active folding

简明释义

活动褶皱;

英英释义

例句

1.The process of active folding can be influenced by temperature and pH levels.

温度和pH水平可以影响活跃折叠的过程。

2.In molecular biology, active folding is crucial for the proper functioning of enzymes.

在分子生物学中，活跃折叠对酶的正常功能至关重要。

3.The protein undergoes active folding during the synthesis process to achieve its functional conformation.

在合成过程中，蛋白质经历活跃折叠以达到其功能构象。

4.Scientists use simulations to predict the active folding pathways of newly discovered proteins.

科学家使用模拟来预测新发现的蛋白质的活跃折叠路径。

5.Researchers study active folding to understand how proteins achieve their complex structures.

研究人员研究活跃折叠以了解蛋白质如何获得其复杂结构。

作文

In the world of materials science and engineering, the concept of active folding has gained significant attention. This term refers to the dynamic process by which materials can change their shape or configuration in response to external stimuli. The ability to fold actively allows for the development of innovative structures that can adapt to various conditions, enhancing their functionality and efficiency. For instance, consider the application of active folding in the design of deployable shelters for disaster relief. When a natural disaster strikes, quick and efficient shelter solutions are crucial. Structures that utilize active folding can be compactly stored and then expanded into fully functional living spaces within minutes. This adaptability not only saves time but also provides immediate safety and comfort to those in need. Moreover, active folding is not limited to temporary structures; it plays a vital role in the field of robotics. Engineers are increasingly incorporating this principle into robotic designs, allowing robots to change shape to navigate through complex environments. For example, soft robots that employ active folding techniques can squeeze through tight spaces or wrap around objects, making them invaluable for search and rescue operations in disaster-stricken areas. The versatility of these robots showcases how active folding can revolutionize the way we approach problem-solving in various fields.In addition to practical applications, the aesthetic potential of active folding cannot be overlooked. Architects and designers are exploring this concept to create visually stunning structures that can transform their appearance based on environmental factors, such as sunlight or wind. Buildings that can open and close their facades using active folding mechanisms not only enhance energy efficiency but also create an engaging experience for occupants and passersby. This interplay between functionality and aesthetics exemplifies the innovative spirit of modern design.The study of active folding also intersects with biology. Nature has long been a source of inspiration for scientists and engineers. The folding mechanisms found in certain plants and animals provide valuable insights into how active folding can be mimicked in artificial systems. For instance, the way leaves fold to protect themselves from harsh weather conditions or how certain flowers bloom can inform the design of materials that respond intelligently to their environment. By understanding these biological processes, researchers can develop new materials that exhibit similar active folding capabilities, leading to advancements in various industries, including textiles and packaging.In conclusion, the concept of active folding represents a fascinating intersection of science, engineering, and art. Its applications are vast and varied, ranging from disaster relief shelters to innovative robotics and architectural marvels. As we continue to explore the potential of active folding, we unlock new possibilities for creating adaptive, efficient, and aesthetically pleasing solutions to the challenges we face. The future of design and technology may very well hinge on our ability to harness the power of active folding in our creations, pushing the boundaries of what is possible and reshaping the world around us.

在材料科学和工程领域，‘active folding’（主动折叠）的概念引起了广泛关注。这个术语指的是材料能够根据外部刺激动态改变其形状或构型的过程。主动折叠的能力使得开发可以适应各种条件的创新结构成为可能，从而增强它们的功能性和效率。例如，考虑到在灾难救援中可部署庇护所的设计。当自然灾害发生时，快速高效的庇护解决方案至关重要。利用‘active folding’的结构可以紧凑地存储，然后在几分钟内扩展为完全功能的居住空间。这种适应性不仅节省了时间，还为需要帮助的人们提供了即时的安全和舒适。此外，‘active folding’不仅限于临时结构；它在机器人领域也发挥着重要作用。工程师们越来越多地将这一原理融入机器人设计中，使机器人能够改变形状以在复杂环境中导航。例如，采用‘active folding’技术的软体机器人可以挤压通过狭小空间或环绕物体，这使它们在灾后救援行动中变得不可或缺。这些机器人的多功能性展示了‘active folding’如何革新我们在各个领域中的问题解决方法。除了实际应用，‘active folding’的美学潜力也不容忽视。建筑师和设计师正在探索这一概念，以创建基于环境因素（如阳光或风）变化外观的视觉惊艳结构。能够使用‘active folding’机制打开和关闭外立面的建筑，不仅提高了能源效率，还为居住者和路人创造了更具吸引力的体验。这种功能性与美学之间的相互作用体现了现代设计的创新精神。‘active folding’的研究还与生物学交叉。自然界长期以来一直是科学家和工程师的灵感来源。某些植物和动物中发现的折叠机制为如何在人工系统中模仿‘active folding’提供了有价值的见解。例如，叶子为了保护自己免受恶劣天气而折叠的方式，或某些花朵盛开的方式，可以为开发能够智能响应环境的新材料提供启示。通过理解这些生物过程，研究人员可以开发出具有类似‘active folding’能力的新材料，从而推动包括纺织品和包装在内的各个行业的进步。总之，‘active folding’的概念代表了科学、工程和艺术的迷人交汇。它的应用广泛而多样，从灾难救援庇护所到创新机器人，再到建筑奇迹。随着我们继续探索‘active folding’的潜力，我们为创造适应性强、高效且美观的解决方案打开了新的可能性，以应对我们面临的挑战。设计和技术的未来可能确实依赖于我们在创造中利用‘active folding’的能力，推动可能性的边界，重塑我们周围的世界。