The Peter Day Series of Magnetic (Super)Conductors †
Abstract
:1. Introduction
2. The Superconducting Monoclinic β″ Phase
2.1. β″-BEDT-TTF Salts with the [Fe(C2O4)3]3− Anion
# | CCDC | Formula a | SG b | Elect. Prop | A+ | G | Ref. |
---|---|---|---|---|---|---|---|
1 | BEMPEO | (ET)4[(H3O)Fe(ox)3]·0.5 py | C2/c | M > 116 K | H3O+ | Py | [15] |
2 | BEMQAL | (ET)4[(H3O)Fe(ox)3]·py | C2/c | - | H3O+ | py | [15] |
3 | COQNEB | (ET)4[(H2O)Fe(ox)3]·PhNO2 | C2/c | σ = 10 S/cm Semi | - | PhNO2 | [22] |
4 | ECOPIV | (ET)4[(H3O/NH4)Fe(ox)3]·PhNO2 | C2/c | Tc = 6.2 K | H3O+/NH4+ | PhNO2 | [14] |
5 | KILFOB | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.78(py)0.22 | C2/c | Tc = 3.9 K | H3O+ | PhCN/py | [16] |
6 | KILFOB01 | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.77(py)0.23 | C2/c | - | H3O+ | PhCN/py | [16] |
7 | KILFOB02 | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.66(py)0.34 | C2/c | Tc = 5.8 K | H3O+ | PhCN/py | [16] |
8 | KILFOB03 | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.62(py)0.38 | C2/c | Tc = 6.9 K | H3O+ | PhCN/py | [16] |
9 | KILFOB04 | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.57(py)0.43 | C2/c | Tc = 6.7 K | H3O+ | PhCN/py | [16] |
10 | KILGOC | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.46(py)0.54 | C2/c | Tc = 5.9 K | H3O+ | PhCN/py | [16] |
11 | KILGUI | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.39(py)0.61 | C2/c | Tc = 4.2 K | H3O+ | PhCN/py | [16] |
12 | KILHAP | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.10(py)0.90 | C2/c | Tc = 7.3 K | H3O+ | PhCN/py | [16] |
13 | PONMEL | (ET)4[(H3O)Fe(ox)3]·1,2-PhCl2 | C2/c | M > 0.5 K | H3O+ | 1,2-PhCl2 | [23] |
14 | QAXSIT | (ET)4[(H3O)Fe(ox)3]·PhI | C2/c | σ = 3.4 S/cm Ea = 64 meV | H3O+ | PhI | [20] |
15 | SAPWEM | (ET)4[(H3O)Fe(ox)3]·PhBr | C2/c | Tc = 4.0 K | H3O+ | PhBr | [21] |
16 | SAPWEM02 | (ET)4[(H3O)Fe(ox)3]·PhBr | P-1 | Tc = 4.0 K | H3O+ | PhBr | [20] |
17 | UJOXAT | (ET)4[(H3O)Fe(ox)3]·PhCl | C2/c | M > 0.4 K | H3O+ | PhCl | [17,20] |
18 | UJOXAT01 | (ET)4[(H3O)Fe(ox)3]·PhCl | P-1 | M > 4.2 K | H3O+ | PhCl | [18,20] |
19 | UJOXEX | (ET)4[(H3O)Fe(ox)3]·PhF | C2/c | Tc = 1.0 K | H3O+ | PhF | [17,20] |
20 | UJOXEX01 | (ET)4[(H3O)Fe(ox)3]·PhF | P-1 | Tc = 1.0 K | H3O+ | PhF | [18,20] |
21 | UJOXIB | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.4(PhF)0.6 | C2/c | Tc = 6.0 K | H3O+ | PhCN/PhF | [17] |
22 | UJOXIB01 | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.4(PhF)0.6 | P-1 | Tc = 6.0 K | H3O+ | PhCN/PhF | [18] |
23 | UJOXOH | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.86(PhCl2)0.14 | C2/c | Tc = 7.2 K | H3O+ | PhCN/PhCl2 | [17] |
24 | UJOYAU | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.35(PhCl)0.65 | C2/c | Tc = 6.0 K | H3O+ | PhCN/PhCl | [17] |
25 | UJOYAU02 | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.35(PhCl)0.65 | P-1 | Tc = 6.0 K | H3O+ | PhCN/PhCl | [18] |
26 | UJOYEY | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.17(PhBr)0.83 | C2/c | Tc = 4.2 K | H3O+ | PhCN/PhBr | [17] |
27 | UJOYEY01 | (ET)4[(H3O)Fe(ox)3]·(PhCN)0.17(PhBr)0.83 | P-1 | Tc = 4.2 K | H3O+ | PhCN/PhBr | [18] |
28 | UMACEQ | (ET)4[(NH4)Fe(ox)3]·dmf | C2/c | M > 4.2 K | NH4+ | dmf | [13] |
29 | YUYTUJ | (ET)4[(H3O)Fe(ox)3]·2-Clpy | C2/c | Tc = 2.4–4.0 K | H3O+ | 2-Clpy | [19] |
30 | YUYTUJ01 | (ET)4[(H3O)Fe(ox)3]·2-Clpy | P-1 | Tc = 2.4–4.0 K | H3O+ | 2-Clpy | [19] |
31 | YUYVEV | (ET)4[(H3O)Fe(ox)3]·2-Brpy | C2/c | Tc = 4.3 K | H3O+ | 2-Brpy | [19] |
32 | YUYVEV01 | (ET)4[(H3O)Fe(ox)3]·2-Brpy | P-1 | Tc = 4.3 K | H3O+ | 2-Brpy | [19] |
33 | YUYVOF | (ET)4[(H3O)Fe(ox)3]·3-Clpy | C2/c | M > 0.5 K | H3O+ | 3-Clpy | [19] |
34 | YUYVUL | (ET)4[(H3O)Fe(ox)3]·3-Brpy | C2/c | M > 0.5 K | H3O+ | 3-Brpy | [19] |
35 | ZIGYET | (ET)4[(H3O)Fe(ox)3]·PhCN | C2/c | Tc = 6.5–8.5 K | H3O+ | PhCN | [2,3,4,17] |
2.2. β″-BEDT-TTF Salts with Other [M(C2O4)3]3− Anions (M ≠ Fe)
# | CCDC | Formula a | SG b | Elect. Prop. | A+ | M | G | Ref. |
---|---|---|---|---|---|---|---|---|
36 | CIWMED | (ET)4[K0.8(H3O)0.2Cr(ox)3]·2-Clpy | C2/c | TMI ≈ 10 K | K+/H3O+ | Cr | 2-Clpy | [27] |
37 | CIWMIH | (ET)4[K0.8(H3O)0.2Cr(ox)3]·2-Brpy | C2/c | TMI ≈ 10 K | K+/H3O+ | Cr | 2-Brpy | [27] |
38 | CIWMON | (ET)4[K0.8(H3O)0.2Ga(ox)3]·2-Clpy | C2/c | TMI ≈ 10 K | K+/H3O+ | Ga | 2-Clpy | [27] |
39 | CIWMUT | (ET)4[K0.8(H3O)0.2Ga(ox)3]·2-Brpy | C2/c | TMI ≈ 10 K | K+/H3O+ | Ga | 2-Brpy | [27] |
40 | ECOPUH | (ET)4[(H3O/NH4)Cr(ox)3]·PhNO2 | C2/c | Tc = 5.8 K | H3O+/NH4+ | Cr | PhNO2 | [14] |
41 | FEBLIK | (ET)4[(NH4)Rh(ox)3]·PhBr | C2/c | Tc = 2.5 K | NH4+ | Rh | PhBr | [32] |
42 | FECDAV | (ET)4[(H3O)Rh(ox)3]·PhF | C2/c | TMI ≈ 180 K | H3O+ | Rh | PhF | [32] |
43 | FECDID | (ET)4[(NH4)Rh(ox)3]·PhCl | C2/c | TMI ≈ 10 K | NH4+ | Rh | PhCl | [32] |
44 | HOBROH | (ET)4[K0.33(H3O)0.67Ga(ox)3]·PhBr | C2/c | Semi | K+/H3O+ | Ga | PhBr | [30] |
45 | HUNQIQ | (ET)4[(H3O)Ga(ox)3]·py | C2/c | Tc ≈ 2 K ?? | H3O+ | Ga | py | [29] |
46 | HUNQUC | (ET)4[(H3O)Ga(ox)3]·PhNO2 | C2/c | Tc = 7.5 K | H3O+ | Ga | PhNO2 | [29] |
47 | JUPGUW01 | (ET)4[(H3O)Cr(ox)3]·PhCN | C2/c | Tc = 6.0 K | H3O+ | Cr | PhCN | [4,24,25] |
48 | MEQZIR | (ET)4[(H3O)Cr(ox)3]·CH2Cl2 | C2/c | Semi | H3O+ | Cr | CH2Cl2 | [28] |
49 | UDETUU | (ET)4[K0.7(H3O)0.3Ru(ox)3]·PhBr | C2/c | Tc = 2.8–6.3 K | K+/H3O+ | Ru | PhBr | [31] |
50 | UMACAM | (ET)4[(K/NH4)Cr(ox)3]·dmf | C2/c | M > 4.2 | K+/NH4+ | Cr | dmf | [13] |
51 | UMACIU | (ET)4[KCr(ox)3]·dmf | C2/c | M > 4.2 | K+ | Cr | dmf | [13] |
52 | - | (ET)4[(H3O)Mn(ox)3]·PhBr | C2/c | Tc = 2.0 K | H3O+ | Mn | PhBr | [20] |
53 | - | (ET)4[(H3O)Cr(ox)3]·PhBr | C2/c | Tc = 1.7 K | H3O+ | Cr | PhBr | [21,26] |
54 | - | (ET)4[(H3O)Cr(ox)3]·PhCl | C2/c | M > 130 K σ300 = 3 × 10−3 S/cm | H3O+ | Cr | PhCl | [26] |
3. The Semiconducting pseudo-κ or κ′ Phase
κ′-BEDT-TTF Radical Salts with [M(C2O4)3]3− Anions
# | CCDC | Formula a | SG b | Elect. Prop. | A+ | M | G | Ref. |
---|---|---|---|---|---|---|---|---|
55 | CISMEZ | κ′-(ET)4[KMn(ox)3]·PhCN | Pbcn | σ = 2 × 10−5 S/cm Ea = 180 meV | K+ | Mn | PhCN | [33] |
56 | FECDEZ | κ′-(ET)4[(NH4)Rh(ox)3]·PhCN | Pbcn | Ea = 245 meV | NH4+ | Rh | PhCN | [32] |
57 | JUPGUW | κ′-(ET)4[(H3O)Cr(ox)3]·PhCN | Pbcn | Ea = 153 meV | H3O+ | Cr | PhCN | [4,25] |
58 | QIWMOY | κ′-(ET)4[(NH4)Co(ox)3]·PhCN | Pbcn | Ea = 225 meV | NH4+ | Co | PhCN | [4] |
59 | QIWMUE | κ′-(ET)4[(NH4)Al(ox)3]·PhCN | Pbcn | Ea = 222 meV | NH4+ | Al | PhCN | [4] |
60 | UDETOO | κ′-(ET)4[K0.8(H3O)0.2Ru(ox)3]·PhCN | Pbcn | Semi | K+/H3O+ | Ru | PhCN | [31] |
61 | UJOXUN | κ′-(ET)4[(H3O)Fe(ox)3]·(PhCN)0.88(PhCl2)0.12 | Pbcn | Semi | H3O+ | Fe | PhCl2/PhCN | [17] |
62 | ZIWNEY | κ′-(ET)4[(NH4)Fe(ox)3]·PhCN | Pbcn | σ = 10−4 S/cm Ea = 140 meV | NH4+ | Fe | PhCN | [2,4] |
63 | ZIWNIC | κ′-(ET)4[KFe(ox)3]·PhCN | Pbcn | σ = 10−4 S/cm Ea = 140 meV | K+ | Fe | PhCN | [2] |
4. Other Phases with BEDT-TTF and Oxalato Complexes
4.1. BEDT-TTF Salts with [M(C2O4)3]3− Anions and 18-Crown-6
# | CCDC | Formula a | SG b | Elect. Prop. | A+ | M | G | Ref. |
---|---|---|---|---|---|---|---|---|
64 | ACAGUG | β″-(ET)4[(H3O)Cr(ox)3]2[(H3O)2(18-c-6)]·5H2O | P-1 | σ = 300 S/cm TMI = 190 K | H3O+ | Cr | H2O/18-c-6 | [34,35] |
65 | COLWUY | β″-(ET)2[(H2O)(NH4)2Ir(ox)3]·18-c-6 | P-1 | TMI ≈ 100 K | NH4+ | Ir | H2O/18-c-6 | [36] |
66 | COLYOU | β″-(ET)2[(H2O)(NH4)2Ru(ox)3]·18-c-6 | P-1 | TMI ≈ 155 K | NH4+ | Ru | H2O/18-c-6 | [36] |
67 | FENHEO | β″-(ET)2[(H2O)(NH4)2Cr(ox)3]·18-c-6 | P-1 | Tc = 4.0–4.9 K | NH4+ | Cr | H2O/18-c-6 | [37] |
68 | FEQQAU | β″-(ET)4[(NH4)Ga(ox)3]2[(NH4)2(18-c-6)]·5H2O | P-1 | σ = 200 S/cm TMI = 240 K | NH4+ | Ga | H2O/18-c-6 | [35] |
69 | KATLAV | β″-(ET)2[(H2O)(NH4)2Rh(ox)3]·18-c-6 | P-1 | Tc = 2.7 K | NH4+ | Rh | H2O/18-c-6 | [38] |
70 | NIHPEA | α-(ET)10(18-c-6)6K6[Fe(ox)3]4·24H2O | P21/c | Ea = 105 meV | K+ | Fe | H2O/18-c-6 | [39] |
71 | UJEYIR | (ET)4[Ga(ox)3](18-c-6)(H2O)6 | P-1 | - | - | Ga | H2O/18-c-6 | c |
4.2. BEDT-TTF Salts with [M(C2O4)3]3− Anions and Two Different Donor Layers
# | CCDC | Formula a | SG b | Elect. Prop. | A+ | M | G | Ref. |
---|---|---|---|---|---|---|---|---|
72 | AQUZUH | α,β″-(ET)4[(NH4)Ga(ox)3] ·PhN(CH3)CHO | P-1 | σ = 0.26–0.60 S/cm | NH4+ | Ga | PhN(CH3)CHO | [40] |
73 | ARABAW | α,β″-(ET)4[(NH4)Ga(ox)3] ·PhCH2CN | P-1 | σ = 0.24–1.34 S/cm | NH4+ | Ga | PhCH2CN | [40] |
74 | ARABEA | α,β″-(ET)4[(NH4)Fe(ox)3]·PhCOCH3 | P-1 | - | NH4+ | Fe | PhCOCH3 | [40] |
75 | CILDIL | α,β″-(ET)4[(NH4)Fe(ox)3] ·(S)-PhC(OH)HCH3 | P1 | σ = 5.3 S/cm TMI = 170 K | NH4+ | Fe | (S)-PhC(OH)OCH3 | [41] |
76 | HOBRIB | α,κ′-(ET)4K0.45(H3O)0.55[Ga(ox)3] ·1,2-PhBr2 | P-1 | Metal | K+/H3O+ | Ga | 1,2-PhBr2 | [30] |
77 | NIPTEM | α,β″-(ET)4[(NH4)Fe(ox)3] ·(R/S)-PhC(OH)HCH3 | P-1 | σ = 10.4 S/cm TMI = 150 K | NH4+ | Fe | (R/S)-PhC(OH)HCH3 | [41] |
78 | TANDIX | α,κ′-(ET)4[(H3O)Fe(ox)3]·1,2-PhBr2 | P-1 | M > 1.5 K | H3O+ | Fe | PhBr2 | [42] |
4.3. BEDT-TTF:[M(C2O4)3]3− Phases with 3:1 Stoichiometry
# | CCDC | Formula a | SG b | Elect. Prop. | A+ | M | G | Ref. |
---|---|---|---|---|---|---|---|---|
79 | BOYTIU | (ET)3[NaAl(ox)3]·CH3NO2 | P21 | Ea = 140 meV | Na+ | Al | CH3NO2 | [43] |
80 | BOYTOA | (ET)3[(NH4)0.83Cr1.17(ox)3]·CH3NO2 | P212121 | Ea = 140 meV | Na+ | Cr | CH3NO2 | [43] |
81 | DUDWUW | (ET)3[LiCr(ox)3]·EtOH | P21/c | Ea = 179 meV | Li+ | Cr | EtOH | [46] |
82 | DUDXAD | (ET)3[LiFe(ox)3]·EtOH | P21/c | Ea = 126 meV | Li+ | Fe | EtOH | [46] |
83 | DUXNOA | (ET)3[Na(Δ-Cr(ox)3)0.56(Λ-Cr(ox)3)0.44]·CH2Cl2 | P1 | Ea = 69 meV | Na+ | Cr | CH2Cl2 | [47] |
84 | KOGMUQ01 | (ET)3[NaCr(ox)3]·CH3CN | P21 | σ = 0.038 S/cmEa = 172 meV | Na+ | Cr | CH3CN | [44] |
85 | XUNXOU | (ET)3{Na[⊗-Cr(ox)3]0.64[Λ-Cr(ox)3]0.36}·CH3NO2 | P212121 | σ = 0.5 S/cm Ea = 80 meV | Na+ | Cr | CH3NO2 | [45] |
86 | XUNXOU01 | (ET)3[NaCr(ox)3]·CH3NO2 | P21 | σ = 0.045 S/cm Ea = 79 meV | Na+ | Cr | CH3NO2 | [45] |
87 | YUCLOZ | (ET)3[NaCr(ox)3]·EtOH | P1 | Semi | Na+ | Cr | EtOH | [44] |
88 | YUCLUF | θ-(ET)3[NaCr(ox)3]·dmf | P1 | Semi | Na+ | Cr | dmf | [44] |
4.4. Other Phases of BEDT-TTF Salts with [M(C2O4)3]3− Anions
# | CCDC | Formula a | SG b | Elect. Prop. | A+ | M | G | Ref. |
---|---|---|---|---|---|---|---|---|
89 | CIWNAA | α″-(ET)5[Ga(ox)3]·3.4H2O·0.6EtOH | Pbca | Ea = 71 meV | - | Ga | EtOH/H2O | [27] |
90 | DUDWOQ | η-(ET)4[(H2O)LiFe(ox)3] | P21/c | σ = 0.41 S/cm Ea = 80 meV | Li+/H2O | Fe | - | [46] |
91 | DUXNUG | α‴-(ET)9Na18[Cr(ox)3]8·24H2O | P-1 | Ea = 66 meV | Na+ | Cr | H2O | [47] |
92 | IPEKAQ | α-(ET)6[Fe(ox)3] | P21 | - | - | Fe | H2O/EtOH ? | [17] |
93 | KIVKAC | α-(ET)12[Fe(ox)3]2·15H2O | C2/c | σ = 0.055 S/cm | H3O+ | Fe | H2O | [51] |
94 | KIVKEG | α-(ET)12[Fe(ox)3]2·16H2O | C2/c | σ = 0.111 S/cm | H3O+ | Fe | H2O | [51] |
95 | NIHPAW | α‴-(ET)9Na18[Fe(ox)3]8·24H2O | P-1 | Ea = 77 meV | Na+ | Fe | H2O | [39] |
96 | OGUPAI | β″-(ET)5[Fe(ox)3](H2O)2CH2Cl2 | P-1 | σ = 4 S/cm Ea = 30 meV | - | Fe | CH2Cl2/H2O | [52] |
4.5. BEDT-TTF Salts with [Ge(C2O4)3]2− and [Cu(C2O4)2]2− Dianions
# | CCDC | Formula a | SG b | Elect. Prop. | G | Anion | Ref. |
---|---|---|---|---|---|---|---|
97 | MAJYUR | (ET)2[Ge(ox)3]·PhCN | P21/c | Ea = 127 meV | PhCN | [Ge(ox)3]2− | [53] |
98 | MUVFUF | (ET)5[Ge(ox)3]2 | C2 | σ = 10−3 S/cm Ea = 225 meV | - | [Ge(ox)3]2− | [54] |
99 | MUVGAM | (ET)7[Ge(ox)3]2·0.87CH2Cl2·0.09H2O | C2/c | σ = 1.75 S/cm Ea = 117–172 meV | CH2Cl2/H2O | [Ge(ox)3]2− | [54] |
100 | PADDOQ | (ET)4[Ge(ox)3].0.5CH2Cl2 | P21/c | σ = 4.7 × 10−3 S/cm Ea = 224 meV | CH2Cl2 | [Ge(ox)3]2− | [55] |
101 | SOJLUY | (ET)4[Cu(ox)2] | P-1 | TM-I = 65 K Ea = 15 meV | - | [Cu(ox)2]2− | [56,57] |
5. BEDT-TTF Salts with Oxalate Dimers and 2D Lattices
# | CCDC | Formula a | SG b | Elect. Prop. | Anion | G | Ref. |
---|---|---|---|---|---|---|---|
102 | CEMMUF | (ET)3[Cu2(ox)3]·CH2Cl2 | P-1 | - | [Cu2(ox)3]2− | CH2Cl2 | c |
103 | IPOZIY | (ET)2.53[MnCr(ox)3]·CH2Cl2 | P-1 | σ = 10 S/cm metal > 0.4 K | [MnCr(ox)3]− | CH2Cl2 | [8] |
104 | IPOZOE | (ET)2.53[MnRh(ox)3]·CH2Cl2 | P-1 | σ = 13 S/cm metal > 100 K | [MnRh(ox)3]− | CH2Cl2 | [8] |
105 | LOHWIO | (ET)4[Fe2(ox)5] | P21/n | σ = 2 × 10−3 S/cm Ea = 1200 meV | [Fe2(ox)5]4− | - | [58] |
106 | NALVIG | (ET)3[MnCr(ox)3] | P-1 | σ = 250 S/cm metal > 0.3 K | [MnCr(ox)3]2− | - | [7] |
107 | SAMMEA | (ET)3[Cu2(ox)3]·2CH3OH | P-1 | σ = 4 S/cm Ea = 50 meV | [Cu2(ox)3]2− | CH3OH | [62] |
108 | WUXWET | (ET)3[Cu2(ox)3]·2H2O | P-1 | - | [Cu2(ox)3]2− | H2O | c |
6. Radical Salts of Metal-Oxalate Anions with Other TTF-Type Donor Molecules
6.1. TTF and TM-TTF Salts with Oxalate Complexes
6.2. Salts with Se-Containing Donors (BEST and BETS)
6.3. Salts with Other Donors
# | CCDC | Formula a | SG b | Elect. Prop. | Donor c | G | Ref |
---|---|---|---|---|---|---|---|
109 | CEWMEX | (BEST)4[Cr(ox)3]·PhCOOH·H2O | P-1 | σ = 1.5 S/cm Ea = 49 meV | BEST | PhCOOHH2O | [68] |
110 | CEWMIB | (BEST)4[Fe(ox)3]·PhCOOH·H2O | P-1 | σ = 6.4 S/cm Ea = 54 meV | BEST | PhCOOHH2O | [68] |
111 | CEWMOH | (BEST)4[Cr(ox)3]·1.5H2O | C2/m | σ = 8.5 S/cm Ea = 62 meV | BEST | H2O | [68] |
112 | CEWMUN | (BEST)9[Fe(ox)3]2·7H2O | P-1 | σ = 2.4 S/cm Ea = 44 meV | BEST | H2O | [68] |
113 | CEWNAU | (BEST)4[Fe(ox)3]·1.5H2O | C2/m | σ = 14.0 S/cm Ea = 60 meV | BEST | H2O | [68] |
114 | DIQFOY | (TTF)7[Fe(ox)3]2·4H2O | P21/c | σ = 10−4 S/cm Ea = 279 meV | TTF | H2O | [59,60] |
115 | DIQFUE | (TTF)5[Fe2(ox)5]·2PhCH3·2H2O | C2/m | σ = 1.8 × 10−6 S/cm | TTF | PhCH3H2O | [59,60] |
116 | DIQGAL | (TMTTF)4[Fe2(ox)5]·PhCN·4H2O | P-1 | σ = 2.2 × 10−3 S/cm Ea = 290 meV | TMTTF | PhCNH2O | [59,60] |
117 | NIDDIP | (BETS)3[Cu2(ox)3]·2CH3OH | P-1 | M > 180 K | BETS | CH3OH | [69] |
118 | OLABAE | (TTF)3[Ru(ox)3]·0.5EtOH·4H2O | C2/c | σ = 1.5 × 10−4 S/cm Ea = 61 meV | TTF | EtOHH2O | [64] |
119 | RUDNOT02 | (BETS)3[MnCr(ox)3]·CH2Cl2 | P-1 | M > 150 K | BETS | CH2Cl2 | [70] |
120 | TUHDOP | (TTF)4{Mn(H2O)2[Cr(ox)3]2}·14H2O | C2/c | σ = 2 × 10−4 S/cm Ea = 200 meV | TTF | H2O | [65] [66] |
121 | VIPYUQ | (DMPET)4[Fe2(ox)5] | P21 | - | DMPET | - | [71] |
7. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Benmansour, S.; Gómez-García, C.J. The Peter Day Series of Magnetic (Super)Conductors. Magnetochemistry 2021, 7, 93. https://doi.org/10.3390/magnetochemistry7070093
Benmansour S, Gómez-García CJ. The Peter Day Series of Magnetic (Super)Conductors. Magnetochemistry. 2021; 7(7):93. https://doi.org/10.3390/magnetochemistry7070093
Chicago/Turabian StyleBenmansour, Samia, and Carlos J. Gómez-García. 2021. "The Peter Day Series of Magnetic (Super)Conductors" Magnetochemistry 7, no. 7: 93. https://doi.org/10.3390/magnetochemistry7070093