JVASP-21545_K6Ge2O7
JARVIS-ID:JVASP-21545 Functional:optB88-vdW Primitive cell Primitive cell Conventional cell Conventional cell
Chemical formula:K6Ge2O7 Formation energy/atom (eV):-1.883 a 6.548 Å α:90.0 ° a 6.548 Å α:90.0 °
Space-group :P2_1/c, 14 Relaxed energy/atom (eV):-3.0289 b 9.141 Å β:124.038 ° b 9.141 Å β:124.038 °
Calculation type:Bulk SCF bandgap (eV):3.339 c 11.142 Å γ:90.0 ° c 11.142 Å γ:90.0 °
Crystal system:monoclinic Point group:2/m Density (gcm-3):2.96 Volume (3):552.63 nAtoms_prim:30 nAtoms_conv:30
Download input files

Convergence [Reference]

Calculations are done using VASP software [Source-code]. Convergence on KPOINTS [Source-code] and ENCUT [Source-code] is done with respect to total energy of the system within 0.001 eV tolerance. Please note convergence on KPOINTS and ENCUT is generally done for target properties, but here we assume energy-convergence with 0.001 eV should be sufficient for other properties also. The points on the curves are obtained with single-point calculation (number of ionic steps, NSW=1 ). However, for very accurate calculations, NSW>1 might be needed.

Structural analysis [Reference]

The following shows the X-ray diffraction (XRD)[Source-code] pattern and the Radial distribution function (RDF) plots [Source-code]. XRD peaks should be comparable to experiments for bulk structures. Relative intensities may differ. For mono- and multi-layer structures , we take the z-dimension during DFT calculation for XRD calculations, which may differ from the experimental set-up.

Electronic structure [Reference]

The following shows the electronic density of states and bandstructure [Source-code]. DFT is generally predicted to underestimate bandgap of materials. Accurate band-gaps are obtained with higher level methods (with high computational requirement) such as HSE, GW , which are under progress. If available, MBJ data should be comparable to experiments also. Total DOS, Orbital DOS and Element dos [Source-code] buttons are provided for density of states options. Energy is rescaled to make Fermi-energy zero. In the bandstructure plot [Source-code], spin up is shown with blue lines while spin down are shown with red lines. Non-degenerate spin-up and spin-down states (if applicable) would imply a net orbital magnetic moment in the system. Fermi-occupation tolerance for bandgap calculation is chosen as 0.001.

High-symmetry kpoints based bandgap (eV): 3.342D

Optoelectronic properties Semi-local [Reference]

Incident photon energy dependence of optical is shown below [Source-code]. Only interband optical transitions are taken into account.Please note the underestimatation of band-gap problem with DFT will reflect in the spectra as well. For very accurate optical properties GW/BSE calculation would be needed, which is yet to be done because of their very high computational cost. Optical properties for mono-/multi-layer materials were rescaled with the actual thickness to simulation z-box ratio. Absorption coeffiecient is in cm-1 unit. Also, ionic contributions were neglected.

Dense k-mesh based bandgap is : 3.3394 eV

Static real-parts of dielectric function in x,y,z: 2.88,2.95,2.93

Finite-difference: elastic tensor and derived phonon properties [Reference]

Elastic tensor calculated for the conventional cell of the system with finite-difference method [Source-code]. For bulk structures, elastic constants are given in GPa unit . For layered materials, the elastic constants are rescaled with respect to vacuum padding (see the input files) and the units for elastic coefficients are in N/m . Phonons obtained [Source-code] from this calculation are also shown.

WARNING: Please note we provide finite-size cell phonons only. At least 1.2 nm x1.2 nm x1.2 nm size cell or more is generally needed for obtaining reliable phonon spectrum, but we take conventional cell of the structure only. For systems having primitive-cell phonon representation tables, I denotes infrared activity and R denotes Raman active modes (where applicabale). Selection of particular q-point mesh can give rise to unphysical negative modes in phonon density of states and phonon bandstructre. The minimum thermal conductivity was calculated using elastic tensor information following Clarke and Cahill formalism.

Voigt-bulk modulus (KV): 40.57 GPa, Voigt-shear modulus (GV): 19.7 GPa

Reuss-bulk modulus (KR): 39.72 GPa, Reuss-shear modulus (GR): 19.29 GPa

Poisson's ratio: 0.29, Elastic anisotropy parameter: 0.13

Clarke's lower limit of thermal conductivity (W/(m.K)): 0.71

Cahill's lower limit of thermal conductivity (W/(m.K)): 0.79

Elastic tensor
72.4 28.9 30.7 0.0 -2.8 -0.0
28.9 66.5 25.3 0.0 -0.9 0.0
30.7 25.3 56.4 -0.0 -2.3 0.0
0.0 0.0 -0.0 20.8 -0.0 -1.2
-2.8 -0.9 -2.3 -0.0 17.9 0.0
-0.0 0.0 0.0 -1.2 0.0 23.0

Phonon mode (cm-1)
-49.05
-0.16
-0.15
-0.09
39.3
53.81
61.05
64.75
73.64
81.32
85.24
85.69
91.95
92.29
94.78
95.85
96.33
96.81
110.68
111.29
111.82
112.43
116.25
118.88
119.18
122.96
123.11
126.6
127.52
132.8
133.21
133.49
137.07
138.32
138.64
138.94
141.85
143.05
144.47
155.67
156.98
158.83
161.91
168.21
168.43
169.84
175.8
179.1
185.71
185.75
192.34
196.79
197.13
208.22
213.78
222.02
230.4
231.12
244.04
256.54
263.47
263.92
276.79
287.53
305.18
306.74
307.28
327.9
332.74
336.51
344.09
350.27
355.38
361.76
363.6
391.12
658.87
660.52
685.83
687.48
691.57
693.09
694.21
698.64
702.09
715.36
718.98
735.63
781.54
781.6

Point group

point_group_type: m

Visualize Phonons here
Phonon mode (cm-1) Representation
-49.05
-49.0511108584
-0.16
-0.1601247933
-0.15
-0.148172362
-0.09
-0.0862701141
39.3
39.3039780096
53.81
53.8123995123
61.05
61.0511055587
64.75
64.7492911865
73.64
73.6397587664
81.32
81.3151240855
85.24
85.2365620666
85.69
85.688090732
91.95
91.9537210813
92.29
92.2942043101
94.78
94.7811462075
95.85
95.8547785939
96.33
96.3252280111
96.81
96.814613973
110.68
110.682986473
111.29
111.286026607
111.82
111.815492947
112.43
112.425219619
116.25
116.24920772
118.88
118.881367392
119.18
119.182066851
122.96
122.961294526
123.11
123.111416475
126.6
126.598845047
127.52
127.523208342
132.8
132.804142345
133.21
133.205240141
133.49
133.488348239
137.07
137.071520957
138.32
138.321642635
138.64
138.644149151
138.94
138.943176036
141.85
141.849118234
143.05
143.048089432
144.47
144.471434423
155.67
155.668908629
156.98
156.976521648
158.83
158.830929911
161.91
161.90739913
168.21
168.207432324
168.43
168.427178573
169.84
169.840575833
175.8
175.795208531
179.1
179.101968263
185.71
185.705139448
185.75
185.748077971
192.34
192.33692242
196.79
196.793232238
197.13
197.127193015
208.22
208.224208523
213.78
213.778349881
222.02
222.019567679
230.4
230.404370174
231.12
231.115024692
244.04
244.043439482
256.54
256.539525586
263.47
263.46788368
263.92
263.921527341
276.79
276.786015596
287.53
287.530035398
305.18
305.181504109
306.74
306.741258239
307.28
307.283909217
327.9
327.901618801
332.74
332.738850916
336.51
336.508625371
344.09
344.087542417
350.27
350.273325559
355.38
355.37819825
361.76
361.764347136
363.6
363.598846987
391.12
391.123633232
658.87
658.872256098
660.52
660.517107942
685.83
685.833656174
687.48
687.481038453
691.57
691.573419753
693.09
693.087013296
694.21
694.214807852
698.64
698.640731042
702.09
702.08652224
715.36
715.355369287
718.98
718.976340512
735.63
735.627475311
781.54
781.541655115
781.6
781.596141825

Thermoelectric properties [Reference]

Thermoelectric properties are calculated using BoltzTrap code [Source-code]. Electron and hole mass tensors (useful for semiconductors and insulators mainly)are given at 300 K [Source-code]. Following plots show the Seebeck coefficient and ZT factor (eigenvalues of the tensor shown) at 300 K along three different crystallographic directions. Seebeck coefficient and ZT plots can be compared for three different temperatures available through the buttons given below. Generally very high Kpoints are needed for obtaining thermoelectric properties. We assume the Kpoints obtained from above convergence were sufficient [Source-code].

WARNING: Constant relaxation time approximation (10-14 s) and only electronic contribution to thermal conductivity were utilized for calculating ZT.

Electron mass tensor (me unit)
0.24 0.0 -0.0
0.0 0.55 -0.0
-0.0 -0.0 0.27

Hole mass tensor (me unit)

16.68 0.0 0.0
0.0 68.19 -30.35
0.0 -30.35 59.47

n-& p-type Seebeck coeff. (µV/K), power-factor (µW/(mK2)), conductivity (1/(*m)), zT (assuming lattice part of thermal conductivity as 1 W/(mK)) at 600K and 1020 cm-3 doping. For mono/multi-layer materials consider Seebeck-coeff only.)

Property xx yy zz
n-Seebeck -103.02 -88.01 -85.15
n-PowerFactor 529.63 567.87 718.97
n-Conductivity 49912.66 78303.17 92831.28
n-ZT 0.17 0.19 0.2
p-Seebeck 415.34 417.31 448.95
p-PowerFactor 32.55 68.68 129.4
p-Conductivity 179.15 369.54 750.12
p-ZT 0.02 0.04 0.08

Magnetic moment [Reference]

The orbital magnetic moment was obtained after SCF run. This is not a DFT+U calculation, hence the data could be used to predict zero or non-zero magnetic moment nature of the material only.

Total magnetic moment: -0.0 μB

Magnetic moment per atom: -0.0 μB

Magnetization
Elementsspdtot
K-0.00.0-0.00.0
K-0.00.00.00.0
K0.00.0-0.00.0
K-0.00.00.00.0
K-0.00.00.0-0.0
K-0.0-0.00.0-0.0
K-0.00.00.0-0.0
K-0.00.00.00.0
K-0.00.00.00.0
K-0.0-0.0-0.0-0.0
K-0.00.00.00.0
K-0.00.0-0.0-0.0
Ge-0.0-0.0-0.0-0.0
Ge-0.0-0.0-0.0-0.0
Ge-0.0-0.0-0.0-0.0
Ge-0.0-0.0-0.0-0.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0
O0.00.00.00.0

See also

Links to other databases or papers are provided below


mp-5116

ICSD-ID: 60651

AFLOW link

MP link
mp-5116

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