capture efficiency

简明释义

俘获效率

英英释义

例句

1.By optimizing the design of the solar panels, we were able to enhance their capture efficiency for sunlight.

通过优化太阳能电池板的设计，我们能够提高其对阳光的捕获效率。

2.The researchers focused on improving the capture efficiency of the carbon capture technology.

研究人员专注于提高碳捕集技术的捕获效率。

3.The new filtration system has significantly improved the capture efficiency of pollutants in the water supply.

新的过滤系统显著提高了水源中污染物的捕获效率。

4.The plant's capture efficiency of nitrogen oxides has been a significant factor in reducing air pollution.

该工厂对氮氧化物的捕获效率是减少空气污染的重要因素。

5.In our latest experiment, we measured the capture efficiency of the CO2 scrubbers during different conditions.

在我们最新的实验中，我们测量了不同条件下二氧化碳清除器的捕获效率。

作文

In today's rapidly evolving world, the concept of efficiency has become paramount across various fields, particularly in technology and environmental science. One term that has gained significant attention is capture efficiency, which refers to the effectiveness with which a system can absorb or utilize a resource, such as energy or carbon dioxide. Understanding capture efficiency is crucial for developing sustainable practices and technologies that minimize waste and maximize output.To illustrate the importance of capture efficiency, let us consider renewable energy systems. For instance, solar panels are designed to capture sunlight and convert it into electricity. The capture efficiency of these panels determines how much of the available sunlight they can effectively transform into usable energy. Higher capture efficiency means more energy production from the same amount of sunlight, which is essential for making solar energy a viable alternative to fossil fuels.Similarly, in the context of carbon capture technologies, capture efficiency plays a critical role in combating climate change. These technologies aim to capture carbon dioxide emissions from industrial processes before they enter the atmosphere. The capture efficiency of these systems indicates how much carbon dioxide can be successfully captured and stored or reused. Improving the capture efficiency of carbon capture technologies is vital for reducing greenhouse gas emissions and mitigating global warming.Furthermore, capture efficiency is not limited to energy and environmental applications. In the field of data science, for example, capture efficiency can refer to the ability of algorithms to identify and extract relevant information from vast datasets. As businesses increasingly rely on big data for decision-making, enhancing the capture efficiency of data processing methods becomes essential for gaining insights and driving innovation.The quest for improved capture efficiency often involves research and development efforts aimed at optimizing existing technologies or creating new ones. Engineers and scientists collaborate to design systems that can achieve higher capture efficiency through innovative materials, advanced techniques, and better integration of processes. This interdisciplinary approach not only enhances the performance of individual systems but also contributes to the overall sustainability of industries.Moreover, understanding capture efficiency can empower consumers to make informed choices. For example, when purchasing appliances or vehicles, individuals can consider the capture efficiency of energy use to select products that align with their values regarding sustainability and environmental impact. By prioritizing high capture efficiency options, consumers can contribute to a larger movement towards resource conservation and ecological responsibility.In conclusion, the term capture efficiency encompasses a wide range of applications and implications across various sectors. Whether in renewable energy, carbon capture, or data science, enhancing capture efficiency is crucial for achieving sustainability goals and improving overall performance. As we continue to face global challenges such as climate change and resource depletion, focusing on capture efficiency will be essential for fostering innovation and promoting a more sustainable future.

在当今快速发展的世界中，效率的概念在各个领域变得至关重要，尤其是在科技和环境科学中。一个受到广泛关注的术语是capture efficiency，它指的是一个系统吸收或利用资源（如能量或二氧化碳）的有效性。理解capture efficiency对于开发可持续的实践和技术，以最小化浪费和最大化产出至关重要。为了说明capture efficiency的重要性，让我们考虑可再生能源系统。例如，太阳能电池板旨在捕捉阳光并将其转化为电力。这些电池板的capture efficiency决定了它们能够有效地将多少可用的阳光转化为可用的能量。更高的capture efficiency意味着在相同的阳光条件下产生更多的能量，这对使太阳能成为化石燃料的可行替代品至关重要。类似地，在碳捕集技术的背景下，capture efficiency在应对气候变化中发挥着关键作用。这些技术旨在在工业过程中捕获二氧化碳排放，以防止其进入大气。此类系统的capture efficiency指示了能够成功捕获和储存或再利用的二氧化碳的量。提高碳捕集技术的capture efficiency对于减少温室气体排放和缓解全球变暖至关重要。此外，capture efficiency不仅限于能源和环境应用。在数据科学领域，例如，capture efficiency可以指算法识别和提取大量数据集中相关信息的能力。随着企业越来越依赖大数据进行决策，增强数据处理方法的capture efficiency对于获取洞察力和推动创新变得至关重要。提高capture efficiency的追求通常涉及研究和开发工作，旨在优化现有技术或创造新技术。工程师和科学家合作设计能够通过创新材料、先进技术和更好地整合过程来实现更高capture efficiency的系统。这种跨学科的方法不仅提高了单个系统的性能，还促进了整个行业的可持续性。此外，理解capture efficiency可以使消费者做出明智的选择。例如，在购买家电或车辆时，个人可以考虑能耗的capture efficiency，以选择符合其可持续发展和环境影响价值观的产品。通过优先选择高capture efficiency选项，消费者可以为资源保护和生态责任的大潮作出贡献。总之，术语capture efficiency涵盖了各个部门广泛的应用和影响。无论是在可再生能源、碳捕集还是数据科学中，提高capture efficiency对于实现可持续发展目标和改善整体性能至关重要。随着我们继续面临气候变化和资源枯竭等全球挑战，专注于capture efficiency将对促进创新和推动更可持续的未来至关重要。