[Pw_forum] =?gb2312?B?Q29tcHV0ZSBidWxrIG1vZHVsdXMgYnkgdXNpbmcgdGhlIGZvcm11bGFlIG9mICBQLVYgYW5kIEUtViBCaXJjaKhDTXVybmFnaGFuIGVxdWF0aW9uIG9mIHN0YXRlLg==?=
zhaohscas
zhaohscas at yahoo.com.cn
Sat Jul 12 17:09:34 CEST 2008
Hi forks,
I use the pwscf to compute bulk modulus of BaHfO_3, I obtaibed the the volume and energy under zero pressure first, then I compute the several volume and energy dataset of BaHfO_3 under 2.5GPa, 5.0GPa, 7.5GPa, 10GPa, 20GPa, and 30GPa respectively.
Then, I use the dataset to compute bulk modulus. Due to the formulae of P-V and E-V Birch¨CMurnaghan equation of state are all can be used to do this, in order to comparison, both the P-V and E-V Birch¨CMurnaghan equation of state are used. But, I found that there're great difference between the result obtained from fitting P-V Birch¨CMurnaghan equation of state and that of the E-V Birch¨CMurnaghan equation of state. I also found that the result from P-V fitting is more close to the reports value in the literatures.
Furthermore, I also have a puzzle about the form of the formulae of P-V and E-V Birch¨CMurnaghan equation of state, in detail, I've read from the different literatures that there are two forms of the P-V Birch¨CMurnaghan equation of state:
a) P(V) = \frac{{3B_0 }}{2}\left[ {\left( {\frac{{V_0 }}{V}} \right)^{\frac{7}{3}} - \left( {\frac{{V_0 }}{V}} \right)^{\frac{5}{3}} } \right]\left\{ {1 + \frac{3}{4}\left( {B_0^' - 4} \right)\left[ {\left( {\frac{{V_0 }}{V}} \right)^{\frac{2}{3}} - 1} \right]} \right\}
b) P(V) = \frac{{3B_0 }}{2}\left[ {\left( {\frac{{V_0 }}{V}} \right)^{\frac{7}{3}} - \left( {\frac{{V_0 }}{V}} \right)^{\frac{5}{3}} } \right]\left\{ {1 + \frac{3}{4}\left( {4 - B_0^'} \right)\left[ {\left( {\frac{{V_0 }}{V}} \right)^{\frac{2}{3}} - 1} \right]} \right\}
Where, the B_0 and the B_0^' are the bulk modulus and its pressure derivative respectively.
Which of the above is correct?
As for the E-V Birch¨CMurnaghan equation of state, I read the following form:
E(V) = E_0 + \frac{{9V_0 B_0 }}{{16}}\left\{ {\left[ {\left( {\frac{{V_0 }}{V}} \right)^{\frac{2}{3}} - 1} \right]^3 B_0^' + \left[ {\left( {\frac{{V_0 }}{V}} \right)^{\frac{2}{3}} - 1} \right]^2 \left[ {6 - 4\left( {\frac{{V_0 }}{V}} \right)^{\frac{2}{3}} } \right]} \right\}
Is this right or not?
Who can give me some hints?
Sincerely yours,
--------------
Hongsheng Zhao <zhaohscas at yahoo.com.cn>
Xinjiang Technical Institute of Physics and Chemistry
Chinese Academy of Sciences
GnuPG DSA: 0xD10849
2008-07-12
More information about the users
mailing list