helical twist
简明释义
螺线扭曲
英英释义
A helical twist refers to a spiral or corkscrew-like configuration or arrangement, often seen in structures such as DNA or certain types of springs. | 螺旋扭转指的是一种螺旋或螺旋状的结构或排列,常见于如DNA或某些类型的弹簧等结构中。 |
例句
1.In engineering, the design of springs often incorporates a helical twist 螺旋扭转 to enhance their elasticity and strength.
在工程中,弹簧的设计通常包含helical twist 螺旋扭转,以增强其弹性和强度。
2.The DNA molecule is famous for its double helix structure, which features a distinct helical twist 螺旋扭转 that encodes genetic information.
DNA分子以其双螺旋结构而闻名,具有独特的helical twist 螺旋扭转,编码遗传信息。
3.The artist used a helical twist 螺旋扭转 in the sculpture to create a sense of movement and dynamic energy.
艺术家在雕塑中使用了helical twist 螺旋扭转,以创造出运动感和动态能量。
4.The helical twist 螺旋扭转 of the staircase adds an elegant touch to the building's interior design.
楼梯的helical twist 螺旋扭转为建筑的室内设计增添了一丝优雅。
5.In biology, the helical twist 螺旋扭转 of certain proteins is crucial for their function and stability.
在生物学中,某些蛋白质的helical twist 螺旋扭转对其功能和稳定性至关重要。
作文
The concept of a helical twist is fascinating and can be observed in various natural and artificial structures around us. A helical twist refers to a spiral shape or configuration that twists around a central axis, resembling the structure of a spring or DNA strand. This unique formation is not only aesthetically pleasing but also serves functional purposes in many contexts. In nature, the helical twist can be seen in the growth patterns of certain plants, such as climbing vines. These plants utilize the helical twist to wrap around supports, allowing them to rise towards sunlight. Similarly, the shells of some mollusks exhibit this twisting form, which helps in creating a compact and strong structure that protects the organism inside. The helical twist in these cases is a testament to nature's ingenuity, optimizing both strength and efficiency.In the realm of science, the helical twist is most famously exemplified by the double helix structure of DNA. This iconic shape was discovered by James Watson and Francis Crick in the mid-20th century and has since become a fundamental concept in genetics. The helical twist of DNA not only stores genetic information but also plays a crucial role in the processes of replication and protein synthesis. Understanding the helical twist of DNA has paved the way for advancements in biotechnology, medicine, and forensic science.Moreover, the helical twist is prevalent in engineering and architecture. For instance, spiral staircases utilize this design to save space while providing an elegant means of elevation. The helical twist allows for a continuous ascent without the need for a large footprint, making it an ideal choice for urban environments where space is at a premium. Additionally, the helical twist can be found in various mechanical components, such as screws and gears, where it aids in converting rotational motion into linear movement.The aesthetic appeal of the helical twist cannot be overlooked either. Artists and designers often incorporate this motif into their work, drawing inspiration from its organic form. From sculptures to jewelry, the helical twist conveys a sense of movement and fluidity, captivating viewers with its dynamic appearance.In conclusion, the helical twist is more than just a geometric configuration; it is a principle that permeates various fields, from biology to engineering and art. Its presence in nature highlights the elegance of evolutionary adaptations, while its applications in technology demonstrate human ingenuity. By appreciating the significance of the helical twist, we can gain deeper insights into the interconnectedness of life, design, and functionality. As we continue to explore and innovate, the helical twist will undoubtedly remain a source of inspiration and a symbol of complexity in simplicity.
‘螺旋扭曲’这个概念令人着迷,可以在我们周围的各种自然和人工结构中观察到。‘螺旋扭曲’指的是一种围绕中心轴线扭曲的螺旋形状或构造,类似于弹簧或DNA链的结构。这种独特的形态不仅在美学上令人愉悦,而且在许多场合中也具有功能性。在自然界中,‘螺旋扭曲’可以在某些植物的生长模式中看到,比如攀缘藤本植物。这些植物利用‘螺旋扭曲’来缠绕支撑物,使它们向阳光生长。同样,一些软体动物的壳也表现出这种扭曲的形态,这有助于形成一个紧凑而坚固的结构,保护内部的生物。在这些情况下,‘螺旋扭曲’是自然聪明才智的证明,优化了强度和效率。在科学领域,‘螺旋扭曲’最著名的例子是DNA的双螺旋结构。这个标志性的形状是由詹姆斯·沃森和弗朗西斯·克里克在20世纪中期发现的,至今已成为遗传学中的基本概念。DNA的‘螺旋扭曲’不仅储存遗传信息,还在复制和蛋白质合成过程中发挥着关键作用。理解DNA的‘螺旋扭曲’为生物技术、医学和法医科学的进步铺平了道路。此外,‘螺旋扭曲’在工程和建筑中也很常见。例如,螺旋楼梯利用这一设计节省空间,同时提供优雅的升降方式。‘螺旋扭曲’允许连续上升,而无需占用大面积的空间,非常适合城市环境中空间紧张的情况。此外,‘螺旋扭曲’还可以在各种机械部件中找到,如螺钉和齿轮,在这些部件中,它有助于将旋转运动转换为线性运动。‘螺旋扭曲’的美学吸引力也不可忽视。艺术家和设计师经常将这一主题融入他们的作品中,从其有机形式中汲取灵感。从雕塑到珠宝,‘螺旋扭曲’传达了一种运动和流动感,以其动态外观吸引观众。总之,‘螺旋扭曲’不仅仅是几何构造;它是一个渗透多个领域的原则,从生物学到工程学再到艺术。它在自然界中的存在突显了进化适应的优雅,而它在技术中的应用则展示了人类的聪明才智。通过欣赏‘螺旋扭曲’的重要性,我们可以更深入地理解生命、设计和功能之间的相互联系。在我们继续探索和创新的过程中,‘螺旋扭曲’无疑将继续成为灵感的源泉和复杂性与简单性的象征。
相关单词
