Homologous temperature: Difference between revisions

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Homologous temperature expresses the thermodynamic temperature of a material as a fraction of the thermodynamic temperature of its melting point (i.e. using the Kelvin scale):

$T_{H}={\frac {T({\text{K}})}{T_{mp}({\text{K}})}}$

For example, the homologous temperature of lead at room temperature (25 °C) is approximately 0.50 (T_H = T/T_mp = 298 K/601 K = 0.50).

Significance of the homologous temperature

The homologous temperature of a substance is useful for determining the rate of steady state creep (diffusion-dependent deformation). A higher homologous temperature results in an exponentially higher rate of diffusion dependent deformation.^[1]

Additionally, for a given fixed homologous temperature, two materials with different melting points would have similar diffusion-dependent deformation behaviour. For example, solder (T_mp = 456 K) at 115 °C would have comparable mechanical properties to copper (T_mp = 1358 K) at 881 °C, because they would both be at 0.85T_mp despite being at different absolute temperatures.

In electronics applications, where circuits typically operate over a −55 °C to +125 °C range, eutectic tin-lead (Sn63) solder is working at 0.48T_mp to 0.87T_mp. The upper temperature is high relative to the melting point; from this we can deduce that solder will have limited mechanical strength (as a bulk material) and significant creep under stress. This is borne out by its comparatively low values for tensile strength, shear strength and modulus of elasticity. Copper, on the other hand, has a much higher melting point, so foils are working at only 0.16T_mp to 0.29T_mp and their properties are little affected by temperature.

References

^ "DoITPoMS - TLP Library Creep Deformation of Metals - Effects of stress and temperature". www.doitpoms.ac.uk. Archived from the original on 2019-06-07. Retrieved 2018-11-12.

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[1] "DoITPoMS - TLP Library Creep Deformation of Metals - Effects of stress and temperature". www.doitpoms.ac.uk. Archived from the original on 2019-06-07. Retrieved 2018-11-12.

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+{{Short description|Fraction of the melting point}}
-'''Homologous temperature''' expresses the [[temperature]] of a material as a fraction of its [[melting point]] temperature using the [[Kelvin scale]].  For example, the homologous temperature of lead at room temperature is approximately 0.50 (T<sub>H</sub> = T/T<sub>mp</sub> = 298K/601K = 0.50).
+'''Homologous temperature''' expresses the [[thermodynamic temperature]] of a material as a fraction of the thermodynamic temperature of its [[melting point]] (i.e. using the [[Kelvin scale]]):
+<math> T_H = \frac{T (\text{K})}{T_{mp} (\text{K})} </math>
-Solder (T<sub>mp</sub>: 183°C = 456K) at 0.85T<sub>mp</sub> or 115°C (= 388K), would thus be expected to have comparable properties to copper (T<sub>mp</sub>: 1085°C = 1358K) at 0.85T<sub>mp</sub> or 881°C (= 1154K).
+For example, the homologous temperature of lead at room temperature (25&nbsp;°C) is approximately 0.50 (T<sub>H</sub> = T/T<sub>mp</sub> = 298&nbsp;K/601&nbsp;K = 0.50).
-In electronics applications, where circuits typically operate over a –55°C to +125°C range, eutectic tin-lead (Sn63) solder is working at 0.48T<sub>mp</sub> to 0.87T<sub>mp</sub>. The upper temperature is high relative to the melting point; from this we can deduce that solder will have limited [[mechanical strength]] (as a bulk material) and significant [[Creep (deformation)|creep]] under stress. This is borne out by its comparatively low values for tensile strength, shear strength and modulus of elasticity.{{fact}}
+== Significance of the homologous temperature ==
-Copper, on the other hand, has a much higher melting point, so foils are working at only 0.16T<sub>mp</sub> to 0.29T<sub>mp</sub>, and their properties are little affected by temperature.
+The homologous temperature of a substance is useful for determining the rate of steady state [[Creep (deformation)|creep]] (diffusion-dependent deformation). A higher homologous temperature results in an exponentially higher rate of diffusion dependent deformation.<ref>{{Cite web|url=https://www.doitpoms.ac.uk/tlplib/creep/stress.php|title=DoITPoMS - TLP Library Creep Deformation of Metals - Effects of stress and temperature|website=www.doitpoms.ac.uk|language=en|access-date=2018-11-12|archive-url=https://web.archive.org/web/20190607165131/https://www.doitpoms.ac.uk/tlplib/creep/stress.php|archive-date=2019-06-07}}</ref>
+Additionally, for a given fixed homologous temperature, two materials with different melting points would have similar diffusion-dependent deformation behaviour. For example, solder (T<sub>mp</sub> = 456&nbsp;K) at 115&nbsp;°C would have comparable mechanical properties to copper (T<sub>mp</sub> = 1358&nbsp;K) at 881&nbsp;°C, because they would both be at 0.85T<sub>mp</sub> despite being at different absolute temperatures.
-[[Category:Units of temperature]]
+In electronics applications, where circuits typically operate over a −55&nbsp;°C to +125&nbsp;°C range, [[eutectic]] tin-lead (Sn63) solder is working at 0.48T<sub>mp</sub> to 0.87T<sub>mp</sub>. The upper temperature is high relative to the melting point; from this we can deduce that solder will have limited [[mechanical strength]] (as a bulk material) and significant creep under stress. This is borne out by its comparatively low values for tensile strength, shear strength and modulus of elasticity. Copper, on the other hand, has a much higher melting point, so foils are working at only 0.16T<sub>mp</sub> to 0.29T<sub>mp</sub> and their properties are little affected by temperature.
-{{Physics-stub}}
-{{measurement-stub}}
+==References==
+{{Reflist}}
+{{DEFAULTSORT:Homologous Temperature}}
+[[Category:Scales of temperature]]
+{{thermodynamics-stub}}
+{{Measurement-stub}}