Difluorophosphate
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Systematic IUPAC name
Difluorophosphate[1] | |||
Identifiers | |||
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PubChem CID
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CompTox Dashboard (EPA)
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Properties | |||
PO 2F− 2 | |||
Molar mass | 100.97 g mol−1 | ||
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Difluorophosphate or difluorodioxophosphate or phosphorodifluoridate is an anion with formula PO
2F−
2. It has a single negative charge and resembles perchlorate (ClO−
4) and monofluorosulfonate (SO3F−) in shape and compounds.[2] These ions are isoelectronic, along with tetrafluoroaluminate, phosphate, orthosilicate, and sulfate.[2][3] It forms a series of compounds. The ion is toxic to mammals as it causes blockage to iodine uptake in the thyroid. However it is degraded in the body over several hours.[2]
Compounds containing difluorophosphate may have it as a simple uninegative ion, it may function as a difluorophosphato ligand where it is covalently bound to one or two metal atoms, or go on to form a networked solid.[4] It may be covalently bound to a non metal or an organic moiety to make an ester or an amide.
Formation
The ammonium salt of difluorophosphate is formed from treating phosphorus pentoxide with ammonium fluoride.[2] This was how the ion was first made by its discoverer, Willy Lange, in 1929.[3][5]
Alkali chlorides can react with dry difluorophosphoric acid to form alkali metal salts.[6]
- NaCl + HPO2F2 → NaPO2F2 + HCl (gas)
Fluoridation of dichlorophosphates can produce difluorophosphates.[7] Another method is fluorination of phosphates or polyphosphates.[5]
Trimethylsilyl difluorophosphate reacts with metal chlorides to give difluorophosphates.[8]
The anhydride phosphoryl difluoride oxide (P2O3F4) reacts with oxides such as UO3 to yield difuorophosphates.[9] Phosphoryl difluoride oxide also reacts with alkali fluorides to yield difluorophosphates.[10]
Properties
In ammonium difluorophosphate the difluorophosphate ion has these interatomic dimensions: P–O length 1.457 Å, P–F length 1.541 Å, O–P–O angle 118.7°, F–P–O 109.4° and F–P–F angle 98.6°. Hydrogen bonding from ammonium to oxygen atoms causes a change to the difluorophosphate ion in the ammonium salt. In potassium difluorophosphate the ion has dimensions: P–O length 1.470 Å, P–F length 1.575 Å, O–P–O angle 122.4°, F–P–O 108.6° and F–P–F angle 97.1°.[11]
On heating the salts that are not of alkali or alkaline earths, difluorophosphates decompose firstly by giving off POF3 forming a monofluorophosphate (PO3F2−) compound, and then this in turn decomposes to an orthophosphate PO3−
4 compound.[12][13]
Difluorophosphate salts are normally soluble and stable in water. However, in acidic or alkaline conditions they can be hydrolyzed to monofluorophosphates and hydrofluoric acid.[14] The caesium and potassium salts are the least soluble.[14]
Irradiating potassium difluorophosphate with gamma rays can make the free radicals PO2F•−, PO3F•− and PO
2F•
2.[15][16]
Compounds
formula | structure | infrared | melting point °C[17] | reference | comment |
---|---|---|---|---|---|
LiPO2F2 | 360 | [5][6] | |||
Be(PO2F2)2 | >400d | [17] | prepared from BeCl2 and acid | ||
C2H5OPOF2 | [18] | ||||
NH4PO2F2 | Orthorhombic a=8·13, b=6·43, c=7·86 Å Z=4 space group Pnma | P-F stretching 842 860 cm−1;P-O stretching 1138 1292 cm−1 | 213 | [6][11] | |
NO2PO2F2 | 515, 530, 550, 560, 575, 845, 880, 1145, 1300, 2390, 3760 cm−1 | [19] | nitronium formed from anydride and N2O5 | ||
NOPO2F2 | 500, 840, 880, 1130, 1272, 1315, 2278 cm−1 | [19] | nitrosonium formed from anydride and N2O3 | ||
NaPO2F2 | 210 | [6] | |||
Mg(PO2F2)2 | 200 | [5] | |||
Al(PO2F2)3 | 1290 1200 971 918 642 582 541 505 cm−1 355(impurity) | [7][8] | Formed from AlEt3 and acid. Colourless insoluble powder. Polymeric.[4] | ||
Si(OPOF2)4 | [18] | formed from SiCl4 and anhydride | |||
(CH3)Si3OPOF2 | [4][18] | formed from anhydride and [(CH3)3Si]2O | |||
KPO2F2 | Orthorhombic a=8.03 b=6.205 c=7.633 Å Z=4 V=380.9 Å3 density=2.44 | 510, 525, 570, 835, 880, 1145, 1320, 1340 cm−1 | 263 | [6][11][19][20][21] | colourless elongated prisms |
K4(PO2F2)2(S2O7) | C2/c a = 13.00, b = 7.543, c = 19.01, β = 130.07°, Z = 4 | [22] | |||
Ca(PO2F2)2•CH3COOCH2CH3 | [23] | ||||
Ca(PO2F2)2 | >345d | [5] | |||
VO2PO2F2 | [9] | ||||
CrO2(PO2F2)2 | [24] | formed from anhydride;red-brown | |||
Cr(PO2F2)3 | 320 385 490 575 905 955 1165 1255 cm−1 | [24] | formed from excess anhydride, green | ||
Mn(CO)5PO2F2 | 184 | [25] | |||
HMn(PO2F2)3 | [26] | dissolve manganese in acid; white | |||
(NH4)Mn3(PO2F2)(PO3F)2F2 | [27] | ||||
Fe(PO2F2)2 | 1290 1139 869(double) 668(weak) 496 463 cm−1 | 180d | [12] | colour blue green, hygroscopic, melts 250 °C, above 300 °C starts decomposing to Fe3(PO4)2 | |
Fe(PO2F2)3 | 1242 1173 965 914 570 528 493 262 cm−1 | >400 | [7] | decomposes at 230 °C yielding FeF3; dissolve iron in acid in presence of oxygen | |
KFe2(PO2F2)(PO3F)2F2 | [27] | ||||
Co(PO2F2)2 | 173 | [17] | prepared from CoCl2 and acid; pink or blue; blue formed by heating pink to 140 °C | ||
HCo(PO2F2)3 | [26] | dissolve cobalt in acid; red-purple | |||
Co(PO2F2)2•2CH3CN | molw weight=342.9 orthorhombic a=9.227 Å b=13.871 Å c=9.471 Å V=1212 Å3 Z=4 density=1.88 | [28] | treat HCo(PO2F2)3 with MeCN for a few weeks; red crystals | ||
(NH4)Co3(PO2F2)(PO3F)2F2 | [27] | ||||
Ni(PO2F2)2 | 255d | [17] | slowly prepared from NiCl2 and acid; yellow | ||
HNi(PO2F2)3 | [26] | dissolve nickel in acid; yellow | |||
Cu(PO2F2)2 | MW=265.5 orthorhombic Fddd a=10.134 Å b=24.49 Å c=34.06 Å Z=48 V=8454.3 Å3 density=2.50 | 265d | [5][28] | pale blue needles | |
CuI(xantphos)2(μ-PO2F2) | monoclinic a=12.435 b=10.887 c=25.682 β=100.220 V=3421 Å3 | [29] | polymer colourless | ||
Zn(PO2F2)2 | ?room temp | [5] | glassy | ||
ZnH2(PO2F2)4 | [8] | ||||
Ga(PO2F2)3 | [30] | ||||
[(CH3)2GaPO2F2]2 | 380 492 520 551 616 709 750 899 949 1171 1218 1262 1295 1404 2922 2982 | [4][31] | dimer | ||
RbPO2F2 | Orthorhombic a=8·15, b=6·45, c=7·79 Å Z=4 V=409.5 Å3 density=3.02 | P-F stretching 827 946 cm−1;P-O stretching 1145 1320 cm−1 | 160 | [6][11][20] | white |
Sr(PO2F2)2 | 250d | [17] | prepared from SrCl2 and acid | ||
Ag PO2F2 | [32] | ||||
Ag9(PO2F2)14 | [27] | ||||
Ag (1-Methyl-2-(alkylthiomethyl)-1H-benzimidazole)PO2F2 | [32] | ||||
Ag (2,6-bis-[(2-methylthiophenyl)-2-azaethenyl]pyridine)PO2F2 | Triclinic P1 a=7.687 b=10.740, c=13.568 Å, α=99.52°, β=96.83°, γ=99.83°, Z=2, V=1076 Å3 | [33] | mol weight=585.37 density 1.81 | ||
4,4'-Dicyanodiphenylacetylene AgPO2F2 | |||||
Cd(PO2F2)2 | 245d | [5] | |||
In(PO2F2)3 | 1269 1179 962 910 567 528 492 269 cm−1 | [7] | white decomposes at 260 °C yielding InF3 | ||
[(CH3)2InPO2F2]2 | 373 490 500 535 559 735 878 925 1128 1179 1275 1435 2928 3000 | [31] | dimer | ||
SnCl2(PO2F2)2 | [34] | ||||
(CH3)2Sn(PO2F2)2 | 204d | [17] | prepared from (CH3)2SnCl2 and acid; yellow | ||
(C2H5)2Sn(PO2F2)2 | 262d | [17] | prepared from (C2H5)2SnCl2 and acid; yellow | ||
(n-C3H7)2Sn(PO2F2)2 | 245d | [17] | prepared from (n-C3H7)2SnCl2 and acid; yellow | ||
(n-C4H9)2Sn(PO2F2)2 | 235d | [17] | prepared from (n-C4H9)2SnCl2 and acid; yellow | ||
(n-C8H17)2Sn(PO2F2)2 | 114 | [17] | prepared from (n-C8H17)2SnCl2 and acid; yellow | ||
SbCl4PO2F2 | [34] | ||||
SbF4PO2F2 | [34] | ||||
(2,2-dipyradyl)2Re(CO)2PO2F2 | [35] | ||||
Bis(triphenylphosphine sulfide-S)gold(I) Difluorophosphate | [36] | ||||
IO2PO2F2 | Raman: 1163, 918 839, 799, 781, 737, 713, 637, 378, 329, 323, 295, 219, 191, 163, 130 cm−1 | [37] | yellowish colour, produced from IO3, decomposed by water | ||
IO3PO2F2 | Raman: 1123, 891, 797, 717, 671, 643, 569, 473, 395, 367, 343, 305, 269, 247, 217 cm−1 | [37] | yellowish colour, produced from H5IO6, decomposed by water | ||
FXePO2F2 | [38] | ||||
Xe(PO2F2)2 | [38] | ||||
CsPO2F2 | Orthorhombic a=8·437, b=6·796, c=8·06 Å Z=4 V=462.1 Å3 density=3.36 | 286 | [6][11][20] | ||
Cs2Fe2(PO2F2)(PO2F)2F3 | [27] | ||||
Ba(PO2F2)2 | >400 | [5] | |||
Re(CO)5PO2F2 | [35] | ||||
Hg(PO2F2)2 | [5] | ||||
Hg2(PO2F2)2 | Raman: 220 cm−1 | [5] | produced from anydride | ||
TlPO2F2 | [5] | produced from andhydride, or acid on TlCl | |||
[(CH3)2TlPO2F2]2 | 360 374 500 505 520 559 850 880 1120 1140 1195 1250 1285 2932 3020 | [31] | dimer | ||
Pb(PO2F2)2 | 189d | [5] | |||
UO2(PO2F2)2 | 1124 980 924 854 498 260 cm−1 | [9] | IR spectrum due to UO22+ | ||
(C2H5)4NPO2F2 | [39] | ||||
1-ethyl-3-methylimidazolium difluorophosphate | [40] | ionic liquid | |||
1-butyl-3-methylimidazolium difluorophosphate | [40] | ionic liquid | |||
1-butyl-1-methylpyrrolidinium difluorophosphate | [40] | ionic liquid | |||
1-butyl-1-methylpiperidinium difluorophosphate | [40] | ionic liquid | |||
Di(3,3',4,4'-tetramethyl-2,2',5,5'-tetraselenafulvalenium)difluorophosphate | [41] | Transitions to a metallic state below 137K | |||
1,4-diphenyl-3,5-enanilo-4,5-dihydro-1,2,4-triazole (nitron) | monoclinic P21/n a=7.3811 b=14.9963 c=
16.922 β=102.138 V=1361.2 Z=4 |
[2][27] | insoluble; yellow-brown | ||
Strychnine PO2F2 | [3] | ||||
Cocaine PO2F2 | [3] | ||||
Brucine PO2F2 | [3] | ||||
Morphine PO2F2 | [3] | ||||
N(CH3)4 PO2F2 | [3] | ||||
HB(PO2F2)4 | 469 502 552 647 836 940 994 1093 1348 1567 cm−1 | [4] | formed from BBr3 and acid; liquid | ||
LiB(PO2F2)4 | monoclinic P21/c a=7.9074 Å b=14.00602 Å c=13.7851 Å β=121.913° Z=4 | 479 502 568 833 945 1002 1080 1334 cm−1 | [4] | formed from HB(PO2F2)4 and butyl lithium; colourless | |
HS(CH3)2B(PO2F2)4 | 472 511 555 648 832 933 993 1082 1337 1436 2851 2921 3042 cm−1 | [4] | formed from BH3•S(CH3)2 and acid; ionic liquid | ||
[LiEtOEt]3Al(PO2F2)6 | trigonal R3 a=17.4058 Å b=17.4058 Å c=21.4947 Å γ=120° Z=6 | 417 503 536 624 723 891 922 964 1174 1204 1283 cm−1 | [4] | formed from butyl lithium and triethyl aluminium and the acid; white | |
K2CrO2(PO2F2)4 | 305 370 485 550 870 920 1050 1130 1250 cm−1 | [24] | formed from anhydride and K2CrO4; brown; dec 145° | ||
Na2MoO2(PO2F2)4 | 280 490 620 880 915 950 1020 1070 1140 1280 cm−1 | [24] | formed from anhydride and K2MoO4; white; dec 125 °C; amorphous | ||
Na2WO2(PO2F2)4 | 280 474 620 930 1030 1130 1230 cm−1 | [24] | formed from anhydride and K2WO4; white; dec 109 °C amorphous |
Related substances
Difluorphosphoric acid
Difluorphosphoric acid (HPO2F2) is one of the fluorophosphoric acids. It is produced when phosphoryl fluoride reacts with water. POF3 + H2O → HPO2F2 + HF. This in turn is hydrolysed more to give monofluorophosphoric acid (H2PO3F), and a trace of hexafluorophosphoric acid (HPF6). HPO2F2 also is produced when HF reacts with phosphorus pentoxide. Yet another method involves making difluorphosphoric acid as a side product of calcium fluoride being heated with damp phosphorus pentoxide. A method to make pure difluorphosphoric acid involves heating phosphoryl fluoride with monofluorophosphoric acid and separating the product by distillation. POF3 + H2PO3F → 2HPO2F2.[42]
Difluorophosphoric acid can also be produced by fluorinating phosphorus oxychlorides. P2O3Cl4 and POCl3 react with hydrogen fluoride solution to yield HPO2Cl2 and then HPO2F2.[43] Yet another way is to treat orthophosphate (PO3−
4) with fluorosulfuric acid (HSO3F).[44]
Difluorphosphoric acid melts at −96.5 °C and boils at 115.9 °C. Its density at 25 °C is 1.583.[14]
Phosphoryl difluoride oxide
Difluorophosphoric acid anhydride also known as phosphoryl difluoride oxide or diphosphoryl tetrafluoride (F2OPOPOF2 or P2O3F4) is an anhydride of difluorphosphoric acid. It crystallises in the orthorhombic system, with space group Pcca and Z = 4.[45] P2O3F4 can be made by refluxing difluorophosphoric acid with phosphorus pentoxide. P2O3F4 boils at 71 °C.[46]
Substitution
In addition to the isoelectronic series, ions related by substituting fluorine or oxygen by other elements include monofluorophosphate, difluorothiophosphate, dichlorothiophosphate, dichlorophosphate, chlorofluorothiophosphate, chlorofluorophosphate, dibromophosphate, and bromofluorophosphate.[47]
Adducts
Difluorophosphate can form adducts with PF5 and AsF5. In these the oxygen atoms form a donor-acceptor link between the P and As (or P) atoms, linking the difluorides to the pentafluorides. Example salts include KPO2F2·2AsF5, KPO2F2·AsF5, KPO2F2·2PF5 and KPO2F2·PF5.[48]
Amines can react with phosphoryl fluoride to make substances with a formula RR′N–POF2. The amines shown to do this include ethylamine, isopropylamine, n-butylamine, tert-butylamine, dimethylamine, and diethylamine. The monoamines can further react to yield an alkyliminophosphoricfluoride (RN=POF).[49]
References
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