thermology
简明释义
n. 热学
英英释义
Thermology is the scientific study of heat and temperature, particularly in relation to their effects on living organisms and materials. | 热学是对热和温度的科学研究,特别是它们对生物体和材料的影响。 |
单词用法
热学研究 | |
热学技术 | |
应用热学 | |
热学原理 |
同义词
| 热度测量学 | 热度测量学在各种科学实验中至关重要。 | ||
| 温度科学 | 温度科学帮助我们理解气候变化。 |
反义词
| 低温学 | 低温学对保存生物样本至关重要。 | ||
| 低体温 | Hypothermia can occur when the body loses heat faster than it can produce it. | 低体温可能发生在身体散热速度快于产生热量时。 |
例句
1.This paper discussed that influence of temperature on the chromaticity and color difference from thermology.
主要从热学角度分析和研究温度对于颜色色度及色差的影响。
2.The basic thermology theory of optimized model is stated, its construction process when used in the model of walking beam furnace is analyzed with mathematics method.
文章阐述了优化加热模型的基本传热学原理,并用数学的方法剖析了此模型的建立过程以及应用到步进式加热炉中数学模型的建立过程。
3.Diamond films have aroused many scientists interests for its remarkable properties in mechanics, thermology, optics, electrics and acoustics.
金刚石具有优异的力学、热学、光学、电学和声学性能,引起了各界科学工作者的广泛关注。
4.In this paper, the crystalline morphology, thermology, rheology and mechanical properties of clarified PP are investigated by PLM, DSC, Rheometer and stretch tester.
采用偏光显微镜(PLM)、差示扫描量热仪(dsc)、毛细管流变仪和拉伸试验机对透明聚丙烯(PP)的结晶形态、热学、流变性、力学性能进行了研究。
5.The structure design of airborne active phased-array antenna involves mechanics, thermology, maintenance, cabling, static balance etc, and thus should be considered fully.
机载有源相控阵天线的结构设计涉及到力学、热学、维修、走线、静平衡等方面,需要进行全面细致的考虑。
6.In the field of thermology, diamond's heat-durability and heat conductivity were enhanced.
在热学方面,使金刚石的耐热性和导热性均有增加;
7.The structure design of airborne active phased-array antenna involves mechanics, thermology, maintenance, cabling, static balance etc, and thus should be considered fully.
机载有源相控阵天线的结构设计涉及到力学、热学、维修、走线、静平衡等方面,需要进行全面细致的考虑。
8.Diamond is one kind of limited functional material in the region of mechanics, thermology, optics, chemic and electronics.
众所周知金刚石是一种在机械、热学、光学、化学、电子学等方面具有极限性能的特殊材料。
9.Understanding thermology is crucial for engineers working with thermal systems.
理解热学对从事热系统工作的工程师至关重要。
10.The principles of thermology are applied in designing energy-efficient buildings.
在设计节能建筑时应用了热学的原理。
11.In medicine, thermology can help diagnose conditions by measuring body temperature variations.
在医学中,热学可以通过测量体温变化来帮助诊断疾病。
12.The field of thermology focuses on the study of heat and temperature in various materials.
领域的热学专注于研究各种材料中的热量和温度。
13.Researchers in thermology are developing new thermal imaging technologies for better diagnostics.
在热学领域的研究人员正在开发新的热成像技术,以便更好地进行诊断。
作文
Thermology, the study of heat and its effects on living organisms and materials, plays a crucial role in various scientific fields. This branch of science is particularly significant in understanding how temperature variations affect biological processes, material properties, and even environmental conditions. In recent years, advancements in technology have allowed for more precise measurements and analyses in thermology (热学), leading to innovations in medicine, engineering, and environmental science. One of the most notable applications of thermology (热学) is in the medical field, where it is used to diagnose and monitor various health conditions. For example, infrared thermography is a non-invasive imaging technique that detects heat patterns and blood flow in tissues. This method has proven invaluable for identifying issues such as inflammation, circulatory problems, and even tumors. By analyzing the thermal signatures of different body regions, healthcare professionals can gain insights into a patient's health status, allowing for timely interventions and improved treatment outcomes. In engineering, thermology (热学) is essential for designing systems that manage heat transfer effectively. Whether it’s in the development of energy-efficient buildings, automotive engines, or electronic devices, understanding the principles of heat flow and thermal insulation is critical. Engineers utilize thermology (热学) to optimize designs, ensuring that systems operate efficiently while minimizing energy loss. For instance, in the construction industry, architects and builders apply thermological principles to enhance insulation materials, thereby reducing heating and cooling costs for homeowners. Moreover, thermology (热学) contributes significantly to environmental science. Understanding how heat interacts with the atmosphere, oceans, and land surfaces is vital for predicting climate change and its impacts. Researchers use thermal data to model weather patterns, assess natural disasters like wildfires, and monitor the health of ecosystems. By studying temperature variations in different environments, scientists can develop strategies to mitigate the effects of global warming and promote sustainability. The importance of thermology (热学) extends beyond these applications. It also fosters interdisciplinary collaboration among scientists, engineers, and medical professionals. For instance, researchers studying the effects of temperature on microbial activity can provide valuable insights for both environmental management and public health. Similarly, engineers working on thermal management solutions can benefit from medical research on body heat regulation. This convergence of knowledge enhances our overall understanding of heat-related phenomena and drives innovation across various sectors. In conclusion, thermology (热学) is a multifaceted field that significantly impacts our understanding of heat and its effects on life and materials. Its applications in medicine, engineering, and environmental science highlight its relevance in addressing contemporary challenges. As technology continues to advance, the role of thermology (热学) will undoubtedly expand, leading to new discoveries and improvements in various domains. Embracing this field of study not only enriches our scientific knowledge but also empowers us to make informed decisions for a healthier and more sustainable future.
热学,即研究热及其对生物和材料影响的学科,在各个科学领域中发挥着至关重要的作用。这个科学分支特别重要,因为它帮助我们理解温度变化如何影响生物过程、材料特性,甚至环境条件。近年来,技术的进步使得在热学(thermology)领域的测量和分析更加精确,从而推动了医学、工程和环境科学的创新。热学(thermology)最显著的应用之一是在医疗领域,它用于诊断和监测各种健康状况。例如,红外热成像是一种非侵入式成像技术,可以检测组织中的热模式和血流。这种方法对于识别炎症、循环问题甚至肿瘤等问题具有重要价值。通过分析不同身体区域的热签名,医疗专业人员能够获得患者健康状态的洞察,从而进行及时干预并改善治疗效果。在工程领域,热学(thermology)对设计有效管理热传递的系统至关重要。无论是在开发节能建筑、汽车发动机还是电子设备方面,理解热流和热绝缘的原理都是关键。工程师利用热学(thermology)来优化设计,确保系统高效运行,同时最小化能源损耗。例如,在建筑行业,建筑师和施工人员应用热学原理来增强绝缘材料,从而降低房主的取暖和制冷成本。此外,热学(thermology)对环境科学也有重要贡献。理解热与大气、海洋和陆地表面的相互作用对于预测气候变化及其影响至关重要。研究人员使用热数据来建模天气模式、评估自然灾害如野火,并监测生态系统的健康。通过研究不同环境中的温度变化,科学家可以制定减缓全球变暖影响和促进可持续发展的策略。热学(thermology)的重要性不仅限于这些应用。它还促进了科学家、工程师和医疗专业人士之间的跨学科合作。例如,研究温度对微生物活性的影响的研究人员可以为环境管理和公共卫生提供宝贵的见解。同样,致力于热管理解决方案的工程师可以从关于人体热调节的医学研究中受益。这种知识的融合增强了我们对与热相关现象的整体理解,并推动了各个行业的创新。总之,热学(thermology)是一个多方面的领域,对我们理解热及其对生命和材料的影响具有重要意义。它在医学、工程和环境科学中的应用突显了其在应对当代挑战中的相关性。随着技术的不断进步,热学(thermology)的角色无疑会扩大,带来新的发现和各个领域的改进。拥抱这一研究领域不仅丰富了我们的科学知识,还使我们能够为更健康和可持续的未来做出明智的决策。
