In physics, temperature is a physical property of a system that underlies the common notions of hot and cold; something that feels hotter generally has the greater temperature. Temperature is one of the principal parameters of thermodynamics. On the macroscopic scale, temperature is the unique physical property that determines the direction of heat flow between two objects placed in thermal contact. If no heat flow occurs, the two objects have the same temperature; otherwise heat flows from the hotter object to the colder object. This is the content of the zeroth law of thermodynamics. On the microscopic scale, temperature can be defined as the average energy in each degree of freedom in the particles in a system- because temperature is a statistical property, a system must contain a few particles for the question as to its temperature to make any sense. For a solid, this energy is found in the vibrations of its atoms about their equilibrium positions. In an ideal monatomic gas, energy is found in the translational motions of the particles; with molecular gases, vibrational and rotational motions also provide thermodynamic degrees of freedom.
Temperature is measured with thermometers that may be calibrated to a variety of temperature scales. In most of the world (except for Myanmar, Liberia and the United States), the Celsius scale is used for most temperature measuring purposes. The entire scientific world (these countries included) measures temperature using the Celsius scale and thermodynamic temperature using the kelvin scale, which is just the Celsius scale shifted downwards so that 0 K[1]= −273.15 °C, or absolute zero. Many engineering fields in the U.S., especially high-tech ones, also use the kelvin and degrees Celsius scales. Other engineering fields in the U.S. also rely upon the Rankine scale (a shifted Fahrenheit scale) when working in thermodynamic-related disciplines such as combustion.
Intuitively, temperature is the measurement of how hot or cold something is, although the most immediate way in which we can measure this, by feeling it, is unreliable, resulting in the phenomenon of felt air temperature, which can differ at varying degrees from actual temperature. On the molecular level, temperature is the result of the motion of particles which make up a substance. Temperature increases as the energy of this motion increases. The motion may be the translational motion of the particle, or the internal energy of the particle due to molecular vibration or the excitation of an electron energy level. Although very specialized laboratory equipment is required to directly detect the translational thermal motions, thermal collisions by atoms or molecules with small particles suspended in a fluid produces Brownian motion that can be seen with an ordinary microscope. The thermal motions of atoms are very fast and temperatures close to absolute zero are required to directly observe them. For instance, when scientists at the NIST achieved a record-setting cold temperature of 700 nK (1 nK = 10−9 K) in 1994, they used optical lattice laser equipment to adiabatically cool caesium atoms. They then turned off the entrapment lasers and directly measured atom velocities of 7 mm per second in order to calculate their temperature.
Molecules, such as O2, have more degrees of freedom than single atoms: they can have rotational and vibrational motions as well as translational motion. An increase in temperature will cause the average translational energy to increase. It will also cause the energy associated with vibrational and rotational modes to increase. Thus a diatomic gas, with extra degrees of freedom rotation and vibration, will require a higher energy input to change the temperature by a certain amount, i.e. it will have a higher heat capacity than a monatomic gas.
The process of cooling involves removing energy from a system. When there is no more energy able to be removed, the system is said to be at absolute zero, which is the point on the thermodynamic (absolute) temperature scale where all kinetic motion in the particles comprising matter ceases and they are at complete rest in the “classic” (non-quantum mechanical) sense. By definition, absolute zero is a temperature of precisely 0 kelvins (−273.15 °C or −459.68 °F).
The formal properties of temperature follow from its mathematical definition (see below for the zeroth law definition and the second law definition) and are studied in thermodynamics and statistical mechanics.
Contrary to other thermodynamic quantities such as entropy and heat, whose microscopic definitions are valid even far away from thermodynamic equilibrium, temperature being an average energy per particle can only be defined at thermodynamic equilibrium, or at least local thermodynamic equilibrium (see below).
As a system receives heat, its temperature rises; similarly, a loss of heat from the system tends to decrease its temperature (at the--uncommon--exception of negative temperature; see below).
When two systems are at the same temperature, no heat transfer occurs between them. When a temperature difference does exist, heat will tend to move from the higher-temperature system to the lower-temperature system, until they are at thermal equilibrium. This heat transfer may occur via conduction, convection or radiation or combinations of them (see heat for additional discussion of the various mechanisms of heat transfer) and some ions may vary.
Temperature is also related to the amount of internal energy and enthalpy of a system: the higher the temperature of a system, the higher its internal energy and enthalpy.
Temperature is an intensive property of a system, meaning that it does not depend on the system size, the amount or type of material in the system, the same as for the pressure and density. By contrast, mass, volume, and entropy are extensive properties, and depend on the amount of material in the system.
Temperature plays an important role in almost all fields of science, including physics, geology, chemistry, and biology.
Many physical properties of materials including the phase (solid, liquid, gaseous or plasma), density, solubility, vapor pressure, and electrical conductivity depend on the temperature. Temperature also plays an important role in determining the rate and extent to which chemical reactions occur. This is one reason why the human body has several elaborate mechanisms for maintaining the temperature at 37 °C, since temperatures only a few degrees higher can result in harmful reactions with serious consequences. Temperature also controls the type and quantity of thermal radiation emitted from a surface. One application of this effect is the incandescent light bulb, in which a tungsten filament is electrically heated to a temperature at which significant quantities of visible light are emitted.
Temperature-dependence of the speed of sound in air c, density of air ρ and acoustic impedance Z vs. temperature °C
求一篇关于温度检测及上下限报警的论文 最好是翻译成英文的。
求一篇关于温度检测及上下限报警的论文 最好是翻译成英文的。 我正在做单片机温度检测及上下限报警的毕业设计,现在缺一篇这样的英文论文我查了很多资料都没有各位大侠谁有的话给小弟我发一份吧我的油箱是chrisstry@163.com... 我正在做 单片机温度检测及上下限报警的毕业设计,现在缺一篇这样的英文论文 我查了很多...
帮忙翻译一篇5000字的英文文献
我朋友的毕业论文需要翻译一篇5000字的英文文献,文献已经准备好了,但是她没空,而我英语实在不行,用翻译软件翻译出来的东西我居然看不懂意思,请各位帮帮忙 明天就要交了。翻译质量好的加送20QB。有帮忙的朋友QQ联系。 展开 我来答 1个回答 #热议# 什么样的人容易遇上渣男?匿名用户 2014-02-18 展开全部...
什么是毕业论文中的英文文献的原文及译文
一般要求都是在5000单词以上,我做毕业 论文的时候对英文文献的题目要求是只要是跟论文题目的所涉及的内容相关就可以。这些东西可以在学校图书馆里或者图书馆网络资料库里找到,就是翻译比较费力,走运的话可以找到带译文的稿子。
毕业论文英文摘要,我英语很烂,不会翻译啊!求好心让你帮忙,拜托拜托啊...
algae it into a 500 ml conical flask, after using the filtered water and seal.Each algal set three parallel samples and set up the three sea blank sample.In temperature 20 ℃, 5000 Lux light intensity, light cycle: L D = 12: h under cultivation, respectively in five days, ...
毕业论文翻译一定要用英文吗?
毕业论文外文翻译:将外文参考文献翻译成中文版本。翻译要求:1、选定外文文献后先给指导老师看,得到老师的确认通过后方可翻译。2、选择外文翻译时一定选择外国作者写的文章,可从学校中知网或者外文数据库下载。3、外文翻译字数要求3000字以上,从外文文章起始处开始翻译,不允许从文章中间部分开始翻译,翻译...
毕业论文的摘要要用英文写,高手给翻译下
II: An analysis for the development status quo of the Internet bank of China Merchants Bank.III: An analysis for some problems of the Internet bank of China Merchants Bank.IV: Some suggestions for the future development of the Internet bank of China Merchants Bank.简释:第一、第...
毕业论文的英文摘要,我的英文不好,希望有人可以帮忙翻译一下,谢谢!
to adjust country industries, to raise the income of peasants and to improve their well-being. It is helpful for urban-rural integration and the introduction and spread of the idea of ecotourism. It also helps to keep working the function of ecological service of countryside and to...
高分悬赏!毕业论文英文翻译求助
高分悬赏!毕业论文英文翻译求助 50 过两天就要交论文,摘要等内容需要英文翻译,本人水平有限,软件翻译的错误很多,因为时间紧迫,恳求英语高手帮帮忙(请不要用软件或在线翻译),在下感激不尽!翻译的差不多就行了,... 过两天就要交论文,摘要等内容需要英文翻译,本人水平有限,软件翻译的错误很多,因为时间紧迫,恳求...
毕业论文摘要求英文翻译,请英语高手帮帮忙,万分感谢
Abstract: China is in from traditional society to modern society, from closed society to open society, from agricultural society to industrial society in transition. The incompleteness of the women's liberation movement, the influence of the remaining feudal thought, the development of ...
帮忙找篇毕业设计的英文文献,可以不翻译成中文,但要求译成中文后不...
帮忙找篇毕业设计的英文文献,可以不翻译成中文,但要求译成中文后不少于3000字 毕业设计的题目是:企业ERP实施中库存管理的设计与实现所用工具:ASP和SQLServer所以英文文献应当至少和ERP、ASP、SQLServer其中的一个相关只要英文即可,我可以自己进行翻译工作。当... 毕业设计的题目是:企业ERP实施中库存管理的设计与实现...
