剪切模量

剪力模数
剪力模数
常见符号	G, S
国际单位	帕斯卡
从其他物理量的推衍	G = τ / γ
因次

剪力模数（shear modulus）是材料力学中的名词，弹性材料承受剪应力时会产生剪应变，定义为剪应力与剪应变的比值。公式记为

G={\frac {\tau }{\gamma }}

其中， $G\,$ 表示剪力模数， $\tau \,$ 表示剪应力， $\gamma \,$ 表示剪应变。在均质且等向性的材料中：

G={E \over {2(1+\nu )}}

其中， $E\,$ 是杨氏模数(Young's modulus )， $\nu \,$ 是泊松比(Poisson's ratio)。

波

在均匀各向同性固体中，有两种波:P波和S波。剪切波的速度， $(v_{s})$ 由剪切模量控制，

v_{s}={\sqrt {\frac {G}{\rho }}}

其中

G是剪切模量

\rho

是固体的密度.

金属的剪切模量

Shear modulus of copper as a function of temperature. The experimental data^[1]^[2] are shown with colored symbols.

金属的剪切模量通常随温度的升高而降低。在高压下，剪切模量也随外加压力的增大而增大。在许多金属中，熔点温度、空位形成能和剪切模量之间的关系已经被观察到。^[3]

有几种模型试图预测金属的剪切模量(可能还有合金的剪切模量)。在塑性流动计算中使用的剪切模量模型包括:

MTS剪切模量模型由机械阈值应力(MTS)塑性流动应力模型开发并与之结合使用。^[4]^[5]^[6]
由SCGL流动应力模型开发并与之结合使用的SCGL剪切模量模型。^[7]
纳达尔和LePoac (NP)剪切模量模型，利用Lindemann理论确定剪切模量对温度的依赖关系，利用SCG模型确定剪切模量对压力的依赖关系。^[2]

MTS剪切模型

MTS剪切模量模型为:

\mu (T)=\mu _{0}-{\frac {D}{\exp(T_{0}/T)-1}}

其中 $\mu _{0}$ 为 $T=0K$ 处的剪切模量， $D$ 和 $T_{0}$ 为材料常数。

SCG剪切模型

NP剪切模型

剪切松弛模量

参见

换算公式
均质各向同性线弹性材料具有独特的弹性性质，因此知道弹性模量中的任意两种，就可由下列换算公式求出其他所有的弹性模量。
	$(\lambda ,\,G)$	$(E,\,G)$	$(K,\,\lambda )$	$(K,\,G)$	$(\lambda ,\,\nu )$	$(G,\,\nu )$	$(E,\,\nu )$	$(K,\,\nu )$	$(K,\,E)$	$(M,\,G)$
$K=\,$	$\lambda +{\tfrac {2G}{3}}$	${\tfrac {EG}{3(3G-E)}}$			${\tfrac {\lambda (1+\nu )}{3\nu }}$	${\tfrac {2G(1+\nu )}{3(1-2\nu )}}$	${\tfrac {E}{3(1-2\nu )}}$			$M-{\tfrac {4G}{3}}$
$E=\,$	${\tfrac {G(3\lambda +2G)}{\lambda +G}}$		${\tfrac {9K(K-\lambda )}{3K-\lambda }}$	${\tfrac {9KG}{3K+G}}$	${\tfrac {\lambda (1+\nu )(1-2\nu )}{\nu }}$	$2G(1+\nu )\,$		$3K(1-2\nu )\,$		${\tfrac {G(3M-4G)}{M-G}}$
$\lambda =\,$		${\tfrac {G(E-2G)}{3G-E}}$		$K-{\tfrac {2G}{3}}$		${\tfrac {2G\nu }{1-2\nu }}$	${\tfrac {E\nu }{(1+\nu )(1-2\nu )}}$	${\tfrac {3K\nu }{1+\nu }}$	${\tfrac {3K(3K-E)}{9K-E}}$	$M-2G\,$
$G=\,$			${\tfrac {3(K-\lambda )}{2}}$		${\tfrac {\lambda (1-2\nu )}{2\nu }}$		${\tfrac {E}{2(1+\nu )}}$	${\tfrac {3K(1-2\nu )}{2(1+\nu )}}$	${\tfrac {3KE}{9K-E}}$
$\nu =\,$	${\tfrac {\lambda }{2(\lambda +G)}}$	${\tfrac {E}{2G}}-1$	${\tfrac {\lambda }{3K-\lambda }}$	${\tfrac {3K-2G}{2(3K+G)}}$					${\tfrac {3K-E}{6K}}$	${\tfrac {M-2G}{2M-2G}}$
$M=\,$	$\lambda +2G\,$	${\tfrac {G(4G-E)}{3G-E}}$	$3K-2\lambda \,$	$K+{\tfrac {4G}{3}}$	${\tfrac {\lambda (1-\nu )}{\nu }}$	${\tfrac {2G(1-\nu )}{1-2\nu }}$	${\tfrac {E(1-\nu )}{(1+\nu )(1-2\nu )}}$	${\tfrac {3K(1-\nu )}{1+\nu }}$	${\tfrac {3K(3K+E)}{9K-E}}$

^ Overton, W.; Gaffney, John. Temperature Variation of the Elastic Constants of Cubic Elements. I. Copper. Physical Review. 1955, 98 (4): 969. Bibcode:1955PhRv...98..969O. doi:10.1103/PhysRev.98.969.
^ ^2.0 ^2.1 Nadal, Marie-Hélène; Le Poac, Philippe. Continuous model for the shear modulus as a function of pressure and temperature up to the melting point: Analysis and ultrasonic validation. Journal of Applied Physics. 2003, 93 (5): 2472. Bibcode:2003JAP....93.2472N. doi:10.1063/1.1539913.
^ March, N. H., (1996), Electron Correlation in Molecules and Condensed Phases （页面存档备份，存于互联网档案馆）, Springer, ISBN 0-306-44844-0 p. 363
^ Varshni, Y. Temperature Dependence of the Elastic Constants. Physical Review B. 1970, 2 (10): 3952–3958. Bibcode:1970PhRvB...2.3952V. doi:10.1103/PhysRevB.2.3952.
^ Chen, Shuh Rong; Gray, George T. Constitutive behavior of tantalum and tantalum-tungsten alloys (PDF). Metallurgical and Materials Transactions A. 1996, 27 (10): 2994 [2019-11-22]. Bibcode:1996MMTA...27.2994C. doi:10.1007/BF02663849. （原始内容存档 (PDF)于2020-10-01）.
^ Goto, D. M.; Garrett, R. K.; Bingert, J. F.; Chen, S. R.; Gray, G. T. The mechanical threshold stress constitutive-strength model description of HY-100 steel. Metallurgical and Materials Transactions A. 2000, 31 (8): 1985–1996 [2019-11-22]. doi:10.1007/s11661-000-0226-8. （原始内容存档于2017-09-25）.
^ Guinan, M; Steinberg, D. Pressure and temperature derivatives of the isotropic polycrystalline shear modulus for 65 elements. Journal of Physics and Chemistry of Solids. 1974, 35 (11): 1501. Bibcode:1974JPCS...35.1501G. doi:10.1016/S0022-3697(74)80278-7.

[Overton55-1] Overton, W.; Gaffney, John. Temperature Variation of the Elastic Constants of Cubic Elements. I. Copper. Physical Review. 1955, 98 (4): 969. Bibcode:1955PhRv...98..969O. doi:10.1103/PhysRev.98.969.

[Nadal03-2] 2.0 ^2.1 Nadal, Marie-Hélène; Le Poac, Philippe. Continuous model for the shear modulus as a function of pressure and temperature up to the melting point: Analysis and ultrasonic validation. Journal of Applied Physics. 2003, 93 (5): 2472. Bibcode:2003JAP....93.2472N. doi:10.1063/1.1539913.

[March-3] March, N. H., (1996), Electron Correlation in Molecules and Condensed Phases （页面存档备份，存于互联网档案馆）, Springer, ISBN 0-306-44844-0 p. 363

[Varshni70-4] Varshni, Y. Temperature Dependence of the Elastic Constants. Physical Review B. 1970, 2 (10): 3952–3958. Bibcode:1970PhRvB...2.3952V. doi:10.1103/PhysRevB.2.3952.

[Chen96-5] Chen, Shuh Rong; Gray, George T. Constitutive behavior of tantalum and tantalum-tungsten alloys (PDF). Metallurgical and Materials Transactions A. 1996, 27 (10): 2994 [2019-11-22]. Bibcode:1996MMTA...27.2994C. doi:10.1007/BF02663849. （原始内容存档 (PDF)于2020-10-01）.

[Goto00-6] Goto, D. M.; Garrett, R. K.; Bingert, J. F.; Chen, S. R.; Gray, G. T. The mechanical threshold stress constitutive-strength model description of HY-100 steel. Metallurgical and Materials Transactions A. 2000, 31 (8): 1985–1996 [2019-11-22]. doi:10.1007/s11661-000-0226-8. （原始内容存档于2017-09-25）.

[Guinan74-7] Guinan, M; Steinberg, D. Pressure and temperature derivatives of the isotropic polycrystalline shear modulus for 65 elements. Journal of Physics and Chemistry of Solids. 1974, 35 (11): 1501. Bibcode:1974JPCS...35.1501G. doi:10.1016/S0022-3697(74)80278-7.

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剪力模数
常见符号	$G$ , $S$
国际单位	帕斯卡
从其他物理量的推衍	$G = τ / γ$
因次	${\mathsf {L}}^{-1}{\mathsf {M}}{\mathsf {T}}^{-2}$