Carbonate chloride

The carbonate chlorides are double salts containing both carbonate and chloride anions. Quite a few minerals are known. Several artificial compounds have been made. Some complexes have both carbonate and chloride ligands. They are part of the family of halocarbonates. In turn these halocarbonates are a part of mixed anion materials.

The carbonate chlorides do not have a bond from chlorine to carbon, however "chlorocarbonate" has also been used to refer to the chloroformates which contain the group ClC(O)O-.

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Formation

Natural

Scapolite is produced in nature by metasomatism, where hot high pressure water solutions of carbon dioxide and sodium chloride modify plagioclase.^[1]

Chloroartinite is found in Sorel cements exposed to air.^[2]

Minerals

In 2016 27 chloride containing carbonate minerals were known.^[3]

name	formula	crystal system	space group	unit cell	density	Optics refractive index	Raman spectrum	comments	reference
Alexkhomyakovite	K₆(Ca₂Na)(CO₃)₅Cl∙6H₂O	hexagonal	P6₃/mcm	a=9.2691, c=15.8419, V=1178.72 Z = 2	2.25	uniaxial (–), ω=1.543, ε=1.476			^[4]
Ashburtonite	HPb₄Cu₄(Si₄O₁₂)(HCO₃)₄(OH)₄Cl								^[3]
Balliranoite	(Na,K)₆Ca₂(Si₆Al₆O₂₄)Cl₂(CO₃)	hexagonal	P6₃	a=12.695 c=5.325 V=743.2 Z=1	2.48	uniaxial (+), ω=1.523, ε=1.525			^[5]
Barstowite	Pb₄(CO₃)Cl₆.H₂O
Chlorartinite	Mg₂(CO₃)Cl(OH).3H₂O
Chlormagaluminite	(Mg,Fe²⁺)₄Al₂(OH)₁₂(Cl, 0.5 CO₃)₂·2H₂O		6/mmm		1.98-2.09	ε=1.560 ω=1.540			^[6]
Davyne								can substitute CO3 for SO4	^[7]
Decrespignyite-(Y)	Y₄Cu(CO₃)₄Cl(OH)₅·2H₂O						V4 bending 694, 718 and 746; V2 bending 791, 815, 837 and 849;v3 antisymmetric stretching 1391, 1414, 1489, 1547; also OH stretching^[8]	light blue	^[9]
Defernite	Ca₃CO₃(OH,Cl)₄.H₂O
Hanksite	Na₂₂K(SO₄)₉(CO₃)₂Cl	hexagonal	P6₃/m	a = 10.46 Å c = 21.19 Å; Z = 2
iowaite	Mg₆Fe₂(Cl,(CO₃)_0.5)(OH)₁₆·4H₂O								^[10]
Kampfite	Ba₁₂(Si₁₁Al₅)O₃₁(CO₃)₈Cl₅	monoclinic	Cc	a = 31.2329, b=5.2398, c=9.0966 β = 106.933°		uniaxial (–), n_ω = 1.642 n_ε = 1.594			^[11]
Marialite	Na₄(AlSi₃O₈)₃(Cl₂,CO₃,SO₄)
Mineevite-(Y)	Na₂₅BaY₂(CO₃)₁₁(HCO₃)₄(SO₄)₂F₂Cl								^[12]
Northupite	Na₃Mg(CO₃)₂Cl	octahedral	Fd3	Z=16		1.514	v4 bending 714; v3 antisymmetric stretching 1554^[8]		^[13]^[14]
Phosgenite	Pb₂CO₃Cl₂	tetragonal		a=8.15 c=8.87					^[13]
Reederite-(Y)	Na15Y2(CO3)9(SO3F)Cl								^[12]
Sakhaite (with Harkerite)	Ca₄₈Mg₁₆Al(SiO₃OH)₄(CO₃)₁₆(BO₃)₂₈·(H₂O)₃(HCl)₃or Ca₁₂Mg₄(BO₃)₇(CO₃)₄Cl(OH)₂·H₂O								^[3]
Scapolite	Ca₃Na₅[Al₈Si₁₆O₄₈]Cl(CO₃)		P4₂/n	a=12.07899 c=7.583467 V=1106.443					^[15]
Tatarskite	Ca₆Mg₂(SO₄)₂(CO₃)₂(OH)₄Cl₄•7H₂O	orthorhombic				Biaxial (-) nα = 1.567 nβ = 1.654 nγ = 1.722			^[16]
Tunisite	NaCa₂Al₄(CO₃)₄Cl(OH)₈	tetragonal	P4/nmm	a=11.198 c=6.5637 Z=2
Vasilyevite	(Hg₂)₁₀O₆I₃Br₂Cl(CO₃)		P1 overbar	a 9.344, b 10.653, c 18.265, α=93.262 β=90.548 γ=115.422° V=1638.3 Z=2	9.57

Artificial

name	formula		crystal system	space group	unit cell in Å	density	comment	reference
	K₅Na₂Cu₂₄(CO₃)₁₆Cl₃(OH)₂₀•12H₂O		cubic	F23	a=15.463 V=3697.5 Z=2	3.044	dark blue	^[17]
	Y₈O(OH)₁₅(CO₃)₃Cl	1197.88	hexagonal	P6₃	a=9.5089 c=14.6730 Z=2 V=1148.97	3.462		^[18]
	Lu₈O(OH)₁₅(CO₃)₃Cl	1886.32	hexagonal	P6₃	a=9.354 c=14.415 V=1092.3 Z=2	5.689	colourless	^[19]
	Y₃(OH)₆(CO₃)Cl		cubic	Im3m	a=12.66 V=2032 Z=8	3.035	colourless	^[20]
	Dy₃(OH)₆(CO₃)Cl		cubic	Im3	a=12.4754 V=1941.6 Z=8	4.687	colourless	^[20]
	Er₃(OH)₆(CO₃)Cl		cubic	Im3m	a=12.4127 V=1912.5 Z=8	4.857	pink	^[20]
	K{Mg(H₂O)₆}₂[Ru₂(CO₃)₄Cl₂]·4H₂O	889.06	monoclinic	P2₁/c	a=11.6399 b=11.7048 c=11.8493 β=119.060 V=1411.6 Z=2	2.092	red-brown	^[21]
	K₂[{Mg(H₂O)₄}2Ru₂(CO₃)₄(H₂O)Cl]Cl₂·2H₂O	880.58	orthorhombic	Fmm2	a=14.392 b=15.699 c=10.741 V=2426.8 Z=4	2.391	dark brown	^[21]
trisodium cobalt dicarbonate chloride	Na₃Co(CO₃)₂Cl		cubic	Fd3	a=13.9959 Z=16	2.75	spin-frustrated antiferromagnetic	^[3]^[22]
trisodium manganese dicarbonate chloride	Na₃Mn(CO₃)₂Cl		cubic		a=14.163		brown	^[23]
di-magnesium hexahydrate trihydrogencarbonate chloride	Mg₂(H₂O)₆(HCO₃)₃Cl			R3c	a=8.22215 c=39.5044 V=2312.85 Z=6	1.61	decompose 125 °C	^[2]
tripotassium tricalcium selenite tricarbonate chloride	K₃Ca₃(SeO₃)(CO₃)₃Cl	579.97	hexagonal	P6₃	a=10.543 c=7.060 V=706.0 Z=2	2.991		^[24]
	LiBa₉[Si₁₀O₂₅]Cl₇(CO₃)				Z=2	3.85	layer silicate	^[25]^[26]
	Ba₃Cl₄CO₃		orthorhombic	Pnma	a=8.407, b=9.589, c=12.483 Z=4			^[27]

Complexes

The "lanthaballs" are lanthanoid atom clusters held together by carbonate and other ligands. They can form chlorides. Examples are [La₁₃(ccnm)₆(CO₃)₁₄(H₂O)₆(phen)₁₈] Cl₃(CO₃)·25H₂O where ccnm is carbamoylcyanonitrosomethanide and phen is 1,10-phenanthroline. Praseodymium (Pr) or cerium (Ce) can substitute for lanthanum (La).^[28] Other lanthanide cluster compounds include :(H₃O)₆[Dy₇₆O₁₀(OH)₁₃₈(OAc)₂₀(L)₄₄(H₂O)₃₄]•2CO₃•4 Cl₂•L•2OAc (nicknamed Dy₇₆) and (H₃O)₆[Dy₄₈O₆(OH)₈₄(OAc)₄(L)₁₅(hmp)₁₈(H₂O)₂₀]•CO₃•14Cl•2H₂O (termed Dy₄₈-T) with OAc=acetate, and L=3-furancarboxylate and Hhmp=2,2-bis(hydroxymethyl)propionic acid.^[29]

Platinum can form complexes with carbonate and chloride ligands, in addition to an amino acid. Examples include the platinum compound [Pt(gluH)Cl(CO₃)]₂.2H₂O gluH=glutamic acid, and Na[Pt(gln)Cl₂(CO₃)].H₂O gln=glutamine.^[30] Rhodium complexes include Rh₂(bipy)₂(CO₃)₂Cl (bipy=bipyridine)^[31]

References

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