electronic charge

简明释义

电子电荷

英英释义

例句

1.The electronic charge 电子电荷 in the capacitor can be released quickly.

电容器中的电子电荷 电子电荷可以快速释放。

2.Electrons carry a negative electronic charge 电子电荷 while protons carry a positive one.

电子携带负的电子电荷 电子电荷，而质子则携带正的。

3.Static electricity is a result of an imbalance of electronic charge 电子电荷 on surfaces.

静电是表面电子电荷 电子电荷失衡的结果。

4.The battery stores an electronic charge 电子电荷 that powers the device.

电池储存的电子电荷 电子电荷为设备供电。

5.When you plug in your phone, it begins to accumulate an electronic charge 电子电荷.

当你插入手机时，它开始积累电子电荷 电子电荷。

作文

The concept of electronic charge plays a fundamental role in the field of physics and chemistry. It refers to the property of subatomic particles, such as electrons and protons, that causes them to experience a force when placed in an electromagnetic field. In simpler terms, electronic charge can be thought of as the 'currency' of electricity, allowing particles to interact with one another through electromagnetic forces. To understand electronic charge, it is essential to first recognize the two types of charges: positive and negative. Protons carry a positive charge, while electrons carry a negative charge. When these particles come together, they create an attractive force due to their opposite charges, which is why atoms can form stable structures. This interaction is crucial for the formation of molecules, which are the building blocks of matter. In practical applications, electronic charge is what allows electrical devices to function. For instance, when you turn on a light switch, you are essentially allowing electrons to flow through a circuit. This flow of negatively charged electrons is what creates light and heat in a bulb. The movement of electronic charge is also responsible for powering computers, smartphones, and countless other devices that have become integral to modern life. Moreover, the manipulation of electronic charge is at the heart of many technological advancements. For example, in semiconductors, the control of electron flow enables the creation of transistors, which are the building blocks of all modern electronic devices. By understanding how to manage electronic charge, engineers can design more efficient circuits and improve the performance of electronic components. Another significant aspect of electronic charge is its role in chemical reactions. During a reaction, electrons may be transferred between atoms, leading to the formation of new substances. This transfer of charge is essential for processes such as combustion, respiration, and photosynthesis, which sustain life on Earth. By studying how electronic charge interacts during these reactions, scientists can develop new materials and energy sources, paving the way for innovations in various fields.In conclusion, electronic charge is not just a mere scientific concept; it is a vital element that underpins the functioning of the universe. From the smallest atoms to the largest technological systems, the principles of electronic charge govern how matter behaves and interacts. As we continue to explore the depths of physics and chemistry, our understanding of electronic charge will undoubtedly lead to new discoveries and advancements that can shape the future of technology and science. Therefore, grasping the significance of electronic charge is essential for anyone interested in the natural sciences or engineering.

电子电荷的概念在物理和化学领域中扮演着基础性的角色。它指的是亚原子粒子（如电子和质子）所具有的特性，这种特性使它们在置于电磁场中时会受到力的作用。简单来说，电子电荷可以被视为电力的“货币”，使粒子能够通过电磁力相互作用。要理解电子电荷，首先必须认识到两种类型的电荷：正电荷和负电荷。质子带有正电荷，而电子带有负电荷。当这些粒子结合在一起时，由于它们的电荷相反，会产生一种吸引力，这就是为什么原子能够形成稳定结构。这种相互作用对分子的形成至关重要，而分子又是物质的构建块。在实际应用中，电子电荷使得电气设备得以正常运作。例如，当你打开灯开关时，你实际上是在允许电子流过电路。负电荷电子的流动就是在灯泡中产生光和热的原因。电子电荷的运动也负责为计算机、智能手机以及无数其他已成为现代生活不可或缺的设备供电。此外，操控电子电荷是许多技术进步的核心。例如，在半导体中，电子流的控制使得晶体管的制造成为可能，而晶体管则是所有现代电子设备的基本组成部分。通过理解如何管理电子电荷，工程师可以设计更高效的电路，提高电子元件的性能。电子电荷的另一个重要方面是它在化学反应中的作用。在反应过程中，电子可能在原子之间转移，从而形成新的物质。这种电荷的转移对燃烧、呼吸和光合作用等过程至关重要，这些过程维持着地球上的生命。通过研究电子电荷在这些反应中的相互作用，科学家可以开发新材料和能源，为各个领域的创新铺平道路。总之，电子电荷不仅仅是一个科学概念；它是支撑宇宙运作的重要元素。从最小的原子到最大的技术系统，电子电荷的原理支配着物质的行为和相互作用。随着我们继续探索物理和化学的深度，对电子电荷的理解无疑将导致新的发现和进步，这些发现和进步可以塑造科技和科学的未来。因此，掌握电子电荷的重要性对于任何对自然科学或工程感兴趣的人来说都是至关重要的。