We report here the predicted structural and electrochemical characteristics of ε-Li_xVOPO₄ doped with 25% Cr or Mo using density functional theory (DFT) calculations. We predict the charging potentials as a function of lithiation and the DFT energetics for various phases of Li_xVOPO₄ from x = 0 to 2.5. We further highlight the electron localization function (ELF) and magnetic spin distributions over the lithiation cycle. For Cr–Li_xVOPO₄, we find an intermediate phase at x = 1.5, and for Mo–Li_xVOPO₄, we find two intermediate phases at x = 0.5 and 1.5. We predict a 50% increase in lithium capacity for both doped and undoped systems with reasonable voltaic behavior and additionally find that the spins on undoped and Cr-doped Li_xVOPO₄ stay ferromagnetic throughout the entire lithiation cycle. Overall, we predict an increase in the electrochemical and structural capabilities with Cr and Mo dopants, suggesting Cr and Mo-doped ε-Li_xVOPO₄ as potentially promising cathodes for next generation lithium-ion batteries

Goddard, William A., III

Iyer, Vedanth B.

English

Caltech Authors - Main

S1
Supporting Information: Electrochemical Performance and Structures of Cr 
and Mo Doped ε-LixVOPO4 Predicted as Promising Cathodes for Next 
Generation Lithium-ion Batteries
Vedanth B. Iyer,† William A. Goddard III*
Materials and Process Simulation Center, MC 137-74,
California Institute of Technology, Pasadena, CA 91125, United States 
†permanent address, Portland OR
*E-mail: wag@caltech.edu
Table of Contents
DFT Relaxed Structures and Atomic Coordinates…………………………………………...S2
Table S1: DFT calculated lattice parameters for different LixVOPO4 phases………......S2
Table S2: DFT calculated lattice parameters for Cr and Mo doped systems…………...S3
Table S3: DFT relaxed atomic positions of the Mo1,2 – Li0.5VOPO4 phases…………...S4
Table S4: DFT relaxed atomic positions of all Z-Li2.5VOPO4 systems……………..S5-S7 
Energetics and Electrochemical Performance……………………………………………......S8
Figure S1: Constructed convex hull of undoped LixVOPO4 …………………………...S9
Table S5: Calculated voltage profile of undoped LixVOPO4 …………………………S10
Local ZO6 Octahedral Evaluation…………………………………………………………....S10
Figures S2(a) – S2(c): Local ZO6 environments of all systems over lithiation…..S10-S13
Electron Localization Function (ELF)……………………………………………………….S14
Table S5: Exact Miller indices used to construct each 2-D plane……………………..S14
References……………………………………………………………………………………...S15
S2
DFT Relaxed Structures and Atomic Coordinates 
Table S1. DFT (PBE+U) calculated unit cell parameters for LixVOPO4 in comparison with 
previous experimental 1 and QM (HSE) 1 lattice parameters 
Lithium 
Content 
(x) 
Data 
Type
a (Å) b (Å) c (Å) α (o) β (o) γ (o) Volume(Å3)
0 PBE+U 7.356 7.006 7.364 90.00 115.14 90.00 343.52
Exp. 7.266 6.893 7.265 90.00 115.30 90.00 329.10
HSE 7.246 6.966 7.308 90.00 114.62 90.00 335.36
1 PBE+U 6.845 7.218 8.010 89.73 91.60 116.51 353.94
Exp. 6.734 7.196 7.918 89.81 91.27 116.91 342.04
HSE 6.870 7.159 7.825 89.79 91.31 117.24 342.06
1.5 PBE+U 7.132 7.199 7.805 90.14 90.44 116.17 359.70
Exp. 6.982 6.992 7.789 89.57 89.90 115.72 342.54
HSE 6.968 7.014 7.770 89.65 89.08 116.22 340.58
2 PBE+U 7.191 7.327 7.864 90.11 90.48 116.18 371.84
Exp. 7.195 7.101 7.775 89.82 89.79 116.34 356.00
HSE 7.250 7.106 7.714 89.68 90.01 116.34 356.16
2.5 PBE+U 7.402 7.618 7.809 91.31 90.32 118.12 388.20
Exp. n/a n/a n/a n/a n/a n/a n/a
HSE n/a n/a n/a n/a n/a n/a n/a
S3
Table S2. DFT (PBE+U) calculated unit cell parameters for stable phases of the doped Z-
LixVOPO4 structures 
Lithium 
Content 
(x) 
System a (Å) b (Å) c (Å) α (o) β (o) γ (o) Volume(Å3)
0 Cr 7.356 7.030 7.373 90.05 115.00 89.97 345.58
Mo 7.397 7.093 7.418 90.21 115.26 91.02 351.90
0.5 Mo1 6.889 7.340 7.965 90.16 90.88 117.45 357.34
Mo2 6.886 7.327 7.970 90.74 90.31 117.28 357.33
1 Cr1 6.809 7.098 8.031 89.85 91.27 116.02 348.72
Cr2 6.822 7.121 8.034 89.61 91.68 116.12 350.22
Mo1 6.861 7.164 8.080 89.65 91.65 115.86 357.21
Mo2 6.851 7.164 8.076 89.59 91.90 115.69 356.97
1.5 Cr1 7.073 7.201 7.802 89.83 91.49 116.82 354.51
Cr2 7.082 7.188 7.812 90.17 90.76 116.70 355.19
Mo1 7.136 7.235 7.888 89.95 91.28 116.76 363.55
Mo2 7.145 7.232 7.884 90.49 91.07 116.77 363.58
2 Cr1 7.184 7.316 7.830 89.90 90.83 116.32 368.81
Cr2 7.184 7.312 7.827 90.26 90.05 116.24 368.71
Mo1 7.249 7.381 7.888 89.94 90.84 116.42 377.87
Mo2 7.259 7.361 7.895 90.23 90.15 116.15 378.62
2.5 Cr1  7.382 7.687 7.797 91.49 89.86 117.92 390.74
Cr2 7.329 7.660 7.780 90.48 89.68 116.12 392.16
Mo1 7.462 7.632 7.871 90.68 90.28 117.62 397.11
Mo2 7.488 7.643 7.871 91.36 90.21 118.33 396.28
S4
Table S3. DFT (PBE+U) relaxed atomic positions of the distinct intermediate phases at Mo-
Li0.5VOPO4. (a) structure with the Mo1 dopant; (b) structure with the Mo2 dopant.   
Atom x y z Atom x y z
Li 0.7859 0.7002 0.9191 Li 0.7843 0.6907 0.9194
Li 0.3218 0.8423 0.4274 Li 0.3038 0.8334 0.4278
V 0.2489 0.0359 0.7680 V 0.2482 0.0344 0.7682
V 0.7553 0.9706 0.2304 V 0.2380 0.5176 0.7387
V 0.2370 0.5178 0.7387 V 0.7566 0.4752 0.2664
P 0.2419 0.7541 0.0804 P 0.2313 0.7503 0.0809
P 0.7612 0.2423 0.9122 P 0.7608 0.2486 0.9104
P 0.2530 0.2368 0.4175 P 0.2664 0.2421 0.4178
P 0.7352 0.7634 0.5880 P 0.7370 0.7575 0.5871
O 0.5513 0.0894 0.8235 O 0.5517 0.0901 0.8253
O 0.4490 0.9100 0.1748 O 0.4396 0.9093 0.1759
O 0.1337 0.8551 0.9688 O 0.1281 0.8535 0.9685
O 0.8549 0.1337 0.0286 O 0.8596 0.1375 0.0216
O
O
0.9272
0.0507
0.9059
0.0900
0.7016
0.3187
O
O
0.9282
0.0633
0.9022
0.0929
0.7003
0.3160
O 0.3315 0.1084 0.5270 O 0.3359 0.1085 0.5273
O 0.6409 0.8667 0.4646 O 0.6408 0.8669 0.4699
O 0.2332 0.7278 0.6657 O 0.2346 0.7288 0.6673
O 0.7609 0.2554 0.3170 O 0.7625 0.2523 0.3187
O 0.2699 0.2612 0.8271 O 0.2687 0.2610 0.8267
O 0.7376 0.7405 0.1620 O 0.7359 0.7482 0.1630
O 0.0869 0.6431 0.2288 O 0.0782 0.6402 0.2279
O 0.9356 0.3645 0.7784 O 0.9347 0.3680 0.7757
O 0.2901 0.6040 0.9714 O 0.2872 0.6034 0.9711
O 0.7246 0.4083 0.1120 O 0.7269 0.4109 0.0157
O 0.4329 0.3702 0.2941 O 0.4440 0.3739 0.2957
O 0.5590 0.6286 0.7174 O 0.5598 0.6255 0.7172
O 0.2014 0.3863 0.5266 O 0.2051 0.3865 0.5263
O 0.8126 0.6289 0.4848 O 0.8123 0.6272 0.4781
Mo 0.7560 0.4794 0.2658 Mo 0.7566 0.9842 0.2353
(a)    (b)
S5
Table S4. DFT (PBE+U) relaxed atomic positions for all Z-Li2.5VOPO4 systems. (a) 
Li2.5VOPO4; (b) Cr1-Li2.5VOPO4; (c) Cr2-Li2.5VOPO4; (d) Mo1-Li2.5VOPO4; (e) Mo2- 
Li2.5VOPO4. Atomic coordinates of the additional Li atoms and dopants are highlighted in bold 
face.   
                                  
   (a)
Atom x y z 
Li 0.3641 0.5155 0.1982
Li 0.5000 0.5000 0.5000
Li 0.5000 0.0000 0.0000
Li 0.2501 0.1258 0.5385
Li 0.1426 0.6733 0.0568
Li 0.1394 0.4006 0.5563
V 0.0215 0.7777 0.7547
V 0.5011 0.7571 0.7536
P 0.7397 0.2278 0.6192
P 0.7528 0.7282 0.1176
O 0.1007 0.5639 0.3014
O 0.6571 0.0842 0.7686
O 0.4284 0.7430 0.4766
O 0.8590 0.1594 0.4953
O
O
0.7421
0.1048
0.2179
0.0737
0.1479
0.7867
O 0.4290 0.2678 0.9767
O 0.7444 0.7011 0.6400
O 0.6599 0.5724 0.2638
O 0.1308 0.3437 0.0085
S6
Atom x y z Atom x y z
Li 0.3598 0.5101 0.1887 Li 0.3597 0.5119 0.2011
Li 0.6270 0.4878 0.8176 Li 0.6452 0.4856 0.7969
Li 0.4994 0.4988 0.5013 Li 0.4954 0.4987 0.5004
Li 0.5003 0.0058 0.9991 Li 0.4987 0.9996 0.0017
Li 0.2515 0.1297 0.5409 Li 0.2448 0.1180 0.5433
Li 0.7495 0.8759 0.4612 Li 0.7459 0.8708 0.4533
Li 0.8593 0.3101 0.9397 Li 0.8640 0.3439 0.9477
Li 0.1432 0.6877 0.0607 Li 0.1480 0.6647 0.0537
Li 0.1387 0.4028 0.5537 Li 0.1317 0.3918 0.5606
Li 0.8655 0.4028 0.5537 Li 0.8625 0.5982 0.4480
V 0.0212 0.7709 0.7546 V 0.9795 0.2132 0.2421
V 0.9764 0.2190 0.2446 V 0.4995 0.7586 0.7533
V 0.4987 0.2436 0.2460 V 0.4997 0.2427 0.2479
P 0.7446 0.2380 0.6167 P 0.7315 0.2111 0.6171
P 0.2612 0.7750 0.3797 P 0.2578 0.7748 0.3816
P 0.2410 0.2605 0.8815 P 0.2551 0.2880 0.8809
P 0.7533 0.7258 0.1210 P 0.7552 0.7257 0.1168
O 0.1027 0.5677 0.3023 O 0.1094 0.5727 0.3028
O 0.9110 0.4502 0.6799 O 0.8810 0.4071 0.7004
O 0.6673 0.1087 0.7731 O 0.6469 0.0588 0.7598
O 0.3388 0.9173 0.2305 O 0.3491 0.9201 0.2340
O
O
0.4319 
0.5735
0.7483
0.2607
0.4747
0.5194
O
O
0.4237
0.5650
0.7435
0.2504
0.4840
0.5242
O 0.8593 0.1597 0.4953 O 0.8545 0.1480 0.4879
O 0.1413 0.8423 0.5064 O 0.1290 0.8393 0.5021
O 0.7422 0.2160 0.1482 O 0.7470 0.2213 0.1482
O 0.2629 0.7843 0.8501 O 0.2743 0.7815 0.8518
O 0.0976 0.0584 0.7978 O 0.1191 0.1079 0.7780
O 0.8891 0.9235 0.2153 O 0.8907 0.9193 0.2099
O 0.4264 0.2653 0.9784 O 0.4334 0.2724 0.9754
O 0.5686 0.7225 0.0239 O 0.5788 0.7370 0.0170
O 0.7391 0.7035 0.6488 O 0.7311 0.7074 0.6451
O 0.2546 0.3001 0.3571 O 0.2534 0.2968 0.2624
O 0.6647 0.5699 0.2659 O 0.6571 0.5732 0.2657
O 0.3287 0.4061 0.7301 O 0.3529 0.4530 0.7407
O 0.1251 0.3349 0.0069 O 0.1374 0.3573 0.0128
O 0.8741 0.6599 0.9927 O 0.8763 0.6512 0.9957
Cr 0.5048 0.7618 0.7538 Cr 0.0191 0.7814 0.7570
(b)                  (c)
S7
Atom x y z Atom x y z
Li 0.3618 0.5083 0.1956 Li 0.3612 0.5051 0.1826
Li 0.6387 0.4804 0.7852 Li 0.6233 0.4815 0.8001
Li 0.4987 0.4972 0.4921 Li 0.4960 0.5048 0.4935
Li 0.4876 0.0025 0.0044 Li 0.4916 0.9991 0.0007
Li 0.2464 0.1179 0.5438 Li 0.2521 0.1272 0.5366
Li 0.7511 0.8757 0.4522 Li 0.7452 0.8764 0.4631
Li 0.8535 0.3376 0.9467 Li 0.8562 0.3059 0.9393
Li 0.1456 0.6680 0.0562 Li 0.1410 0.6765 0.0608
Li 0.1386 0.3922 0.5557 Li 0.1400 0.3954 0.5568
Li 0.8582 0.6044 0.4470 Li 0.8563 0.6020 0.4346
V 0.0178 0.7713 0.7544 V 0.9776 0.2219 0.2472
V 0.9793 0.2216 0.2440 V 0.5023 0.7603 0.7544
V 0.5010 0.2425 0.2485 V 0.5023 0.2432 0.2470
P 0.7417 0.2268 0.6160 P 0.7421 0.2306 0.6197
P 0.2567 0.7721 0.3810 P 0.2628 0.7726 0.3799
P 0.2472 0.2725 0.8843 P 0.2484 0.2769 0.8833
P 0.7562 0.7266 0.1176 P 0.7505 0.7245 0.1181
O 0.1069 0.5658 0.3002 O 0.1006 0.5649 0.3028
O 0.8940 0.4303 0.6980 O 0.9058 0.4382 0.6970
O 0.6564 0.0816 0.7643 O 0.6632 0.0908 0.7708
O 0.3499 0.9187 0.2372 O 0.3481 0.9172 0.2341
O
O
0.4212
0.5745
0.7403
0.2576
0.4821
0.5223
O
O
0.4274
0.5748
0.7439
0.2580
0.4769
0.5262
O 0.8606 0.1594 0.4937 O 0.8585 0.1605 0.4968
O 0.1347 0.8373 0.5005 O 0.1447 0.8443 0.5015
O 0.7463 0.2234 0.1508 O 0.7451 0.2194 0.1492
O 0.2768 0.7909 0.8675 O 0.2715 0.7916 0.8681
O 0.1126 0.0846 0.7842 O 0.1067 0.0784 0.7893
O 0.8905 0.9221 0.2135 O 0.8910 0.9226 0.2137
O 0.4272 0.2565 0.9800 O 0.4318 0.2790 0.9768
O 0.5800 0.7369 0.0198 O 0.5727 0.7264 0.0208
O 0.7302 0.6981 0.6294 O 0.7324 0.6985 0.6319
O 0.2545 0.2944 0.3611 O 0.2554 0.2955 0.3577
O 0.6548 0.5709 0.2622 O 0.6562 0.5681 0.2622
O 0.3440 0.4341 0.7400 O 0.3360 0.4312 0.7371
O 0.1309 0.3450 0.0091 O 0.1313 0.3440 0.0106
O 0.8728 0.6526 0.9975 O 0.8693 0.6533 0.9959
Mo 0.5026 0.7585 0.7538 Mo 0.0183 0.7672 0.7532
             (d)    (e)
S8
Energetics and Electrochemical Performance 
Based on previous studies and literature on computational battery theory 1,2 , we calculated the 
formation energies and constructed the convex hulls for all systems relative to the ε-LixVOPO4 
end members (x = 0 – 2). Equation 1 is used to derive the formation energy ΔE (x) at each phase: 
𝛥𝐸(𝑥) = 𝐸(𝐿𝑖𝑥𝑉𝑂𝑃𝑂4) ―
2 ― 𝑥
2 ∗ 𝐸
(𝑉𝑂𝑃𝑂4) ―
𝑥
2 ∗ 𝐸(𝐿𝑖2𝑉𝑂𝑃𝑂4)  
(1)
where E is defined as the total DFT energy of the system. We also calculated the formation 
energies in this manner for the dopant systems as well. 
Furthermore, the DFT energetics can be used to obtain a theoretical voltage profile with 
increasing lithiation 2,3. Equation 2 is used to derive the voltage step using two LixVOPO4 
reference points: 
𝑉 =  ―
𝐸(𝐿𝑖𝑥2𝑉𝑂𝑃𝑂4) ― 𝐸(𝐿𝑖𝑥1𝑉𝑂𝑃𝑂4) ― (𝑥2 ― 𝑥1) ∗ 𝐸(𝐿𝑖)
(𝑥2 ― 𝑥1)𝑒
(2)
where E is again defined as the total DFT energy of the system and “e” is termed as the exact 
coulombic charge of an electron. Equation 2 thus provides an average change in voltaic behavior 
across the lithiation cycle. 
The root-mean-squared deviation (RMSD) values for both delithation and relithiation were 
calculated using the initial structures with either the Li removed or added (reference system) and 
the reoptimized structures. Equation 3 is used to calculate the RMSD: 7
𝑅𝑀𝑆𝐷 =  
1
𝑁
𝑁
∑
𝑖 = 0
((𝑣𝑖𝑥 ― 𝑤𝑖𝑥)2 + (𝑣𝑖𝑦 ― 𝑤𝑖𝑦)2 + (𝑣𝑖𝑧 ― 𝑤𝑖𝑧)2)
(3)
where v and w are the vector coordinates in Å for the reference and reoptimized systems 
respectively and N is the total number of ions in the system.  
S9
DFT Constructed Convex Hull and Voltage Profiles for undoped LixVOPO4  
The DFT calculated formation energies and voltage profiles for LixVOPO4 are generally 
consistent with previous experimental and theoretical works 1. Figure S1 displays the constructed 
convex hull highlighting the formation energies of undoped LixVOPO4 for stable phases of 
VOPO4 to Li2VOPO4. 
Figure S1. DFT (PBE+U) constructed convex hull showing the formation energies for the most 
stable configurations of ε-LixVOPO4  
We observe that going from the fully delithiated phase to the first lithium insertion, there are no 
stable intermediate configurations of LixVOPO4 since the Li0.5VOPO4 phase displays a 
calculated formation energy above the convex hull. This is in agreement with previous 
experiments and QM studies 1,5. We also note that the most stable phase of LixVOPO4 is for the 
first lithium insertion (where x = 1). We further observe a stable intermediate phase at 
Li1.5VOPO4 between the first and second lithium insertion, which is also in agreement with 
previous experiments and QM studies 1. 
The DFT calculated voltage profile for LixVOPO4 shown in Table S5 is also in great agreement 
with previous experimental studies and QM calculations 1,6. Table S5 compares our DFT (PBE+U) 
calculated voltage profiles with previous experimental values and hybrid DFT (HSE) calculations 
taken as an average over the entire lithiation cycle. 
0 0.5 1 1.5 2
-0.8
-0.7
-0.6
-0.5
-0.4
-0.3
-0.2
-0.1
0
0.1
Lithium content (x) in Ɛ-LiXVOPO4   
Fo
rm
at
io
n 
En
er
gy
 (e
V)
S10
Table S5. Comparison of our calculated voltage profile (PBE+U) for ε-LixVOPO4 as a function 
of the lithiation cycle
Charging Potential 
of ε-LixVOPO4 as a 
function of (x)
DFT (PBE+U) 
Calculated (0K) 
(this work)
Experimental (298 
K) [ref 1.]
DFT (HSE) 
Calculated
(0K) [ref 1.]
0 - 0.5 3.73 V 3.8 - 4.5 V 4.01 V
0.5 - 1 3.73 V 3.8 - 4.5 V 4.01 V
1 - 1.5 2.74 V 2.37- 2.5 V 2.67 V
1.5 - 2 1.92 V 2.04 – 2.14 V 2.00 V
2 – 2.5 0.97 V N/A N/A
Here, we predict that the voltage step beyond the second lithium insertion (from 2 to 2.5) is 
around 1 V, suggesting that a higher lithium capacity is technically possible. This might not be 
realistic however because the electrolyte in such a battery would require a somewhat large 
electrochemical window that is lower than 1V and higher than 4V.    
Local ZO6 Octahedral Evaluation
Figures S2(a) – 2(c) highlight the local ZO6 environments (where Z = V, Cr, or Mo) of the 
systems at the fully delithiated state and each Li insertion. 
S11
S12
S13
Figure S2. (a) Local ZO6 octahedral environments of VOPO4 [1], Cr-VOPO4 [2], and Mo-
VOPO4 [3]. This shows a clear Z=O oxo bond for all three cases. As a result, the O6 atom is very 
far from the transition metal atoms; (b) Local ZO6 octahedral environments of LiV1OPO4 [1], 
LiV2OPO4 [2], Cr1-LiVOPO4 [3], Cr2-LiVOPO4 [4],  Mo1-LiVOPO4 [5], and Mo2-LiVOPO4 [6]. 
Again, we see the strong Z=O bonds to the O1 atom, but now the O6 atom is much closer for all 
cases; (c) Local ZO6 octahedral environments of Li2V1OPO4 [1], Li2V2OPO4 [2], Cr1-Li2VOPO4 
[3], Cr2-Li2VOPO4 [4],  Mo1-Li2VOPO4 [5], and Mo2-Li2VOPO4 [6]. We no longer see the Z=O 
bonds but instead, a more perfect octahedral coordination for the t2g occupied orbitals. 
The unit cell data of ε-LixVOPO4 is fairly consistent with the previously reported experimental 
and QM (HSE) derived cell parameters of LixVOPO4 1,4 . 
The VO6 environments at the 5+ oxidation state show one short V=O bond at 1.6 Å with four 
longer V-O bonds between 1.9 to 2.0 Å and one significantly longer bond at 2.6 Å. This is 
typical for a d0 configuration in V. 
For the 4+ oxidation state, we again find one short V=O bond at around 1.7 Å with four longer 
V-O bonds at 1.9 to 2.0 Å but now the O6 atom is much closer with a distance at around 2.2 Å.
For the high spin 3+ oxidation state we find a rather symmetrical octahedral coordination of the 
V-O bonds with all six bonds ranging from 1.9 to 2.1 Å each. 
The Cr-O bonds in CrO6 for all oxidation states are generally similar in length to the V-O bonds 
showing that Cr is only slightly smaller than V. 
The Mo-O bonds in MoO6 are consistently longer than the V-O bonds by ~0.1 Å. The 
environments at the 5+ oxidation state highlight one short Mo=O bond at around 1.7 Å with four 
longer Mo-O bonds between 2.0 to 2.1 Å and the non-bonded O6 atom that is 2.6 Å away. 
For the Mo 4+ oxidation state, we find that the Mo-O bonds have a fairly symmetrical 
coordination with all six Mo-O bonds ranging from around 1.9 to 2.1 Å. This behavior is not 
found in either the V-O or Cr-O bonds at the 4+ oxidation state. 
For the Mo 3+ oxidation state, we again see a symmetrical coordination of the O atoms with 
bonds ranging between 2.1 to 2.2 Å. 
.  
S14
Electron Localization Function (ELF)
We assessed the electron localization using a topological display of the ELF 4,5 in which we 
sliced a 2-D plane through the transition metal atom and four of its oxygen neighbors at the 
dopant sites. Table S6 shows the exact Miller indices and vector distances from the origin “ ” to 𝑑
form the 2-D plane for each system. Because structural relaxation was slightly different for each 
system, the same Miller indices were not used to construct each 2-D plane but rather, the plane 
was fitted to the transition metal atoms and oxygen neighbors of interest specific to each system. 
Table S6. Miller indices in the (hkl) plane format and vector distances from the origin for each 
constructed 2-D ELF plane
Lithium 
Content (x)
System h k l  (Å)𝒅
0 V -1.183 5.360 -1 0.455
Cr 1.237 -5.504 1 -0.455
Mo 1.199 -5.618 1 -0.513
1 V1 68.266 -1 -14.215 4.258
V2 -5.249 1 -2.081 -4.083
Cr1 141.112 -1 -24.690 4.318
Cr2 5.656 -1 2.306 4.157
Mo1 48.558 -1 -9.290 4.316
Mo2 5.675 -1 2.337 4.182
2 V1 1 14.459 -1.078 4.602
V2 1 -5.289 -1.366 -6.488
Cr1 1.049 14.075 -1 4.619
Cr2 -1 5.157 1.328 6.476
Mo1 1.095 13.173 -1 4.643
Mo2 -1 4.744 1.229 6.551
S15
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Electrochemical Performance and Structures of Chromium and Molybdenum-Doped ε-Li_xVOPO₄ Predicted as Promising Cathodes for Next Generation Lithium-Ion Batteries

https://authors.library.caltech.edu/107303/2/jp0c10156_si_001.pdf

Electrochemical Performance and Structures of Chromium and Molybdenum-Doped ε-Li_xVOPO₄ Predicted as Promising Cathodes for Next Generation Lithium-Ion Batteries

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