X-Ray Diffraction Table

Minerals Arranged by X-Ray Powder Diffraction

Powder X-ray Diffraction (XRD) is one of the primary techniques used by mineralogists and solid state chemists to examine the physico-chemical make-up of unknown materials. This data is represented in a collection of single-phase X-ray powder diffraction patterns for the three most intense D values in the form of tables of interplanar spacings (D), relative intensities (I/Io), mineral name and chemical formulae

The XRD technique takes a sample of the material and places a powdered sample in a holder, then the sample is illuminated with x-rays of a fixed wave-length and the intensity of the reflected radiation is recorded using a goniometer. This data is then analyzed for the reflection angle to calculate the inter-atomic spacing (D value in Angstrom units - 10^-8 cm). The intensity(I) is measured to discriminate (using I ratios) the various D spacings and the results are compared to this table to identify possible matches. Note: 2 theta (Θ) angle calculated from the Bragg Equation, 2 Θ = 2(arcsin(n λ/(2d)) where n=1

For more information about this technique, see X-Ray Analysis of a Solid or take an internet course at Birkbeck College On-line Courses. Many thanks to Frederic Biret for these data.

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Selected X-Ray λ	Change X-Ray λ	D₁ Å	D₂ Å	D₃ Å	Tolerance %	Elements

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**Found 29 Records, Sorted by D₁ using 1.54056 - CuKa1 for 2θ** WHERE (d1 > 13.0242 AND d1 < 13.5558)
D₁ Å (2θ)	I₁ %)	D₂ Å (2θ)	I₂ (%)	D₃ Å (2θ)	I₃ (%)	Mineral	Formula
13.040(6.77)	200	12.060(7.32)	160	6.010(14.73)	100	Liroconite	Cu2Al(AsO4)(OH)4·4(H2O)
13.040(6.77)	200	6.510(13.59)	80	8.100(10.91)	80	Wooldridgeite	Na2CaCu++2(P2O7)2·10(H2O)
13.040(6.77)	200	5.060(17.51)	160	5.800(15.26)	120	Murunskite	K2Cu3FeS4
13.050(6.77)	200	7.078(12.50)	160	8.774(10.07)	120	Delrioite	CaSrV2O6(OH)2·3(H2O)
13.060(6.76)	200	19.860(4.45)	190	8.480(10.42)	110	Stercorite	H(NH4)Na(PO4)·4(H2O)
13.078(6.75)	200	6.338(13.96)	180	14.080(6.27)	160	Wheatleyite	Na2Cu(C2O4)2·2(H2O)
13.080(6.75)	200	6.540(13.53)	100	9.560(9.24)	80	Calkinsite-(Ce)	(Ce,La)2(CO3)3·4(H2O)
13.100(6.74)	200	6.840(12.93)	160	6.460(13.70)	140	Tombarthite-(Y)	Y4(Si,H4)4O12-x(OH)4+2x
13.100(6.74)	200	8.780(10.07)	90	11.800(7.49)	70	Rhodesite	KHCa2Si8O19·5(H2O)
13.120(6.73)	200	6.240(14.18)	140	7.060(12.53)	100	Carnotite	K2(UO2)2V2O8·3(H2O)
13.140(6.72)	200	10.270(8.60)	60	13.940(6.34)	50	Tunellite	SrB6O9(OH)2·3(H2O)
13.140(6.72)	200	6.566(13.47)	110	8.000(11.05)	100	Montroyalite	Sr4Al8(CO3)3(OH,F)26·10-11(H2O)
13.160(6.71)	200	5.960(14.85)	60	6.360(13.91)	52	Annabergite	Ni3(AsO4)2·8(H2O)
13.200(6.69)	200	6.320(14.00)	80	4.004(22.18)	40	Lakebogaite	CaNaFe+++2H(UO2)2(PO4)4(OH)2(H2O)8
13.234(6.67)	200	7.424(11.91)	160	8.232(10.74)	160	Anorthominasragrite	V++++O(SO4)(H2O)5
13.248(6.67)	200	5.844(15.15)	144	9.636(9.17)	122	Arupite	(Ni,Fe++)3(PO4)2·8(H2O)
13.320(6.63)	200	5.440(16.28)	140	6.280(14.09)	100	Hydrozincite	Zn5(CO3)2(OH)6
13.340(6.62)	200	5.382(16.46)	140	5.896(15.01)	140	Pakhomovskyite	Co3(PO4)2·8(H2O)
13.360(6.61)	200	11.820(7.47)	160	6.012(14.72)	140	Tinsleyite	KAl2(PO4)2(OH)·2(H2O)
13.384(6.60)	200	5.424(16.33)	100	6.010(14.73)	100	Hornesite	Mg3(AsO4)2·8(H2O)
13.400(6.59)	200	17.220(5.13)	160	8.320(10.62)	120	Bijvoetite-(Y)	(Y,REE)8(H2O)25(UO2)16O8(OH)8(CO3)16·14(H2O)
13.400(6.59)	200	7.360(12.01)	160	7.440(11.89)	160	Gebhardite	Pb8(As+++2O5)2OCl6
13.406(6.59)	200	6.448(13.72)	70	15.908(5.55)	54	Kottigite	Zn3(AsO4)2·8(H2O)
13.420(6.58)	200	5.398(16.41)	140	5.912(14.97)	120	Baricite	(Mg,Fe++)3(PO4)2·8(H2O)
13.420(6.58)	200	6.712(13.18)	184	10.720(8.24)	170	Hungchaoite	MgB4O5(OH)4·7(H2O)
13.420(6.58)	200	9.720(9.09)	80	17.180(5.14)	80	Metavivianite	(Fe++3-x,Fe+++x)(PO4)2(OH)x·8-x(H2O), x=0.5
13.440(6.57)	200	6.006(14.74)	94	6.454(13.71)	84	Erythrite	Co3(AsO4)2·8(H2O)
13.460(6.56)	200	7.440(11.89)	180	8.320(10.62)	120	Astrocyanite-(Ce)	Cu2(Ce,Nd,La)2(UO2)(CO3)5(OH)2·1.5(H2O)
13.500(6.54)	200	6.050(14.63)	100	16.114(5.48)	60	Parasymplesite	Fe++3(AsO4)2·8(H2O)

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