resonance irradiation
简明释义
共振辐照
英英释义
例句
1.In medical applications, resonance irradiation 共振辐射 is used to target tumors with precision.
在医学应用中,resonance irradiation 共振辐射 被用于精确定位肿瘤。
2.The researchers discovered that resonance irradiation 共振辐射 could enhance the efficiency of solar panels.
研究人员发现,resonance irradiation 共振辐射 可以提高太阳能电池板的效率。
3.Understanding resonance irradiation 共振辐射 can lead to breakthroughs in quantum computing.
理解 resonance irradiation 共振辐射 可以带来量子计算的突破。
4.The concept of resonance irradiation 共振辐射 is crucial in developing advanced communication technologies.
概念 resonance irradiation 共振辐射 在开发先进通信技术中至关重要。
5.The team utilized resonance irradiation 共振辐射 to improve the quality of materials in their experiments.
团队利用 resonance irradiation 共振辐射 来提高实验中材料的质量。
作文
In the realm of physics and engineering, the concept of resonance irradiation plays a crucial role in understanding how energy interacts with matter. This phenomenon can be observed in various fields, including medical imaging, telecommunications, and materials science. To grasp the significance of resonance irradiation and its applications, it is essential to break down the term and explore its implications.First, let's define what we mean by resonance irradiation. Resonance refers to the tendency of a system to oscillate at maximum amplitude at certain frequencies. When an external force is applied at these frequencies, the system absorbs energy efficiently. Irradiation, on the other hand, involves the emission or transmission of energy in the form of waves or particles. Therefore, resonance irradiation can be understood as the process where energy is absorbed by a material when it is subjected to electromagnetic waves at specific resonant frequencies.One of the most prominent applications of resonance irradiation is in magnetic resonance imaging (MRI). MRI is a non-invasive imaging technique that uses strong magnetic fields and radio waves to generate detailed images of the organs and tissues inside the body. The principle behind MRI relies on the fact that certain nuclei in the body, such as hydrogen atoms, resonate at specific frequencies when exposed to a magnetic field. By applying resonance irradiation, the MRI machine excites these hydrogen nuclei, causing them to emit signals that are then captured to create images. This application has revolutionized the field of medical diagnostics, allowing for early detection of diseases without the need for invasive procedures.In telecommunications, resonance irradiation is essential for the functioning of various devices, including antennas and transmitters. Antennas are designed to resonate at particular frequencies, enabling them to efficiently transmit and receive electromagnetic waves. When an antenna is irradiated with signals at its resonant frequency, it can convert electrical energy into electromagnetic waves and vice versa. This principle is fundamental to wireless communication technologies, including radio, television, and mobile phones, facilitating the transfer of information over vast distances.Materials science also benefits from the understanding of resonance irradiation. Researchers study how different materials respond to resonant frequencies to develop new materials with tailored properties. For instance, certain materials may exhibit enhanced absorption or emission of energy at specific frequencies, making them suitable for applications such as sensors, solar cells, or photonic devices. By harnessing the principles of resonance irradiation, scientists can innovate and create advanced materials that meet the demands of modern technology.In conclusion, the concept of resonance irradiation is integral to various scientific and engineering disciplines. Its applications in medical imaging, telecommunications, and materials science highlight the importance of understanding how energy interacts with matter at resonant frequencies. As technology continues to advance, the exploration of resonance irradiation will undoubtedly lead to further innovations and improvements in numerous fields, enhancing our ability to diagnose, communicate, and create new materials for the future.
在物理和工程领域,共振辐射的概念在理解能量与物质相互作用方面发挥着关键作用。这种现象可以在多个领域中观察到,包括医学成像、通信和材料科学。要掌握共振辐射的重要性及其应用,必须对这个术语进行拆解并探讨其含义。首先,让我们定义一下共振辐射的含义。共振是指系统在某些频率下以最大幅度振荡的倾向。当外部力量以这些频率施加时,系统会有效地吸收能量。而辐射则涉及以波或粒子的形式发射或传输能量。因此,共振辐射可以理解为当材料受到特定共振频率的电磁波照射时,能量被材料吸收的过程。共振辐射最显著的应用之一是在磁共振成像(MRI)中。MRI是一种非侵入性的成像技术,利用强磁场和无线电波生成体内器官和组织的详细图像。MRI背后的原理依赖于身体中某些核(如氢原子)在暴露于磁场时以特定频率共振。通过施加共振辐射,MRI机器激发这些氢核,导致它们发出信号,然后捕获这些信号以生成图像。这一应用彻底改变了医学诊断领域,使得早期发现疾病成为可能,而无需进行侵入性操作。在通信领域,共振辐射对于各种设备的功能至关重要,包括天线和发射器。天线被设计为在特定频率上共振,使其能够有效地发送和接收电磁波。当天线受到其共振频率的信号照射时,它能够将电能转换为电磁波,反之亦然。这一原理是无线通信技术(包括广播、电视和手机)的基础,促进了信息在广阔距离上的传输。材料科学也受益于对共振辐射的理解。研究人员研究不同材料如何响应共振频率,以开发具有特定性能的新材料。例如,某些材料可能在特定频率下表现出增强的能量吸收或发射,使其适合用于传感器、太阳能电池或光子设备等应用。通过利用共振辐射的原理,科学家们可以创新并创造出满足现代技术需求的先进材料。总之,共振辐射的概念是多个科学和工程学科不可或缺的一部分。它在医学成像、通信和材料科学中的应用突显了理解能量如何在共振频率下与物质相互作用的重要性。随着技术的不断进步,对共振辐射的探索无疑将引领更多的创新和改进,提升我们在未来诊断、通信和创造新材料的能力。
相关单词
