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温度
,無編輯摘要
温度是物体内分子间平均动能的一种表现形式。值得注意的是,少数几个分子甚至是一个分子构成的系统,由于缺乏统计的数量要求,是没有温度的意义的。
== 温度计量 ==
使用当代科学[[温度计]]和温度标记法进行温度计量可以追溯到18世纪早期,[[加布里埃尔·华伦海特]]使用了[[奥勒·罗默]]发明的温度计(转换成了[[水银]])和标记方式。[[华氏温标]]仍然在[[美国]]日常生活中使用。
==== 转换 ====
下面的表格展示了各温标如何转换为摄氏温标。
{|class=wikitable
| 10,608.3 nm<br />(长波[[红外线]])
|-
| style="background:#d9d9d3"|水的[[沸点]]{{ref label|water|A|A}}
| 373.1339 K
| 99.9839 °C
| 7,766.03 nm<br />(中波红外线)
|-
| style="background:#d9d9d3" |[[电灯泡]]{{ref label|incadescent|B|B}}
| 2500 K
| ≈2,200 °C
| 1,160 nm<br />(接近红外线){{ref label|tungsten|C|C}}
|-
| style="background:#d9d9d3" |[[乙炔|氧炔焰]]
| 3600 K
| ≈3,300 °C
| 可见光
|-
| style="background:#d9d9d3"|[[太阳]]可见表 面{{ref label|sun面sun|D|D}}<ref>于2002年测量,有±3凯尔文的误差。[http://www.kis.uni-freiburg.de/~hw/astroandsolartitles.html 1989年的测量结果]为5,777.0±2.5 K。参考资料:[http://theory.physics.helsinki.fi/~sol_phys/Sol0601.pdf ''Overview of the Sun''] (Chapter 1 lecture notes on Solar Physics by Division of Theoretical Physics, Dept. of Physical Sciences, University of Helsinki).</ref>
| 5,778 K
| 5,505 °C
| 501.5 nm<br />([[颜色|绿-蓝光]])
|-
| style="background:#d9d9d3" |[[闪电]]{{ref label|celsiuskelvin|E|E}}
| 28 kK
| 28,000 °C
| 100 nm<br />(远[[紫外线]]光)
|-
| style="background:#d9d9d3"|[[太阳#核心|太阳核心]]{{ref label|celsiuskelvin|E|E}}
| 16 MK
| 1600万 °C
| 0.18 nm<br>([[X射线]])
|-
| style="background:#d9d9d3"|[[核武器]]<br />(最高温度 ){{ref label|celsiuskelvin)celsiuskelvin|E|E}}<ref>350 MK的数值是指氢弹的最高燃烧温度。原子弹的最高温度大概在50到100 MK。参考资料:''Nuclear Weapons Frequently Asked Questions, 3.2.5 Matter At High Temperatures.'' [http://nuclearweaponarchive.org/Nwfaq/Nfaq3.html#nfaq3.2 Link to relevant Web page.] All referenced data was compiled from publicly available sources.</ref>
| 350 MK
| 3.5亿 °C
| 8.3×10<sup>−3</sup> nm<br />([[伽马射线]])
|-
| style="background:#d9d9d3"|桑迪亚国家实验室<br />[[Z脉冲功率设施|Z machine]]{{ref label|celsiuskelvin|E|E}}<ref>In fact, the iron and manganese ions in the plasma averaged 3.58±0.41 GK (309±35 keV) for 3 ns (ns 112 through 115). [http://prl.aps.org/abstract/PRL/v96/i7/e075003 ''Ion Viscous Heating in a Magnetohydrodynamically Unstable Z Pinch at Over {{val|2|e=9}} Kelvin''], M. G. Haines ''et al.'', Physical Review Letters '''96''' (2006) 075003. [http://sandia.gov/news-center/news-releases/2006/physics-astron/hottest-z-output.html Link to Sandia's news release.]</ref>
| 2 GK
| 20亿 °C
| 1.4×10<sup>−3</sup> nm<br />(伽马射线){{ref label|zmachine|F|F}}
|-
| style="background:#d9d9d3"|[[硅燃烧过程|大质量恒星最后一天]]的核心{{ref label|celsiuskelvin|E|E}}<ref>大质量(>8–11倍太阳质量)恒星核心温度离开[[赫罗图]]上主序带进入[[硅燃烧过程|燃烧硅-28]]的[[氦核作用|α过程]](持续1天),依照下列顺序演变为重核元素:硫–32 →氩–36 →钙–40 →钛–44 →铬–48 →铁–52 →镍–56。在完成该序带后数分钟内,该恒星爆炸成为[[II型超新星]]。参考资料:''Stellar Evolution: The Life and Death of Our Luminous Neighbors'' (by Arthur Holland and Mark Williams of the University of Michigan). [http://umich.edu/~gs265/star.htm Link to Web site].更多资料可以参见[http://schools.qps.org/hermanga/images/Astronomy/chapter_21___stellar_explosions.htm 这里] {{webarchive|url=https://web.archive.org/web/20130411183756/http://schools.qps.org/hermanga/images/Astronomy/chapter_21___stellar_explosions.htm |date=2013-04-11 }},以及[http://cosserv3.fau.edu/~cis/AST2002/Lectures/C13/Trans/Trans.html 这里] {{webarchive|url=https://web.archive.org/web/20110814005149/http://cosserv3.fau.edu/~cis/AST2002/Lectures/C13/Trans/Trans.html |date=2011-08-14 }},另外还有来自NASA的[http://nasa.gov/worldbook/star_worldbook.html 有关星体的淮确论述]。</ref>
| 3 GK
| 30亿 °C
| 1×10<sup>−3</sup> nm<br />(伽马射线)
|-
| style="background:#d9d9d3"|融合中的双[[中子星]]系统{{ref label|celsiuskelvin|E|E}}<ref>[http://arxiv.org/pdf/astro-ph/0507099.pdf ''Torus Formation in Neutron Star Mergers and Well-Localized Short Gamma-Ray Bursts''], R. Oechslin ''et al''. of [http://www.mpa-garching.mpg.de/ Max Planck Institute for Astrophysics.], arXiv:astro-ph/0507099 v2, 22 Feb. 2006. [http://www.mpa-garching.mpg.de/mpa/research/current_research/hl2005-10/hl2005-10-en.html An html summary].</ref>
| 350 GK
| 3500亿 °C
| 8×10<sup>−6</sup> nm<br />(伽马射线)
|-
| style="background:#d9d9d3"|{{link-en|相对论重离子对撞机|Relativistic Heavy Ion Collider}}{{ref label|celciuskelvin|E|E}}<ref>Results of research by Stefan Bathe using the [http://www.phenix.bnl.gov/ PHENIX] detector on the [http://www.bnl.gov/rhic/ Relativistic Heavy Ion Collider] at [http://www.bnl.gov/world/ Brookhaven National Laboratory] in Upton, New York, U.S.A. Bathe has studied gold-gold, deuteron-gold, and proton-proton collisions to test the theory of quantum chromodynamics, the theory of the strong force that holds atomic nuclei together. [http://bnl.gov/bnlweb/pubaf/pr/PR_display.asp?prID=06-56 Link to news release.]</ref>
| 1 TK
| 1万亿 °C
| 3×10<sup>−6</sup> nm<br />(伽马射线)
|-
| style="background:#d9d9d3" |[[欧洲核子研究组织|CERN]]质子-核碰撞{{ref label|celsiuskelvin|E|E}}<ref>[http://public.web.cern.ch/public/Content/Chapters/AboutCERN/HowStudyPrtcles/HowSeePrtcles/HowSeePrtcles-en.html How do physicists study particles?] by [http://public.web.cern.ch/public/Welcome.html CERN].</ref>
| 10 TK
| 10万亿 °C
| 3×10<sup>−7</sup> nm<br />(伽马射线)
|-
| style="background:#d9d9d3"|宇宙在[[大爆炸]]之后[[普朗克时间|5.391×10<sup>−44</sup> s]]{{ref label|celsiuskelvin|E|E}}
| [[普朗克温度|1.417×10<sup>32</sup> K]]
| 1.417×10<sup>32</sup> °C
==温度测量==
由于温度会对体积、密度、声速、阻抗等物理量产生影响,因此可以通过测量这些物理量数值的变化来测量温度。目前温度测量的方法有数十种,按照测量原理可以分为以下几类:
*膨胀测温法,是采用几何量(体积、长度)作为温度的标志。如[[水银温度计]]的测量范围大约是-30~300°C,[[酒精温度计]]的测量范围大约是-115~110℃,
== 外部连结 ==
[[Category: 温度]][[Category:基本物理概念]][[Category:物理量]][[Category:热力学]][[Category:传热]][[Category:态函数]][[Category:日语借词335 熱學]]