galvanism

简明释义

英[ˈɡælvənɪzəm]美[ˈɡælvənɪzəm]

n. 电疗法；流电

英英释义

单词用法

同义词

反义词

例句

1.The main structure have: Electromagnet and Heng galvanism source, numerical type Gauss account (the effect of Huo er) and ammeter and volt account, have control dish of illuminate the system.

主要结构有：电磁铁和恒流电源、数字式高斯计(霍尔效应)、安培计和伏特计、配有照明系统的控制盘。

2.The main structure have: Electromagnet and Heng galvanism source, numerical type Gauss account (the effect of Huo er) and ammeter and volt account, have control dish of illuminate the system.

主要结构有：电磁铁和恒流电源、数字式高斯计(霍尔效应)、安培计和伏特计、配有照明系统的控制盘。

3.The discovery of galvanism revolutionized the field of bioelectricity.

对电刺激的发现彻底改变了生物电学领域。

4.Many scientists in the 19th century were fascinated by galvanism and its effects on living tissues.

19世纪的许多科学家对电刺激及其对活体组织的影响感到着迷。

5.The experiments conducted by Luigi Galvani laid the groundwork for the study of galvanism.

卢伊吉·伽尔瓦尼所做的实验为电刺激的研究奠定了基础。

6.In medicine, galvanism is sometimes used to treat muscle disorders.

在医学中，电刺激有时用于治疗肌肉疾病。

7.Artists have used the concept of galvanism to inspire their works, reflecting the connection between electricity and life.

艺术家们利用电刺激的概念来激发他们的作品，反映电与生命之间的联系。

作文

The term galvanism refers to the phenomenon of electricity produced by chemical reactions, particularly in the context of its early applications in medicine and science. Named after the Italian scientist Luigi Galvani, who discovered that frog legs twitched when exposed to electric currents, galvanism has played a crucial role in the development of bioelectricity and electrotherapy. In this essay, we will explore the historical context of galvanism, its implications in modern science, and its impact on our understanding of the nervous system. Historically, galvanism emerged during the late 18th century, a time when the boundaries of science were being pushed. Galvani's experiments with frog legs sparked curiosity among scientists and philosophers alike. His findings suggested that there was a connection between electricity and biological functions, which was revolutionary at the time. This led to further investigations into the nature of electricity and its relationship with living organisms. One of the most significant contributions of galvanism was its influence on the field of neurology. The idea that electrical impulses could stimulate muscle contractions paved the way for understanding how nerves function. This laid the groundwork for future research into the nervous system and the development of various medical treatments. For instance, the principles of galvanism are still applied today in techniques such as transcutaneous electrical nerve stimulation (TENS), which is used for pain relief. Moreover, galvanism also contributed to the birth of the field of electrophysiology, which studies the electrical properties of biological cells and tissues. This branch of science has provided invaluable insights into how electrical signals govern heartbeats, brain activity, and muscle movements. The discoveries made possible by galvanism have not only advanced our understanding of human physiology but have also led to innovations in medical devices like pacemakers and neurostimulators. In literature and art, galvanism inspired many thinkers and creators. The notion of reanimating the dead through electrical stimulation captured the imagination of writers such as Mary Shelley, whose novel "Frankenstein" explored themes of life, death, and the ethical implications of scientific experimentation. This intersection of science and art illustrates how galvanism permeated cultural consciousness, prompting discussions about the moral responsibilities of scientists. In conclusion, galvanism represents a pivotal moment in the history of science, marking the intersection of electricity and biology. Its discovery opened up new avenues for research and innovation, leading to significant advancements in medicine and our understanding of the human body. As we continue to explore the complexities of bioelectricity, the legacy of galvanism reminds us of the profound connections between science, ethics, and the very essence of life itself. Understanding galvanism not only enriches our knowledge of scientific history but also encourages us to reflect on the implications of our technological advancements in contemporary society.

术语galvanism指的是由化学反应产生的电现象，特别是在其早期在医学和科学中的应用。这个词以意大利科学家路易吉·伽尔瓦尼的名字命名，他发现当青蛙腿暴露在电流中时会抽动，galvanism在生物电和电疗的发展中发挥了至关重要的作用。在这篇文章中，我们将探讨galvanism的历史背景、它在现代科学中的意义以及它对我们理解神经系统的影响。 从历史上看，galvanism出现在18世纪末，那是一个科学边界不断被推动的时代。伽尔瓦尼对青蛙腿的实验引发了科学家和哲学家的好奇。他的发现表明电与生物功能之间存在联系，这在当时是革命性的。这导致了对电的性质及其与生物体之间关系的进一步研究。 galvanism最重要的贡献之一是它对神经学领域的影响。电信号可以刺激肌肉收缩的想法为理解神经的功能铺平了道路。这为未来对神经系统的研究奠定了基础，并促进了各种医疗治疗的发展。例如，galvanism的原理至今仍然应用于经皮电神经刺激（TENS）技术，用于缓解疼痛。 此外，galvanism还促进了电生理学领域的诞生，该领域研究生物细胞和组织的电特性。这个科学分支为我们提供了关于电信号如何支配心跳、大脑活动和肌肉运动的宝贵见解。galvanism所带来的发现不仅推动了我们对人体生理的理解，还导致了心脏起搏器和神经刺激器等医疗设备的创新。 在文学和艺术中，galvanism激发了许多思想家和创作者的灵感。通过电刺激复活死者的概念吸引了作家们的想象，例如玛丽·雪莱的小说《弗兰肯斯坦》，探讨了生命、死亡和科学实验的伦理含义。这种科学与艺术的交汇展示了galvanism如何渗透到文化意识中，促使人们讨论科学家的道德责任。 总之，galvanism代表了科学史上的一个关键时刻，标志着电与生物之间的交汇。它的发现为研究和创新开辟了新的途径，导致医学和我们对人体理解的重大进展。随着我们继续探索生物电的复杂性，galvanism的遗产提醒我们科学、伦理与生命本质之间深刻的联系。理解galvanism不仅丰富了我们对科学历史的知识，也鼓励我们反思当代社会中技术进步的意义。