biomimetic

简明释义

英[ˌbaɪəʊmɪˈmetɪk]美[baɪɒmɪˈmetɪk]

adj. 仿生的；生物模拟的

英英释义

单词用法

同义词

反义词

例句

1.Using biomimetic synthesis, the conditions and method of forming ha crystallite film were studied in this paper, and the trial mechanism was discussed.

本文用仿生合成法，对HA微晶薄膜形成的条件及实验方法进行了研究，并讨论了此方法的实验机理。

2.In addition, the applications of polyoxometalate in the area of biomimetic catalysis are discussed.

同时也关注了多金属氧酸盐在仿生催化领域的应用。

3.Biomimetic chemistry could supply the best designing principle for developing modern medical technologies.

仿生化学可以为现代医药技术提供最佳的设计原理。

4.Using the templating of the organic matrix, the new inorganic materials with excellent properties can be prepared by the biomimetic synthesis.

利用有机基质的模板作用能仿生合成出性能优异的新型无机材料。

5.Molecularly imprinted polymers will possess promising application future in the separation and analysis, biomimetic sensors and enzyme mimics catalysis.

分子印迹聚合物在分离分析、仿生传感器和模拟酶催化等领域将具有重要的应用前景。

6.The varieties of biomimetic bone matrix-materials are fabricated to solve the bone defect.

本文对仿生骨基质材料的研究进展进行综述。

7.Creepy yet cute, Osaka University's four-foot-tall Child-robot with Biomimetic Body is designed to learn like a child by watching and interacting with humans.

吓人却又不失可爱，大阪大学发明的四英尺（约1.22米）高的仿生儿童机器人，能像幼儿一样，在观察以及与人互动的过程中习得技能。

8.In medicine, biomimetic 仿生的 implants are designed to closely resemble natural tissues for better integration.

在医学中，仿生的植入物旨在与自然组织紧密相似，以实现更好的整合。

9.The biomimetic 仿生的 robot can fly like a bird, using wing flapping techniques derived from nature.

这款仿生的机器人可以像鸟一样飞行，使用源自自然的翅膀拍打技术。

10.Researchers are developing biomimetic 仿生的 materials that mimic the structure of lotus leaves to create self-cleaning surfaces.

研究人员正在开发仿生的材料，模仿莲叶的结构，以创造自清洁表面。

11.The biomimetic 仿生的 adhesive developed by scientists works underwater, inspired by the sticky feet of frogs.

科学家们开发的仿生的粘合剂能够在水下工作，灵感来自青蛙的粘脚。

12.The new building design features a biomimetic 仿生的 approach, inspired by termite mounds for natural cooling.

这座新建筑设计采用了仿生的方法，受到白蚁巢穴的启发，以实现自然降温。

作文

The concept of biomimetic design has gained significant attention in recent years, as it offers innovative solutions by emulating nature's time-tested patterns and strategies. Biomimetic approaches are not just limited to architecture or product design; they extend to various fields such as medicine, engineering, and environmental science. By studying the intricate mechanisms found in nature, scientists and engineers can develop technologies that are more efficient, sustainable, and harmonious with the environment.One of the most notable examples of biomimetic design is the invention of Velcro, which was inspired by the way burrs stick to animal fur. This simple yet effective mechanism demonstrates how observing natural phenomena can lead to groundbreaking inventions. Similarly, architects have looked to termite mounds for inspiration in designing energy-efficient buildings. The natural ventilation systems found in these mounds allow for temperature regulation without the need for artificial heating or cooling, showcasing the potential of biomimetic principles in reducing energy consumption.In the field of medicine, biomimetic strategies have led to advancements in drug delivery systems. Researchers have developed nanoparticles that mimic the behavior of viruses, allowing them to target specific cells more effectively. This targeted approach not only increases the efficacy of treatments but also minimizes side effects, highlighting the importance of biomimetic techniques in improving health outcomes.Moreover, the study of natural ecosystems has provided valuable insights into sustainable practices. For instance, the way certain plants manage water resources can inform agricultural practices, leading to more efficient irrigation methods. By adopting biomimetic strategies, farmers can enhance crop yields while conserving water, thus addressing the pressing issue of food security in a world facing climate change.Despite the promising applications of biomimetic design, challenges remain in translating these natural principles into practical solutions. One significant hurdle is the complexity of biological systems, which often cannot be replicated precisely in artificial environments. However, with advancements in technology and materials science, researchers are making strides in overcoming these obstacles. For example, 3D printing and synthetic biology are opening new avenues for creating biomimetic materials that can mimic the properties of natural substances, such as spider silk or lotus leaves.In conclusion, the exploration of biomimetic design is a testament to the ingenuity of human innovation inspired by nature. As we continue to face global challenges such as climate change, resource depletion, and health crises, embracing biomimetic principles may provide us with the tools needed to create a more sustainable and resilient future. By learning from the wisdom of nature, we can develop solutions that not only meet our needs but also respect and preserve the delicate balance of our ecosystems.

‘仿生’设计的概念近年来受到广泛关注，因为它通过模拟自然经过时间考验的模式和策略，提供了创新的解决方案。‘仿生’方法不仅限于建筑或产品设计；它们还扩展到医学、工程和环境科学等多个领域。通过研究自然界中复杂的机制，科学家和工程师可以开发出更高效、可持续且与环境和谐的技术。‘仿生’设计最显著的例子之一是维可牢的发明，它的灵感来源于荨麻刺在动物毛发上的附着方式。这一简单而有效的机制展示了观察自然现象如何导致突破性发明。同样，建筑师们也借鉴了白蚁巢穴的设计灵感，设计出节能建筑。这些巢穴中的自然通风系统可以在不需要人工供暖或制冷的情况下调节温度，展示了‘仿生’原则在减少能源消耗方面的潜力。在医学领域，‘仿生’策略促成了药物递送系统的进步。研究人员开发了模仿病毒行为的纳米颗粒，使其能够更有效地靶向特定细胞。这种靶向方法不仅提高了治疗效果，还减少了副作用，突显了‘仿生’技术在改善健康结果方面的重要性。此外，对自然生态系统的研究为可持续实践提供了宝贵的见解。例如，某些植物管理水资源的方式可以为农业实践提供信息，从而导致更高效的灌溉方法。通过采用‘仿生’策略，农民可以在节水的同时提高作物产量，从而应对气候变化带来的紧迫粮食安全问题。尽管‘仿生’设计的应用前景广阔，但在将这些自然原则转化为实际解决方案时仍面临挑战。其中一个重要障碍是生物系统的复杂性，这往往无法在人工环境中精确复制。然而，随着技术和材料科学的进步，研究人员正在努力克服这些障碍。例如，3D打印和合成生物学为创造能够模仿自然物质（如蜘蛛丝或荷叶）特性的‘仿生’材料开辟了新的途径。总之，探索‘仿生’设计证明了人类创新的智慧，受到了自然的启发。随着我们继续面临全球性挑战，如气候变化、资源枯竭和健康危机，接受‘仿生’原则可能为我们提供创建更可持续和韧性未来所需的工具。通过学习自然的智慧，我们可以开发出不仅满足我们需求而且尊重和保护我们生态系统微妙平衡的解决方案。