multicellular electrometer

简明释义

多室静电计

英英释义

例句

1.Using the multicellular electrometer, they were able to detect minute changes in voltage across cell membranes.

利用多细胞电表，他们能够检测到细胞膜上微小的电压变化。

2.Researchers found that the multicellular electrometer provided more accurate readings than traditional methods.

研究人员发现，多细胞电表提供的读数比传统方法更准确。

3.In the study, the multicellular electrometer was crucial for analyzing the interaction between neurons.

在这项研究中，多细胞电表对于分析神经元之间的相互作用至关重要。

4.The laboratory used a multicellular electrometer to measure the electrical activity of different cell types.

实验室使用了一个多细胞电表来测量不同细胞类型的电活动。

5.The team calibrated the multicellular electrometer before conducting their experiments.

团队在进行实验之前对多细胞电表进行了校准。

作文

In the realm of scientific instrumentation, the development of advanced devices has revolutionized our ability to measure and analyze various physical phenomena. One such remarkable device is the multicellular electrometer, which plays a crucial role in the field of electrometry. An multicellular electrometer is an instrument designed to measure electric charge or electrical potential differences with high precision. Its multicellular design allows for multiple measurement cells to operate simultaneously, enhancing the accuracy and efficiency of the readings obtained.The significance of the multicellular electrometer cannot be overstated. In laboratories around the world, researchers utilize this instrument to conduct experiments that require precise measurements of electrical properties. For instance, in the field of physics, understanding the behavior of charged particles under various conditions is essential. The multicellular electrometer provides scientists with the tools needed to quantify these properties accurately.One of the primary advantages of the multicellular electrometer is its ability to minimize errors that may arise from environmental factors. Traditional electrometers often face challenges due to fluctuations in temperature, humidity, or electromagnetic interference. However, the multicellular design helps mitigate these issues by allowing for compensatory measurements across different cells. This feature ensures that the final readings are more reliable and consistent, which is paramount in scientific research.Moreover, the multicellular electrometer is versatile and can be employed in various applications beyond basic research. In medical technology, for example, it is used in electrophysiological studies to monitor heart activity or neural signals. The ability to measure small electrical changes in biological systems can provide invaluable data for diagnosing and treating medical conditions.Another exciting application of the multicellular electrometer is in the field of environmental monitoring. As concerns about pollution and climate change grow, scientists are increasingly tasked with measuring electrical properties of pollutants or changes in atmospheric conditions. The multicellular design allows for comprehensive data collection, enabling researchers to analyze trends and make informed decisions regarding environmental protection.Furthermore, advancements in technology have led to the integration of digital interfaces in modern multicellular electrometers. These interfaces facilitate real-time data analysis and visualization, making it easier for researchers to interpret their results. With the ability to connect to computers and other devices, scientists can store large amounts of data and share findings with colleagues worldwide, fostering collaboration and innovation in research.In conclusion, the multicellular electrometer is a vital instrument in the scientific community, providing accurate and efficient measurements of electrical properties. Its multicellular design enhances reliability and versatility, making it suitable for a wide range of applications, from fundamental research to medical diagnostics and environmental monitoring. As technology continues to evolve, the role of the multicellular electrometer will undoubtedly expand, contributing to advancements in science and technology for years to come.

在科学仪器的领域，先进设备的发展彻底改变了我们测量和分析各种物理现象的能力。其中一种显著的设备是多细胞电表，它在电测量领域中发挥着至关重要的作用。多细胞电表是一种旨在高精度测量电荷或电位差的仪器。其多细胞设计允许多个测量单元同时操作，从而提高了所获得读数的准确性和效率。多细胞电表的重要性不容小觑。在世界各地的实验室中，研究人员利用这一仪器进行需要精确电气特性测量的实验。例如，在物理学领域，理解带电粒子在各种条件下的行为至关重要。多细胞电表为科学家提供了准确量化这些特性的工具。多细胞电表的主要优势之一是其能够最小化由于环境因素引起的误差。传统电表常常面临温度、湿度或电磁干扰波动带来的挑战。然而，多细胞设计通过允许不同单元进行补偿测量来帮助减轻这些问题。此特性确保最终读数更可靠且一致，这在科学研究中至关重要。此外，多细胞电表具有多功能性，可在超越基础研究的各种应用中使用。例如，在医疗技术中，它用于电生理研究，以监测心脏活动或神经信号。测量生物系统中微小电变化的能力可以为诊断和治疗医疗条件提供宝贵数据。多细胞电表的另一个令人兴奋的应用是在环境监测领域。随着对污染和气候变化的关注加剧，科学家们越来越多地被要求测量污染物的电气特性或大气条件的变化。多细胞设计允许全面的数据收集，使研究人员能够分析趋势并就环境保护作出明智决策。此外，现代多细胞电表的技术进步使数字接口的集成成为可能。这些接口促进实时数据分析和可视化，使研究人员更容易解释他们的结果。凭借与计算机和其他设备的连接能力，科学家可以存储大量数据，并与全球同事分享发现，从而促进研究中的合作与创新。总之，多细胞电表是科学界的重要仪器，提供准确和高效的电气特性测量。其多细胞设计增强了可靠性和多功能性，使其适用于从基础研究到医学诊断和环境监测等广泛应用。随着技术的不断发展，多细胞电表的角色无疑会扩展，为未来几年科学和技术的进步做出贡献。