技术。研究人员正在探索如何在分子层面操纵卷曲结构，以创造具有独特性能的新材料。通过控制纤维的卷曲，科学家可以开发出具有增强强度、导电性或生物相容性的材料，为医学和电子等各个领域的创新开辟新的途径。总之，coiled filament的概念是多方面的，跨越了生物学、材料科学等多个学科。它的重要性不容忽视，因为它支撑着生物体内的基本过程，并为先进材料的设计提供了信息。随着研究的进展，对卷曲纤维的研究可能会导致更多的突破，增强我们对自然和合成系统的理解。coiled filament的多功能性展示了不同科学领域之间的相互联系，并强调了跨学科方法在解决复杂问题中的重要性。随着我们继续探索卷曲结构的潜力，我们可能会发现新的应用和技术，这些应用和技术可以显著影响我们的日常生活和周围世界。