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edited Mar 29, 2016 at 6:07

Xiaoyu Liu

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edited Mar 29, 2016 at 3:42

Xiaoyu Liu

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When I use bilbao crystallographic server recently, I noticed a notation called physically irreducible representationphysically irreducible representation. It seems to mean

Paper says it is a direct sum of two complex conjugate representations (if $\Delta$ is a complex irreducible representation, then a physical irreps is $\Delta \oplus \Delta^*$). For further detail (http://journals.aps.org/prb/pdf/10.1103/PhysRevB.18.2391)

For example, you can checkin this document.article http://www.bgcryst.com/symp10/proceeding/02_Aroyo_183-197.pdf

Now I am wondering, what is the difference between the physically and "unphysically" (see section 4.1.1 full group irreps part (pg 13)), and when I want to check the band degeneracythey gave an example on space group no. 135 for k = T(0.37, which one should be used1/2, 1/2). It has 4 allowable irreps while its full group irreps characters are listed after those. e.g.

The little group of the k-vector has  4  allowed irreps.
The matrices, corresponding to all of the little group elements are :

Irrep T_1 ,  dimension 1
      1               2               3               4         
(1.000,  0.0)   (1.000,113.4)   (1.000,  0.0)   (1.000,113.4)   


 Irrep T_2 ,  dimension 1
      1               2               3               4         
(1.000,  0.0)   (1.000,113.4)   (1.000,180.0)   (1.000,293.4)   


 Irrep T_4 ,  dimension 1
  1               2               3               4         
(1.000,  0.0)   (1.000,293.4)   (1.000,  0.0)   (1.000,293.4)   


 Irrep T_3 ,  dimension 1
      1               2               3               4         
(1.000,  0.0)   (1.000,293.4)   (1.000,180.0)   (1.000,113.4)   


General position characters:
Gen Pos:      1             2             3             4             5           6             7             8             9             10             11             12             13             14             15             16             
T_1      (4.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836, 90.0) (1.836, 90.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836, 90.0) (1.836,270.0) (0.000,  0.0) (0.000,  0.0) 
T_2      (4.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836, 90.0) (1.836, 90.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836,270.0) (1.836, 90.0) (0.000,  0.0) (0.000,  0.0) 
T_4      (4.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836,270.0) (1.836,270.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836,270.0) (1.836, 90.0) (0.000,  0.0) (0.000,  0.0) 
T_3      (4.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836,270.0) (1.836,270.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836, 90.0) (1.836,270.0) (0.000,  0.0)    (0.000,  0.0)

Thanks very muchThen it shows:

Physically-irreducible representations:
  *T_1+*T_4  *T_2+*T_3

Can anyone give me some instructions what it means or some references about its definition and physical meaning?

When I use bilbao crystallographic server recently, I noticed a notation called physically irreducible representation. It seems to mean a direct sum of two complex conjugate representations (if $\Delta$ is a complex irreducible representation, then a physical irreps is $\Delta \oplus \Delta^*$). For further detail, you can check this document. http://www.bgcryst.com/symp10/proceeding/02_Aroyo_183-197.pdf

Now I am wondering, what is the difference between the physically and "unphysically" irreps, and when I want to check the band degeneracy, which one should be used.

Thanks very much

When I use bilbao crystallographic server recently, I noticed a notation called physically irreducible representation.

Paper says it is a direct sum of two complex conjugate representations (if $\Delta$ is a complex irreducible representation, then a physical irreps is $\Delta \oplus \Delta^*$). (http://journals.aps.org/prb/pdf/10.1103/PhysRevB.18.2391)

For example, in this article http://www.bgcryst.com/symp10/proceeding/02_Aroyo_183-197.pdf (see section 4.1.1 full group irreps part (pg 13)), they gave an example on space group no. 135 for k = T(0.37, 1/2, 1/2). It has 4 allowable irreps while its full group irreps characters are listed after those. e.g.

The little group of the k-vector has  4  allowed irreps.
The matrices, corresponding to all of the little group elements are :

Irrep T_1 ,  dimension 1
      1               2               3               4         
(1.000,  0.0)   (1.000,113.4)   (1.000,  0.0)   (1.000,113.4)   


 Irrep T_2 ,  dimension 1
      1               2               3               4         
(1.000,  0.0)   (1.000,113.4)   (1.000,180.0)   (1.000,293.4)   


 Irrep T_4 ,  dimension 1
  1               2               3               4         
(1.000,  0.0)   (1.000,293.4)   (1.000,  0.0)   (1.000,293.4)   


 Irrep T_3 ,  dimension 1
      1               2               3               4         
(1.000,  0.0)   (1.000,293.4)   (1.000,180.0)   (1.000,113.4)   


General position characters:
Gen Pos:      1             2             3             4             5           6             7             8             9             10             11             12             13             14             15             16             
T_1      (4.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836, 90.0) (1.836, 90.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836, 90.0) (1.836,270.0) (0.000,  0.0) (0.000,  0.0) 
T_2      (4.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836, 90.0) (1.836, 90.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836,270.0) (1.836, 90.0) (0.000,  0.0) (0.000,  0.0) 
T_4      (4.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836,270.0) (1.836,270.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836,270.0) (1.836, 90.0) (0.000,  0.0) (0.000,  0.0) 
T_3      (4.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836,270.0) (1.836,270.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (0.000,  0.0) (1.836, 90.0) (1.836,270.0) (0.000,  0.0)    (0.000,  0.0)

Then it shows:

Physically-irreducible representations:
  *T_1+*T_4  *T_2+*T_3

Can anyone give me some instructions what it means or some references about its definition and physical meaning?

Source Link

asked Mar 29, 2016 at 2:55

Xiaoyu Liu

49
4

What is physically irreducible representation?

When I use bilbao crystallographic server recently, I noticed a notation called physically irreducible representation. It seems to mean a direct sum of two complex conjugate representations (if $\Delta$ is a complex irreducible representation, then a physical irreps is $\Delta \oplus \Delta^*$). For further detail, you can check this document. http://www.bgcryst.com/symp10/proceeding/02_Aroyo_183-197.pdf

Now I am wondering, what is the difference between the physically and "unphysically" irreps, and when I want to check the band degeneracy, which one should be used.

Thanks very much

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