absolute capacitivity

简明释义

绝对电容率

英英释义

例句

1.Engineers are focusing on improving the absolute capacitivity 绝对电容能力 of supercapacitors to enhance their performance in electric vehicles.

工程师们正在致力于提高超级电容器的绝对电容能力 absolute capacitivity，以增强其在电动汽车中的性能。

2.Research indicates that materials with higher absolute capacitivity 绝对电容能力 can significantly reduce energy loss in circuits.

研究表明，具有更高绝对电容能力 absolute capacitivity的材料可以显著减少电路中的能量损失。

3.The new battery technology has demonstrated an impressive level of absolute capacitivity 绝对电容能力, allowing for faster charging times.

新型电池技术展示了令人印象深刻的绝对电容能力 absolute capacitivity，使充电时间更快。

4.The absolute capacitivity 绝对电容能力 of this new composite material is twice that of traditional options.

这种新复合材料的绝对电容能力 absolute capacitivity是传统选项的两倍。

5.In the field of renewable energy, maximizing absolute capacitivity 绝对电容能力 is crucial for efficient energy storage systems.

在可再生能源领域，最大化绝对电容能力 absolute capacitivity对于高效的能源存储系统至关重要。

作文

In today's rapidly evolving world, the concept of absolute capacitivity plays a crucial role in understanding how systems interact and adapt to various challenges. Absolute capacitivity refers to the inherent ability of a system or organism to absorb, store, and utilize energy or resources effectively without any limitations. This concept can be applied across various fields, including biology, engineering, and environmental science. To illustrate this idea, consider the natural world, where ecosystems demonstrate remarkable absolute capacitivity. For instance, forests have an incredible capacity to capture carbon dioxide from the atmosphere, store it as biomass, and release oxygen back into the environment. This process not only supports life on Earth but also helps mitigate climate change by reducing greenhouse gas concentrations. The absolute capacitivity of forests is essential for maintaining ecological balance and promoting biodiversity. In engineering, the principle of absolute capacitivity can be seen in the design of renewable energy systems. Solar panels, for example, have the ability to harness sunlight and convert it into electricity. The efficiency with which these panels can absorb and utilize solar energy is a reflection of their absolute capacitivity. As technology advances, engineers strive to enhance the absolute capacitivity of these systems, making them more effective and sustainable. By improving the absolute capacitivity of energy systems, we can reduce our reliance on fossil fuels and promote a cleaner, greener future. Moreover, the concept of absolute capacitivity extends to human resilience in the face of adversity. Individuals and communities often exhibit a remarkable capacity to adapt and thrive despite challenges such as economic downturns, natural disasters, or health crises. This human absolute capacitivity is characterized by the ability to learn from experiences, develop new skills, and foster social connections that provide support during difficult times. The resilience demonstrated by individuals and communities showcases the power of absolute capacitivity in overcoming obstacles and achieving personal and collective growth. In conclusion, understanding absolute capacitivity is essential for addressing the complex challenges we face today. Whether in nature, technology, or human behavior, the ability to absorb, store, and utilize resources effectively is fundamental to survival and progress. By recognizing and enhancing our absolute capacitivity, we can create sustainable systems that benefit both people and the planet. As we move forward, it is imperative to embrace the principles of absolute capacitivity in all aspects of life, ensuring a brighter and more resilient future for generations to come.

在当今快速发展的世界中，绝对能力的概念在理解系统如何相互作用和适应各种挑战方面发挥着至关重要的作用。绝对能力指的是一个系统或生物体在没有任何限制的情况下有效吸收、储存和利用能量或资源的固有能力。这个概念可以应用于多个领域，包括生物学、工程学和环境科学。为了说明这个想法，可以考虑自然界，在这里生态系统展现出惊人的绝对能力。例如，森林具有捕获大气中二氧化碳、将其储存为生物质并释放氧气回到环境中的惊人能力。这个过程不仅支持地球上的生命，还通过减少温室气体浓度来帮助缓解气候变化。森林的绝对能力对于维持生态平衡和促进生物多样性至关重要。在工程领域，绝对能力的原则可以在可再生能源系统的设计中看到。例如，太阳能电池板能够利用阳光并将其转化为电力。这些电池板吸收和利用太阳能的效率反映了它们的绝对能力。随着技术的进步，工程师努力提高这些系统的绝对能力，使其更加有效和可持续。通过改善能源系统的绝对能力，我们可以减少对化石燃料的依赖，推动更清洁、更绿色的未来。此外，绝对能力的概念扩展到人类在逆境面前的韧性。个人和社区在经济衰退、自然灾害或健康危机等挑战面前，常常表现出惊人的适应和繁荣能力。这种人类的绝对能力以从经验中学习、发展新技能和培养提供支持的社会联系为特征。在困难时期，个人和社区所展现的韧性展示了绝对能力在克服障碍和实现个人与集体成长中的力量。总之，理解绝对能力对于解决我们今天面临的复杂挑战至关重要。无论是在自然、技术还是人类行为中，有效吸收、储存和利用资源的能力是生存和进步的基础。通过认识和增强我们的绝对能力，我们可以创建有益于人类和地球的可持续系统。随着我们向前发展，必须在生活的各个方面拥抱绝对能力的原则，以确保为后代创造一个更加光明和有韧性的未来。