self repairing

简明释义

自修

英英释义

例句

1.Researchers are developing materials that are self repairing 自我修复 to extend the lifespan of products.

研究人员正在开发自我修复 self repairing 材料，以延长产品的使用寿命。

2.The self repairing 自我修复 technology in this car helps fix small dents automatically.

这款车中的自我修复 self repairing 技术可以自动修复小凹痕。

3.The self repairing 自我修复 paint used in this building can mend itself after being scratched.

这栋建筑中使用的自我修复 self repairing 油漆可以在被划伤后自行修复。

4.The new smartphone features a self repairing 自我修复 screen that can heal minor scratches.

这款新智能手机配备了一个自我修复 self repairing 屏幕，可以修复轻微划痕。

5.These self repairing 自我修复 polymers can close up tears when exposed to heat.

这些自我修复 self repairing 聚合物在加热时可以闭合撕裂。

作文

In today's fast-paced world, the concept of self repairing has gained significant attention across various fields, including technology, biology, and materials science. The ability of a system or organism to automatically restore itself after damage is not only fascinating but also crucial for sustainability and efficiency. This essay explores the implications and applications of self repairing mechanisms in different domains, highlighting their importance in our daily lives and future innovations.Firstly, in the realm of technology, the idea of self repairing systems is becoming increasingly prevalent. For instance, software applications are now being designed with built-in recovery features that allow them to fix bugs and errors autonomously. This self-sustaining capability reduces downtime and enhances user experience. Moreover, hardware components are being developed with self repairing properties, such as smartphones with screens that can heal minor scratches. These advancements not only improve product lifespan but also contribute to reducing electronic waste, which is a growing environmental concern.Secondly, the natural world provides numerous examples of self repairing systems. Many organisms possess remarkable regenerative abilities. For example, certain species of starfish can regenerate lost limbs, while some amphibians can regrow entire limbs or even parts of their hearts. Understanding these biological processes can inspire scientists to develop new medical treatments for humans. Tissue engineering and regenerative medicine aim to harness the principles of self repairing found in nature to create therapies that promote healing and restoration in injured tissues.Furthermore, materials science is witnessing groundbreaking innovations driven by the concept of self repairing. Researchers are developing polymers and composites that can autonomously seal cracks and damages when exposed to specific stimuli, such as heat or light. This technology has the potential to revolutionize construction and manufacturing industries by significantly enhancing the durability and longevity of structures and products. Imagine buildings that can repair themselves after sustaining damage from natural disasters, or vehicles that can mend their own bodywork after minor collisions.The implications of self repairing technologies extend beyond mere convenience; they represent a shift towards more sustainable practices. By minimizing the need for repairs and replacements, we can conserve resources and reduce environmental impact. As we continue to face challenges related to climate change and resource depletion, embracing self repairing solutions may be key to achieving a more sustainable future.In conclusion, the concept of self repairing holds immense potential across various fields, from technology to biology and materials science. The ability to autonomously restore functionality not only enhances efficiency but also promotes sustainability. As research continues to uncover the secrets behind self repairing mechanisms, we can expect to see innovative applications that will transform our world and improve our quality of life. Embracing this concept could lead us to a future where systems and organisms alike can thrive despite challenges, ultimately fostering resilience and sustainability in an ever-changing environment.

在当今快节奏的世界中，自我修复的概念在技术、生物学和材料科学等各个领域引起了广泛关注。一个系统或生物体在受损后能够自动恢复自身的能力，不仅令人着迷，而且对可持续性和效率至关重要。本文探讨了自我修复机制在不同领域的影响和应用，突显了它们在我们日常生活和未来创新中的重要性。首先，在技术领域，自我修复系统的理念日益普及。例如，软件应用程序现在被设计为具有内置的恢复功能，能够自主修复错误和漏洞。这种自我维持的能力减少了停机时间，提升了用户体验。此外，硬件组件也在开发具有自我修复特性的产品，如可以修复轻微划痕的智能手机屏幕。这些进步不仅提高了产品的使用寿命，还帮助减少电子废物，这正是一个日益严重的环境问题。其次，自然界提供了许多自我修复系统的例子。许多生物体具有显著的再生能力。例如，某些种类的海星能够再生失去的肢体，而一些两栖动物则可以再生整个肢体甚至心脏的一部分。了解这些生物过程可以激励科学家开发新的医疗治疗方法。组织工程和再生医学旨在利用自然界中发现的自我修复原理，创造促进受伤组织愈合和恢复的疗法。此外，材料科学正在见证由自我修复概念推动的突破性创新。研究人员正在开发聚合物和复合材料，当暴露在特定刺激（如热或光）下时，可以自主密封裂缝和损伤。这项技术有潜力彻底改变建筑和制造业，通过显著增强结构和产品的耐用性和使用寿命。想象一下，能够在遭受自然灾害后自我修复的建筑，或者能够在发生小碰撞后自行修复车身的车辆。自我修复技术的意义超越了便利，它代表了向更可持续实践转变。通过最小化维修和更换的需求，我们可以节约资源并减少环境影响。随着我们继续面临与气候变化和资源枯竭相关的挑战，采用自我修复解决方案可能是实现更可持续未来的关键。总之，自我修复的概念在技术、生物学和材料科学等多个领域具有巨大的潜力。能够自主恢复功能不仅提高了效率，还有助于促进可持续性。随着研究不断揭示自我修复机制背后的秘密，我们可以期待看到将改变我们世界并改善我们生活质量的创新应用。拥抱这一概念可能会引导我们走向一个尽管面临挑战仍能蓬勃发展的未来，最终在不断变化的环境中培养韧性和可持续性。