electroactivity
简明释义
英[ɪˌlɛktrəʊˈæktɪvɪti]美[ɪˌlɛktrəˈæktɪvɪti]
n. 电活性
英英释义
Electroactivity refers to the ability of a substance or material to conduct electricity and respond to electrical stimulation. | 电活性是指物质或材料导电并对电刺激作出反应的能力。 |
单词用法
电活性材料 | |
电活性测量 | |
电活性响应 | |
高电活性 | |
低电活性 | |
增强的电活性 |
同义词
| 电活动 | The electroactivity of the material was tested using a potentiostat. | 该材料的电活动通过使用电位统计仪进行测试。 |
反义词
例句
1.High molecular polyaniline and its derivatives have good electroactivity.
高分子聚苯胺及其衍生物具有良好的电活性。
2.Objective:To investigate the effect of electroacupuncturing Pishu on electroactivity of gastrointestinal smooth muscle in acute gastric ulcer rats and explore its mechanism.
目的:观察电针“脾俞”对胃窦部溃疡大鼠胃肠平滑肌电活动的影响,并探讨其作用机制。
3.Objective:To investigate the effect of electroacupuncturing Pishu on electroactivity of gastrointestinal smooth muscle in acute gastric ulcer rats and explore its mechanism.
目的:观察电针“脾俞”对胃窦部溃疡大鼠胃肠平滑肌电活动的影响,并探讨其作用机制。
4.The researchers studied the electroactivity 电活性 of the newly developed battery material.
研究人员研究了新开发的电池材料的电活性。
5.In bioengineering, understanding the electroactivity 电活性 of cells is crucial for tissue regeneration.
在生物工程中,理解细胞的电活性对于组织再生至关重要。
6.The electroactivity 电活性 of the surface can be enhanced by applying a specific coating.
通过施加特定涂层,可以增强表面的电活性。
7.Scientists measured the electroactivity 电活性 of the microbial fuel cell during the experiment.
科学家在实验中测量了微生物燃料电池的电活性。
8.The electroactivity 电活性 of the polymer was tested under various conditions.
该聚合物的电活性在不同条件下进行了测试。
作文
Electroactivity is a term that refers to the ability of a substance to conduct electricity and respond to electrical stimuli. This property is crucial in many fields, including chemistry, biology, and materials science. Understanding electroactivity (电活性) is essential for developing new technologies and improving existing ones. In this essay, I will explore the significance of electroactivity (电活性) in various applications, particularly in the context of electrochemical sensors, batteries, and biological systems.One of the most prominent applications of electroactivity (电活性) is in the field of electrochemical sensors. These sensors are widely used for detecting various substances, such as gases, ions, or biomolecules. The electroactivity (电活性) of the sensor materials determines their sensitivity and selectivity. For instance, materials like graphene and conducting polymers exhibit high electroactivity (电活性), making them ideal candidates for sensor applications. By leveraging the electroactivity (电活性) of these materials, researchers can develop sensors that provide real-time monitoring of environmental pollutants or biomarkers in medical diagnostics.In addition to sensors, electroactivity (电活性) plays a vital role in energy storage devices, particularly batteries. Lithium-ion batteries, which power everything from smartphones to electric vehicles, rely on the electroactivity (电活性) of electrode materials to store and release energy efficiently. The choice of electrode materials directly affects the battery's performance, including its capacity, charging speed, and overall lifespan. Researchers are constantly exploring new materials with enhanced electroactivity (电活性) to improve battery technology. For example, silicon has shown promise as an anode material due to its high theoretical capacity, but its practical application has been limited by challenges related to electroactivity (电活性) during cycling. Addressing these challenges is crucial for the advancement of next-generation batteries.Furthermore, electroactivity (电活性) is also significant in biological systems. Many biological processes involve electron transfer reactions, which are fundamental to cellular respiration and metabolism. Enzymes, for instance, often possess inherent electroactivity (电活性), allowing them to facilitate redox reactions necessary for life. Understanding the electroactivity (电活性) of these biological molecules can lead to advancements in biotechnology and medicine. For example, bioelectronic devices that utilize the electroactivity (电活性) of living cells can be developed for applications in drug delivery and tissue engineering.In conclusion, electroactivity (电活性) is a critical property that influences various scientific and technological fields. Its implications in electrochemical sensors, energy storage devices, and biological systems highlight the importance of understanding and harnessing this property. As research continues to evolve, the potential applications of electroactivity (电活性) will undoubtedly expand, paving the way for innovative solutions to contemporary challenges. By investing in the study of electroactivity (电活性), we can unlock new possibilities that benefit society as a whole.
电活性是一个术语,指的是物质导电和响应电刺激的能力。这一特性在许多领域中至关重要,包括化学、生物学和材料科学。理解电活性(electroactivity)对于开发新技术和改善现有技术至关重要。在这篇文章中,我将探讨电活性(electroactivity)在各种应用中的重要性,特别是在电化学传感器、电池和生物系统的背景下。电活性(electroactivity)最突出的应用之一是在电化学传感器领域。这些传感器广泛用于检测各种物质,如气体、离子或生物分子。传感器材料的电活性(electroactivity)决定了它们的灵敏度和选择性。例如,石墨烯和导电聚合物等材料表现出高电活性(electroactivity),使其成为传感器应用的理想候选者。通过利用这些材料的电活性(electroactivity),研究人员可以开发出实时监测环境污染物或医学诊断中生物标志物的传感器。除了传感器,电活性(electroactivity)在能源存储设备中也发挥着重要作用,特别是在电池中。锂离子电池为从智能手机到电动汽车的一切提供动力,依赖于电极材料的电活性(electroactivity)来高效地存储和释放能量。电极材料的选择直接影响电池的性能,包括其容量、充电速度和整体寿命。研究人员不断探索具有增强电活性(electroactivity)的新材料,以改善电池技术。例如,硅作为阳极材料显示出良好的前景,因为它具有高理论容量,但由于与循环过程中的电活性(electroactivity)相关的挑战,其实际应用受到限制。解决这些挑战对下一代电池的进步至关重要。此外,电活性(electroactivity)在生物系统中也非常重要。许多生物过程涉及电子转移反应,这对细胞呼吸和代谢至关重要。例如,酶通常具有固有的电活性(electroactivity),使其能够促进生命所需的氧化还原反应。理解这些生物分子的电活性(electroactivity)可以推动生物技术和医学的发展。例如,利用活细胞的电活性(electroactivity)开发的生物电子设备可以用于药物递送和组织工程等应用。总之,电活性(electroactivity)是影响各个科学和技术领域的重要特性。它在电化学传感器、能源存储设备和生物系统中的影响突显了理解和利用这一特性的必要性。随着研究的不断发展,电活性(electroactivity)的潜在应用无疑会扩大,为当代挑战提供创新解决方案。通过投资于电活性(electroactivity)的研究,我们可以解锁有益于整个社会的新可能性。
