interdigitated structure

简明释义

交叉指型结构

英英释义

例句

1.The interdigitated structure in this microfluidic device allows for better mixing of fluids.

该微流体设备中的交错结构可以更好地混合液体。

2.The design of the new semiconductor device features an interdigitated structure that enhances its performance.

新半导体设备的设计采用了交错结构，提高了其性能。

3.The efficiency of the battery was improved by using an interdigitated structure in the electrode design.

通过在电极设计中使用交错结构，电池的效率得到了提高。

4.In piezoelectric sensors, the interdigitated structure is crucial for converting mechanical stress into electrical signals.

在压电传感器中，交错结构对于将机械应力转化为电信号至关重要。

5.Researchers are studying the effects of temperature on the interdigitated structure of organic solar cells.

研究人员正在研究温度对有机太阳能电池的交错结构的影响。

作文

The concept of an interdigitated structure is fascinating and plays a significant role in various fields, including materials science, biology, and engineering. An interdigitated structure refers to a configuration where two or more elements are arranged in a way that their 'fingers' interlock or overlap with each other. This arrangement can enhance the properties of the materials involved, leading to improved performance in applications ranging from sensors to energy storage devices.In materials science, researchers often explore interdigitated structures to create composite materials that exhibit superior mechanical and thermal properties. For instance, when designing a new polymer composite, engineers might incorporate fibers that are arranged in an interdigitated structure. This configuration allows for better load distribution and increases the overall strength of the material. The interlocking nature of the fibers helps prevent delamination, which is a common failure mode in composite materials.Similarly, in the field of electronics, interdigitated structures are widely used in the design of capacitors and sensors. An interdigitated capacitor consists of two sets of conductive plates that are arranged in an overlapping pattern. This design maximizes the surface area while minimizing the distance between the plates, resulting in higher capacitance values. Such capacitors are crucial in applications where space is limited, such as in mobile devices and compact electronic circuits.Biological systems also exhibit interdigitated structures, particularly at the cellular level. For example, the interdigitation of cell membranes can facilitate communication and transport between cells. This phenomenon is essential for maintaining homeostasis within tissues and organs. Understanding these biological interdigitated structures can lead to advancements in medical treatments and regenerative medicine.Moreover, the study of interdigitated structures has implications for energy storage technologies, particularly in batteries and supercapacitors. Researchers are investigating how to optimize the arrangement of electrodes in these devices to improve charge capacity and discharge rates. By employing an interdigitated structure for the electrodes, it is possible to increase the contact area between the electrolyte and the electrodes, thus enhancing the overall efficiency of the energy storage system.In conclusion, the term interdigitated structure encapsulates a critical design principle that transcends multiple disciplines. Whether in the development of advanced materials, innovative electronic components, or biological systems, the interlocking nature of these structures can lead to significant improvements in performance and functionality. As research continues to evolve, the understanding and application of interdigitated structures will undoubtedly pave the way for new technologies and solutions to complex challenges in science and engineering.

“交错结构”这一概念引人入胜，并在材料科学、生物学和工程等多个领域中发挥着重要作用。“交错结构”是指两种或多种元素以其“手指”相互交错或重叠的方式排列。这种排列可以增强所涉及材料的特性，从而在传感器到能量存储设备等应用中提高性能。在材料科学中，研究人员经常探索“交错结构”以创建具有优越机械和热性能的复合材料。例如，在设计新型聚合物复合材料时，工程师可能会加入以“交错结构”排列的纤维。这种配置允许更好的载荷分配，并增加材料的整体强度。纤维的交错特性有助于防止分层，这是复合材料中常见的失效模式。同样，在电子学领域，“交错结构”被广泛应用于电容器和传感器的设计中。一个“交错电容器”由两组以重叠模式排列的导电板组成。这种设计最大化了表面积，同时最小化了板之间的距离，从而导致更高的电容值。这类电容器在空间有限的应用中至关重要，例如在移动设备和紧凑型电子电路中。生物系统也表现出“交错结构”，特别是在细胞层面。例如，细胞膜的交错可以促进细胞之间的通信和运输。这一现象对于维持组织和器官内的稳态至关重要。理解这些生物“交错结构”可以推动医学治疗和再生医学的进步。此外，对“交错结构”的研究对能量存储技术，特别是在电池和超级电容器中也有影响。研究人员正在调查如何优化这些设备中电极的排列，以改善充电能力和放电速率。通过为电极采用“交错结构”，可以增加电解质与电极之间的接触面积，从而提高能量存储系统的整体效率。总之，术语“交错结构”概括了一种跨越多个学科的重要设计原则。无论是在先进材料的开发、创新电子组件，还是生物系统中，这些结构的交错特性都可以显著提高性能和功能。随着研究的不断发展，对“交错结构”的理解和应用无疑将为科学和工程中的复杂挑战提供新的技术和解决方案。