electric hysteresis effect

简明释义

电滞效应

英英释义

例句

1.The electric hysteresis effect 电滞效应 can impact the performance of sensors used in automotive applications.

在汽车应用中，电滞效应 电滞效应可能影响传感器的性能。

2.The electric hysteresis effect 电滞效应 can cause delays in the response of electronic circuits.

在电子电路中，电滞效应 电滞效应可能导致响应延迟。

3.Understanding the electric hysteresis effect 电滞效应 is crucial for designing efficient magnetic materials.

理解电滞效应 电滞效应对于设计高效的磁性材料至关重要。

4.The electric hysteresis effect 电滞效应 in transformers can lead to energy losses during operation.

变压器中的电滞效应 电滞效应可能会导致运行中的能量损失。

5.Engineers must account for the electric hysteresis effect 电滞效应 when developing inductors.

工程师在开发电感器时必须考虑电滞效应 电滞效应。

作文

The concept of electric hysteresis effect refers to the phenomenon where the output of an electric system depends not only on its current input but also on its past states. This effect is particularly significant in materials that exhibit ferroelectric properties, where the polarization of the material can remain even after the external electric field is removed. Understanding the electric hysteresis effect is crucial for various applications in electronics and materials science.In simple terms, hysteresis can be observed in many physical systems, but in the context of electricity, it often describes how certain materials respond to electric fields. When a voltage is applied to a ferroelectric material, it becomes polarized, meaning that the positive and negative charges within the material are separated. However, when the voltage is removed, the material does not return to its original state immediately. Instead, it retains some of its polarization due to the electric hysteresis effect, which can be graphically represented by a loop known as the hysteresis loop.This loop illustrates the relationship between the electric field applied to the material and the resulting polarization. The area within the loop represents energy loss due to the electric hysteresis effect, which is an important factor to consider in designing efficient electronic devices. For instance, in capacitors and memory devices, minimizing hysteresis can lead to better performance and lower power consumption.In practical terms, the electric hysteresis effect can influence the behavior of various electronic components. For example, in piezoelectric devices, which convert mechanical stress into electrical energy, hysteresis can affect the efficiency and response time of the device. Similarly, in non-volatile memory technologies like ferroelectric RAM (FeRAM), understanding this effect is essential for improving data retention and access speeds.Moreover, the electric hysteresis effect plays a vital role in the development of smart materials and sensors. These materials can change their properties in response to external stimuli, and the hysteresis effect can enhance their sensitivity and reliability. As researchers continue to explore new materials and applications, the significance of the electric hysteresis effect remains a key area of study.In conclusion, the electric hysteresis effect is a fundamental phenomenon in the field of electricity and materials science. Its implications extend across various applications, from everyday electronic devices to advanced technological innovations. By gaining a deeper understanding of this effect, scientists and engineers can develop more efficient and effective solutions that harness the unique properties of materials. As technology continues to evolve, the exploration of the electric hysteresis effect will undoubtedly contribute to future advancements in electronics and materials engineering.

电滞后效应（electric hysteresis effect）是指电气系统的输出不仅取决于其当前输入，还取决于其过去状态的现象。这种效应在表现出铁电特性的材料中尤为重要，这些材料的极化即使在外部电场移除后也会保持。理解electric hysteresis effect对于电子和材料科学的各种应用至关重要。简单来说，滞后现象可以在许多物理系统中观察到，但在电的背景下，它通常描述某些材料对电场的响应。当施加电压到铁电材料时，它会被极化，这意味着材料内部的正负电荷被分开。然而，当电压被移除时，材料并不会立即恢复到原始状态。相反，由于electric hysteresis effect，它保留了一些极化，这可以通过一个称为滞回环的图形表示。这个环描绘了施加于材料的电场与产生的极化之间的关系。环内的面积代表由于electric hysteresis effect造成的能量损失，这是设计高效电子设备时必须考虑的重要因素。例如，在电容器和存储设备中，最小化滞后可以提高性能并降低功耗。在实际应用中，electric hysteresis effect可以影响各种电子元件的行为。例如，在压电设备中，这些设备将机械应力转化为电能，滞后可能会影响设备的效率和响应时间。同样，在非易失性存储技术如铁电RAM（FeRAM）中，理解这种效应对改善数据保持和访问速度至关重要。此外，electric hysteresis effect在智能材料和传感器的发展中也发挥着重要作用。这些材料可以响应外部刺激改变其性质，而滞后效应可以增强其灵敏度和可靠性。随着研究人员继续探索新材料和应用，electric hysteresis effect的重要性仍然是一个关键研究领域。总之，electric hysteresis effect是电气和材料科学领域的一个基本现象。它的影响延伸到各种应用，从日常电子设备到先进的技术创新。通过深入理解这一效应，科学家和工程师可以开发出更高效、更有效的解决方案，利用材料的独特特性。随着技术的不断发展，对electric hysteresis effect的探索无疑将促进电子和材料工程的未来进步。