roentgen radiation

简明释义

x 射线辐射

英英释义

Roentgen radiation refers to a type of electromagnetic radiation that is produced by the deceleration of charged particles, typically electrons, when they are deflected by atomic nuclei.

伦琴辐射是指由带电粒子(通常是电子)在被原子核偏转时减速产生的一种电磁辐射。

It is commonly known as X-rays and is used extensively in medical imaging and industrial applications.

它通常被称为X射线,广泛应用于医学成像和工业领域。

例句

1.Patients undergoing treatment should be informed about the risks of roentgen radiation 伦琴辐射 exposure.

接受治疗的患者应该被告知关于roentgen radiation 伦琴辐射暴露的风险。

2.In the lab, researchers study the effects of roentgen radiation 伦琴辐射 on living tissues.

在实验室,研究人员研究roentgen radiation 伦琴辐射对活体组织的影响。

3.The technician calibrated the machine to ensure accurate roentgen radiation 伦琴辐射 output.

技术员校准了机器,以确保准确的roentgen radiation 伦琴辐射输出。

4.The doctor explained that the roentgen radiation 伦琴辐射 used in X-rays can help diagnose fractures.

医生解释说,X光中使用的roentgen radiation 伦琴辐射可以帮助诊断骨折。

5.Safety precautions are necessary when working with roentgen radiation 伦琴辐射 to minimize exposure.

在处理roentgen radiation 伦琴辐射时,必须采取安全预防措施以最小化暴露。

作文

The discovery of roentgen radiation has significantly transformed the field of medicine and our understanding of physics. Roentgen radiation, also known as X-rays, was first discovered by Wilhelm Conrad Röntgen in 1895. This groundbreaking discovery allowed for the visualization of the internal structures of the human body without the need for invasive procedures. The ability to see bones, organs, and other tissues has revolutionized diagnostics, enabling doctors to diagnose conditions more accurately and efficiently.Before the advent of roentgen radiation, medical practitioners relied heavily on physical examinations and exploratory surgeries to understand a patient’s health issues. These methods were not only time-consuming but also posed various risks to patients. With the introduction of roentgen radiation, healthcare providers could obtain immediate images of the affected areas, leading to quicker diagnoses and treatment plans. For instance, fractures can be identified swiftly, allowing for prompt intervention that is crucial for healing.Moreover, roentgen radiation has applications beyond just bone imaging. It is used in detecting tumors, monitoring the progression of diseases, and guiding certain surgical procedures. The versatility of roentgen radiation makes it an indispensable tool in modern medicine. However, the use of this technology does come with its challenges. Prolonged exposure to roentgen radiation can pose health risks, including an increased chance of developing cancer. Therefore, it is essential for medical professionals to follow safety protocols to minimize exposure while still providing necessary care.In addition to its medical applications, roentgen radiation has also been utilized in various industrial fields. For example, it is employed in non-destructive testing to inspect the integrity of materials and structures. This application is crucial in industries such as aerospace and construction, where safety is paramount. By using roentgen radiation, engineers can detect flaws and ensure that the materials used in critical components meet safety standards.Furthermore, the study of roentgen radiation has paved the way for advancements in other imaging technologies. Techniques such as computed tomography (CT) scans and fluoroscopy are built upon the principles established by Röntgen’s original discovery. These innovations have further enhanced our capability to visualize the human body in detail, leading to improved healthcare outcomes.In conclusion, the discovery of roentgen radiation has had a profound impact on both medicine and industry. It has enabled healthcare providers to diagnose and treat conditions more effectively, while also ensuring the safety and integrity of various structures in industrial applications. As technology continues to evolve, the principles behind roentgen radiation will undoubtedly lead to even more advancements, enhancing our understanding of the world around us. It is essential for both medical professionals and the general public to recognize the significance of roentgen radiation and to advocate for its responsible use in order to maximize its benefits while minimizing potential risks.

罗特根辐射的发现极大地改变了医学领域和我们对物理学的理解。罗特根辐射,也称为X射线,首次由威廉·康拉德·罗特根于1895年发现。这一突破性发现使得在不需要侵入性程序的情况下可视化人体内部结构成为可能。查看骨骼、器官和其他组织的能力彻底革新了诊断,使医生能够更准确、高效地诊断病情。在罗特根辐射出现之前,医疗从业者主要依赖身体检查和探索性手术来了解患者的健康问题。这些方法不仅耗时,而且对患者存在各种风险。随着罗特根辐射的引入,医疗提供者能够立即获取受影响区域的图像,从而快速诊断和制定治疗方案。例如,骨折可以迅速识别,从而进行及时干预,这对愈合至关重要。此外,罗特根辐射在肿瘤检测、疾病进展监测和指导某些外科手术方面也有应用。这种技术的多功能性使其成为现代医学中不可或缺的工具。然而,使用这种技术确实带来了挑战。长期暴露于罗特根辐射可能会带来健康风险,包括增加癌症的机会。因此,医疗专业人员必须遵循安全协议,以最小化暴露,同时仍能提供必要的护理。除了在医学上的应用,罗特根辐射还被用于各种工业领域。例如,它被用于无损检测,以检查材料和结构的完整性。这一应用在航空航天和建筑等行业至关重要,因为安全是重中之重。通过使用罗特根辐射,工程师可以检测缺陷,确保用于关键组件的材料符合安全标准。此外,对罗特根辐射的研究为其他成像技术的进步铺平了道路。计算机断层扫描(CT)和荧光透视等技术建立在罗特根最初发现的原理之上。这些创新进一步增强了我们详细可视化人体的能力,从而改善了医疗结果。总之,罗特根辐射的发现对医学和工业产生了深远的影响。它使医疗提供者能够更有效地诊断和治疗疾病,同时确保工业应用中各种结构的安全和完整。随着技术的不断发展,罗特根辐射背后的原理无疑将导致更多的进步,增强我们对周围世界的理解。医疗专业人员和公众都应认识到罗特根辐射的重要性,并倡导其负责任的使用,以最大化其益处,同时最小化潜在风险。