Crystal structure of barium perchlorate anhydrate, Ba(ClO4)2, from laboratory X-ray powder data

Lee, J.H.; Kang, J.H.; Lim, S.-C.; Hong, S.-T.

doi:10.1107/S2056989015008828

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Volume 71| Part 6| June 2015| Pages 588-591

doi:10.1107/S2056989015008828

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Crystal structure of barium perchlorate anhydrate, Ba(ClO₄)₂, from laboratory X-ray powder data

Jeonghoo H. Lee,^a Ji Hoon Kang,^a Sung-Chul Lim ^a and Seung-Tae Hong ^a ^*

^aDaegu Gyeongbuk Institute of Science & Technology (DGIST), Daegu 711-873, Republic of Korea
^*Correspondence e-mail: st.hong@dgist.ac.kr

Edited by V. V. Chernyshev, Moscow State University, Russia (Received 24 April 2015; accepted 6 May 2015; online 9 May 2015)

The previously unknown crystal structure of barium perchlorate anhydrate, determined and refined from laboratory X-ray powder diffraction data, represents a new structure type. The title compound was obtained by heating hydrated barium perchlorate [Ba(ClO₄)₂·xH₂O] at 423 K in vacuo for 6 h. It crystallizes in the orthorhombic space group Fddd. The asymmetric unit contains one Ba (site symmetry 222 on special position 8a), one Cl (site symmetry 2 on special position 16f) and two O sites (on general positions 32h). The structure can be described as a three-dimensional polyhedral network resulting from the corner- and edge-sharing of BaO₁₂ polyhedra and ClO₄ tetrahedra. Each BaO₁₂ polyhedron shares corners with eight ClO₄ tetrahedra, and edges with two ClO₄ tetrahedra. Each ClO₄ tetrahedron shares corners with four BaO₁₂ polyhedra, and an edge with the other BaO₁₂ polyhedron.

Keywords: crystal structure; powder diffraction; Ba(ClO₄)₂; barium perchlorate anhydrate.

CCDC reference: 1063587

1. Chemical context

The alkaline earth metal ions (Mg, Ca, Sr and Ba) have been of increasing interest as ion carriers for post Li ion batteries (Wang et al., 2013 ), and their perchlorates are often used as conventional organic electrolyte salts for electrochemical cells such as magnesium (Amatucci et al., 2001 ; Levi et al., 2010 ) and calcium ion batteries (Padigi et al., 2015 ). Since such salts adsorb water easily from the atmosphere and the water causes unwanted side reactions in the electrochemical cells, removing water from the salts and its confirmation before use would be very important. However, due to the difficulty in growing a single crystal of such anhydrous perchlorates, no crystal structure had ever been solved before we first identified the magnesium perchlorate structure from powder X-ray diffraction data (Lim et al., 2011 ). Barium perchlorate is a very strong oxidizing agent due to the high oxidation state of chlorine VII, and it is commonly stabilized as hydrate forms in the atmosphere. Several different forms of the hydrates are expected to exist, as observed in the magnesium analogues (Robertson & Bish, 2010 ; West, 1935 ). The crystal structure of the trihydrate form was determined from single-crystal data (Gallucci & Gerkin, 1988 ), but the anhydrous form, Ba(ClO₄)₂, has not been reported to date. We present here its crystal structure, as determined and refined from laboratory powder X-ray diffraction data (Fig. 1). This is the second crystal structure reported among the anhydrate alkaline earth metal perchlorates.

Figure 1
X-ray Rietveld refinement profiles for Ba(ClO₄)₂ recorded at room temperature. Crosses mark experimental points (red) and the solid line is the calculated profile (green). The bottom trace shows the difference curve (purple) and the ticks denote expected peak positions.

2. Structural commentary

Anhydrous Ba(ClO₄)₂ crystallizes in a new structure type in terms of atomic ratios (1:2:8) and its polyhedral network is, to our knowledge, unique. The asymmetric unit contains one Ba (site symmetry 222 on special position 8a), one Cl (site symmetry 2 on special position 16f) and two O sites (on general positions 32h). The crystal structure is illustrated in Fig. 2, where two different views along [010] and [001] are presented for better visualization. The crystal structure is represented with ClO₄ tetrahedra and Ba atoms in Fig. 2a and 2b. The local environment around the Ba atom is presented in Fig. 3. It is clearly seen that there are chains of [(ClO₄)–Ba–(ClO₄)]_∞ parallel to the b-axis direction. Along each chain, the barium atom is placed between the two ClO₄ tetrahedra, bonded to two oxygen atoms at each tetrahedron. The [010] view in Fig. 2a clearly shows the two-dimensional arrangement of the chains. The chains are interconnected through Ba—O bonds. Each chain is surrounded by six neighboring ones that are shifted parallel to b-axis in such a way that a barium atom of the central chain is connected to the oxygen atoms of eight ClO₄ tetrahedra of six neighboring chains. Four tetrahedra are from four chains, one from each. The other four tetrahedra are from two other chains, two from each. The structure may also be described as a three-dimensional polyhedral network resulting from the corner- and edge-sharing of BaO₁₂ polyhedra and ClO₄ tetrahedra. Each BaO₁₂ polyhedron shares corners with eight ClO₄ tetrahedra, and edges with two ClO₄ tetrahedra. Each ClO₄ tetrahedron shares corners with four BaO₁₂ polyhedra, and an edge with the other BaO₁₂ polyhedron. The oxygen atoms in a ClO₄ tetrahedron consist of two O1 and two O2 ones. O1 is bonded to three atoms, one Cl and two Ba atoms, forming an almost planar environment. On the other hand, O2 is bonded to only two atoms, Cl and Ba. Selected bond lengths are given in Table 1.

Table 1
Selected bond lengths (Å)

Ba1—O1	2.901 (4)	Ba1—O2ⁱⁱⁱ	2.903 (4)
Ba1—O1ⁱ	2.939 (4)	Cl1—O1	1.441 (4)
Ba1—O1ⁱⁱ	2.901 (4)	Cl1—O2	1.437 (4)
Symmetry codes: (i) $[x+{\script{1\over 4}}, y-{\script{1\over 4}}, -z+{\script{1\over 2}}]$ ; (ii) $[x, -y+{\script{1\over 4}}, -z+{\script{1\over 4}}]$ ; (iii) $[x, -y+{\script{3\over 4}}, -z+{\script{3\over 4}}]$ .

Figure 2
The unit cell structures for Ba(ClO₄)₂ with (ClO₄) tetrahedra (yellow) and Ba atoms (green), showing (a) the [010] view and (b) the [001] view.

Figure 3
The local environment of the Ba²⁺ cation (green sphere) surrounded by (ClO₄₎ tetrahedra (yellow). [Symmetry codes: (i) x + $[{1\over 4}]$ , y − $[{1\over 4}]$ , −z + $[{1\over 2}]$ ; (ii) −x, y − $[{1\over 4}]$ , z − $[{1\over 4}]$ ; (iii) x + $[{1\over 4}]$ , −y + $[{1\over 2}]$ , z − $[{1\over 4}]$ ; (iv) −x, −y + $[{1\over 2}]$ , −z + $[{1\over 2}]$ ; (v) x, −y + $[{1\over 4}]$ , −z + $[{1\over 4}]$ ; (vi) −x + $[{1\over 4}]$ , −y + $[{1\over 4}]$ , z; (vii) −x + $[{1\over 4}]$ , y, −z + $[{1\over 4}]$ ; (viii) x, −y + $[{3\over 4}]$ , −z + $[{3\over 4}]$ ; (ix) x, y − $[{1\over 2}]$ , z − $[{1\over 2}]$ ; (x) −x + $[{1\over 4}]$ , −y + $[{3\over 4}]$ , z − $[{1\over 2}]$ ; (xi) −x + $[{1\over 4}]$ , y − $[{1\over 2}]$ , −z + $[{3\over 4}]$ .]

It is interesting to see the significant difference in crystal structures between Ba(ClO₄)₂ and Mg(ClO₄)₂ due to the difference in the cation radii, 1.61 Å for Ba²⁺ and 0.72 Å for Mg²⁺ (Shannon, 1976 ). The much bigger cation, Ba²⁺, is coordinated by eight ClO₄ tetrahedra, while the magnesium is coordinated by only six. Accordingly, the repulsion between two cations of Ba²⁺–Cl⁷⁺ must be much weaker that that of the magnesium compound since the interatomic Ba—Cl distances of 3.55–4.06 Å are much longer than that (3.3 Å) of Mg—Cl for the same charges. This might be a reason why magnesium perchlorate is much more highly reactive with water when exposed to the atmosphere.

The empirical expression for bond valence, which has been widely adopted to estimate valences in inorganic solids (Brown, 2002 ), was used to check the Ba(ClO₄)₂ crystal structure. The bond-valence sums (Brown & Altermatt, 1985 ; Brese & O'Keeffe, 1991 ) calculated with the program Valence (Hormillosa et al., 1993 ) [given in v.u. (valence units): Ba 2.20, Cl 6.89, O1 2.04 and O2 1.73] match the expected charges of the ions reasonably well.

3. Synthesis and crystallization

The anhydrous form of barium perchlorate was prepared by dehydration from Ba(ClO₄)₂·xH₂O (97%, Aldrich). The powder was thoroughly ground in an agate mortar and put into the bottom of a fused-silica tube with the other end sealed with a rubber septum. The tube was inserted into a box furnace through a hole on top of the furnace so that the bottom of the tube was at the center of the furnace inside, and the other end outside connected to a vacuum pump through a needle stuck into the septum. It was heated at a rate of 4K/min up to 423K for 6 h under continuous vacuum. After furnace cooling, powder sampling for X-ray measurement was processed in an Ar atmosphere glove-box, and a tightly sealed dome-type X-ray sample holder commercially available from Bruker was used to prevent hydration during measurement.

4. Refinement details

Crystal data, data collection and structure refinement details are summarized in Table 2. The powder X-ray diffraction (XRD) data were collected at room temperature on a Bragg–Brentano diffractometer (PANalytical Empyrean) with a Cu Kα1 X-ray tube, a focusing primary Ge (111) monochromator (λ = 1.54059 Å), and a position-sensitive PIXcel 3D 2x2 detector, the angular range of 15 ≤ 2θ ≤ 130°, step 0.0260 and total measurement time of 13 h at room temperature. The structure determination from the powder XRD data was performed using a combination of the powder profile refinement program GSAS (Larson & Von Dreele, 2000 ) and the single-crystal structure refinement program CRYSTALS (Betteridge et al., 2003 ). For a three-dimensional view of the Fourier density maps, MCE was used (Rohlíček & Hušák, 2007 ). The XRD pattern was indexed using the program TREOR90 (Werner, 1990 ) run in CRYSFIRE (Shirley, 2002 ) via the positions of 20 diffraction peaks, resulting in an orthorhombic unit cell. The systematic absences suggested the space group Fddd. The structure determination was performed in the same way as in our previous work (Lee & Hong, 2008 ) where the details were described. At the beginning, a structural model with only a dummy atom at an arbitrary position in the unit cell was used. Structure factors were extracted from the powder data, then direct methods were used for the initial solution of the structure using SHELXS97 (Sheldrick, 2008 ) run in CRYSTALS, which yielded a couple of atom positions. However, not all the atoms could be identified at once. The partial model at this stage replaced the initial dummy-atom model, and was used for a Le Bail fit in GSAS. Then, improved structure factors were extracted, which were used for the improved data in the refinement in CRYSTALS. These processes were iterated until a complete and satisfactory structural model was obtained. Finally, Rietveld refinement was employed to complete the structure determination, resulting with reasonable temperature factors and an R_wp factor of 0.06.

Table 2
Experimental details

Crystal data
Chemical formula	Ba(ClO₄)₂
M_r	336.23
Crystal system, space group	Orthorhombic, Fddd
Temperature (K)	298
a, b, c (Å)	14.304 (9), 11.688 (7), 7.2857 (4)
V (Å³)	1218.1 (11)
Z	8
Radiation type	Cu Kα₁, λ = 1.54059 Å
Specimen shape, size (mm)	Flat sheet, 20 × 20

Data collection
Diffractometer	PANalytical Empyrean
Specimen mounting	Packed powder
Data collection mode	Reflection
Scan method	Step
2θ values (°)	2θ_min = 14.992 2θ_max = 129.964 2θ_step = 0.026

Refinement
R factors and goodness of fit	R_p = 0.041, R_wp = 0.060, R_exp = 0.045, R(F²) = 0.05733, χ² = 1.769
No. of data points	4423
No. of parameters	25
Computer programs: X'Pert Data Collector and X'Pert HighScore-Plus (PANalytical, 2011 ), GSAS (Larson & Von Dreele, 2000), SHELXS97 (Sheldrick, 2008), CRYSTALS (Betteridge et al., 2003) and ATOMS (Dowty, 2000 ).

Supporting information

CCDC reference: 1063587

Crystal structure: contains datablock I. DOI: 10.1107/S2056989015008828/cv5487sup1.cif

Rietveld powder data: contains datablock I. DOI: 10.1107/S2056989015008828/cv5487Isup2.rtv

Structure factors: contains datablock I. DOI: 10.1107/S2056989015008828/cv5487Isup3.hkl

checkCIF report

Chemical context top

The alkaline earth metal ions (Mg, Ca, Sr and Ba) have been of increasing interest as ion carriers for post Li ion batteries (Wang et al., 2013), and their perchlorates are often used as conventional organic electrolyte salts for electrochemical cells such as magnesium (Amatucci, 2001; Levi et al., 2010) and calcium ion batteries (Padigi et al., 2015). Since such salts absorb water easily from the atmosphere and the water causes unwanted side reactions in the electrochemical cells, removing water from the salts and its confirmation before use would be very important. However, due to the difficulty in growing a single crystal of such anhydrous perchlorates, no crystal structure had ever been solved before we first identified the magnesium perchlorate structure from powder X-ray diffraction data (Lim et al., 2011). Barium perchlorate is a very strong oxidizing agent due to the high oxidation state of chlorine VII, and it is commonly stabilized as hydrate forms in the atmosphere. Several different forms of the hydrates are expected to exist, as observed in the magnesium analogues (Robertson & Bish, 2010; West, 1935). The crystal structure of the trihydrate form was determined from single-crystal data (Gallucci & Gerkin, 1988), but the anhydrous form, Ba(ClO₄)₂, has not been reported to date. We present here its crystal structure, as determined and refined from laboratory powder X-ray diffraction data (Fig. 1). This is the second crystal structure reported among the anhydrate alkaline earth metal perchlorates.

Structural commentary top

Anhydrous Ba(ClO₄)₂ crystallizes in a new structure type in terms of atomic ratios (1:2:8) and its polyhedral network is, to our knowledge, unique. The asymmetric unit contains one Ba (site symmetry 222 on special position 8a), one Cl (site symmetry 2 on special position 16f) and two O sites (on general positions 32h). The crystal structure is illustrated in Fig. 2, where two different views of [010] and [001] are presented for better visualization. The unit-cell structure is represented with ClO₄ tetrahedra and Ba atoms in Figs. 2a and 2b. The local environment around the Ba atom is presented in Fig. 3. It is clearly seen that there are chains of [(ClO₄)–Ba–(ClO₄)]∞ parallel to b-axis direction. Along each chain, the barium atom is placed between the two ClO₄ tetrahedra, bonded to two oxygen atoms at each tetrahedron. The [010] view in Fig. 2a clearly shows the two-dimensional arrangement of the chains. The chains are interconnected through Ba—O bonds. Each chain is surrounded by six neighboring ones that are shifted parallel to b-axis in such a way that a barium atom of the central chain is connected to the oxygen atoms of eight ClO₄ tetrahedra of six neighboring chains. Four tetrahedra are from four chains, one from each. The other four tetrahedra are from two other chains, two from each. The structure may also be described as a three-dimensional polyhedral network resulting from the corner- and edge-sharing of BaO₁₂ polyhedra and ClO₄ tetrahedra. Each BaO₁₂ polyhedron shares corners with eight ClO₄ tetrahedra, and edges with two ClO₄ tetrahedra. Each ClO₄ tetrahedron shares corners with four BaO₁₂ polyhedra, and an edge with the other BaO₁₂ polyhedron. The oxygen atoms in a ClO₄ tetrahedron consist of two O1 and two O2 ones. O1 is bonded to three atoms, one Cl and two Ba atoms, forming almost planar bonds. On the other hand, O2 is bonded to only two atoms, Cl and Ba. Selected bond lengths are given in Table 1.

It is interesting to see the significant difference in crystal structures between Ba(ClO₄)₂ and Mg(ClO₄)₂. It could be due to the difference in the cation radii, 1.61 Å for Ba²⁺ and 0.72 Å for Mg²⁺ (Shannon, 1976). The much bigger cation, Ba²⁺, is coordinated by eight ClO₄ tetrahedra, while the magnesium is coordinated by only six. Accordingly, the repulsion between two cations of Ba²⁺–Cl⁷⁺ must be much weaker that that of the magnesium compound since the interatomic Ba—Cl distances of 3.55–4.06 Å are much longer than that (~3.3 Å) of Mg—Cl for the same charges. This might be a reason why magnesium perchlorate is much more highly reactive with water when exposed to the atmosphere.

The empirical expression for bond valence, which has been widely adopted to estimate valences in inorganic solids (Brown, 2002), was used to check the Ba(ClO₄)₂ crystal structure. The bond-valence sums (Brown & Altermatt, 1985; Brese & O'Keeffe, 1991) calculated with the program Valence (Hormillosa et al., 1993) [given in v.u. (valence units): Ba 2.20, Cl 6.89, O1 2.04 and O2 1.73] match the expected charges of the ions reasonably well.

Synthesis and crystallization top

The anhydrous form of barium perchlorate was prepared by dehydration from Ba(ClO₄)₂·xH₂O (97%, Aldrich). The powder was thoroughly grounded in an agate mortar and put into the bottom of a fused-silica tube with the other end sealed with a rubber septum. The tube was inserted into a box furnace through a hole on top of the furnace so that the bottom of the tube was at the center of the furnace inside, and the other end outside connected to a vacuum pump through a needle stuck into the septum. It was heated at a rate of 4K/min up to 423K for 6 h under continuous vacuum. After furnace cooling, powder sampling for X-ray measurement was processed in an Ar atmosphere glove-box, and a tightly sealed dome-type X-ray sample holder commercially available from Bruker was used to prevent hydration during measurement.

Refinement details top

The powder X-ray diffraction (XRD) data were collected at room temperature on a Bragg–Brentano diffractometer (PANalytical Empyrean) with a Cu Kα1 X-ray tube, a focusing primary Ge (111) monochromator (λ = 1.54059 Å), and a position-sensitive PIXcel 3D 2x2 detector, the angular range of 15 ≤ 2θ ≤ 130°, step 0.0260 and total measurement time of 13 h at room temperature. The structure determination from the powder XRD data was performed using a combination of the powder profile refinement program GSAS (Larson & Von Dreele, 2000) and the single-crystal structure refinement program CRYSTALS (Betteridge et al., 2003). For a three-dimensional view of the Fourier density maps, MCE was used (Rohlíček & Hušák, 2007). The XRD pattern was indexed using the program TREOR90 (Werner, 1990) run in CRYSFIRE (Shirley, 2002) via the positions of 20 diffraction peaks, resulting in an orthorhombic unit cell. The systematic absences suggested a space group Fddd. The structure determination was performed in the same way as in our previous work (Lee & Hong, 2008) where the details were described. At the beginning, a structural model with only a dummy atom at an arbitrary position in the unit cell was used. Structure factors were extracted from the powder data, then direct methods were used for the initial solution of the structure using SHELXS (Sheldrick, 2008) run in CRYSTALS, which yielded a couple of atom positions. However, not all the atoms could be identified at once. The partial model at this stage replaced the initial dummy-atom model, and was used for a Le Bail fit in GSAS. Then, improved structure factors were extracted, which were used for the improved data in the refinement in CRYSTALS. These processes were iterated until a complete and satisfactory structural model was obtained. Finally, Rietveld refinement was employed to complete the structure determination, resulting with reasonable thermal parameters and an R_wp factor of 0.06.

Related literature top

For related literature, see: Amatucci et al. (2001); Betteridge et al. (2003); Brese & O'Keeffe (1991); Brown (2002); Brown & Altermatt (1985); Gallucci & Gerkin (1988); Hormillosa et al. (1993); Larson & Von Dreele (2000); Lee & Hong (2008); Levi et al. (2010); Lim et al. (2011); Padigi et al. (2015); Robertson & Bish (2010); Rohlíček & Hušák (2007); Shannon (1976); Sheldrick (2008); Shirley (2002); Wang et al. (2013); Werner (1990); West (1935).

Computing details top

Data collection: X'Pert Data Collector (PANalytical, 2011); cell refinement: GSAS (Larson & Von Dreele, 2000); data reduction: X'Pert HighScore-Plus (PANalytical, 2011); program(s) used to solve structure: SHELXS97 (Sheldrick, 2008) and CRYSTALS (Betteridge et al., 2003); program(s) used to refine structure: GSAS (Larson & Von Dreele, 2000); molecular graphics: ATOMS (Dowty, 2000); software used to prepare material for publication: GSAS (Larson & Von Dreele, 2000).

Figures top

	Fig. 1. X-ray Rietveld refinement profiles for Ba(ClO₄)₂ recorded at room temperature. Crosses marks experimental points (red) and the solid line is the calculated profile (green). The bottom trace shows the difference curve (purple) and the ticks denote expected peak positions.
	Fig. 2. The unit cell structures for Ba(ClO₄)₂ with (ClO₄) tetrahedra (yellow) and Ba atoms (green), showing (a) the [010] view and (b) the [001] view.
	Fig. 3. The local environment of barium (Ba1) with (ClO₄₎ tetrahedra (yellow) and Ba atom (green). [Symmetry codes: (i) x + 1/4, y - 1/4, -z + 1/2; (ii) -x, y - 1/4, z - 1/4; (iii) x + 1/4, -y + 1/2, z - 1/4; (iv) -x, -y + 1/2, -z + 1/2; (v) x, -y + 1/4, -z + 1/4; (vi) -x + 1/4, -y + 1/4, z; (vii) -x + 1/4, y, -z + 1/4; (viii) x, -y + 3/4, -z + 3/4; (ix) x, y - 1/2, z - 1/2; (x) -x + 1/4, -y + 3/4, z - 1/2; (xi) -x + 1/4, y - 1/2, -z + 3/4.]

Barium perchlorate anhydrate top

Crystal data top

Ba(ClO₄)₂	Z = 8
M_r = 336.23	F(000) = 1232.0
Orthorhombic, Fddd	D_x = 3.667 Mg m⁻³
Hall symbol: -F 2uv 2vw	Cu Kα₁ radiation, λ = 1.54059 Å
a = 14.304 (9) Å	T = 298 K
b = 11.688 (7) Å	white
c = 7.2857 (4) Å	flat sheet, 20 × 20 mm
V = 1218.1 (11) Å³

Data collection top

PANalytical Empyrean diffractometer	Data collection mode: reflection
Radiation source: sealed X-ray tube, PANalytical Cu Ceramic X-ray tube	Scan method: step
Specimen mounting: packed powder	2θ_min = 14.992°, 2θ_max = 129.964°, 2θ_step = 0.026°

Refinement top

Least-squares matrix: full	Profile function: CW Profile function number 3 with 19 terms Pseudovoigt profile coefficients as parameterized in P. Thompson, D.E. Cox & J.B. Hastings (1987). J. Appl. Cryst.,20,79-83. Asymmetry correction of L.W. Finger, D.E. Cox & A. P. Jephcoat (1994). J. Appl. Cryst.,27,892-900. #1(GU) = 0.000 #2(GV) = 0.000 #3(GW) = 0.000 #4(GP) = 4.256 #5(LX) = 1.263 #6(LY) = 7.277 #7(S/L) = 0.0005 #8(H/L) = 0.0005 #9(trns) = -1.26 #10(shft)= 1.5725 #11(stec)= 4.60 #12(ptec)= 1.24 #13(sfec)= 0.00 #14(L11) = -0.018 #15(L22) = -0.022 #16(L33) = -0.202 #17(L12) = 0.017 #18(L13) = 0.017 #19(L23) = 0.000 Peak tails are ignored where the intensity is below 0.0010 times the peak Aniso. broadening axis 0.0 0.0 1.0
R_p = 0.041	25 parameters
R_wp = 0.060	0 restraints
R_exp = 0.045	(Δ/σ)_max = 0.01
R(F²) = 0.05733	Background function: GSAS Background function number 1 with 36 terms. Shifted Chebyshev function of 1st kind 1: 567.648 2: -857.136 3: 662.653 4: -377.264 5: 131.512 6: 59.5938 7: -169.995 8: 206.701 9: -185.404 10: 133.783 11: -68.7256 12: 6.71856 13: 43.4515 14: -72.2732 15: 82.7653 16: -73.3661 17: 50.0183 18: -22.8495 19: -2.57480 20: 20.6662 21: -29.1651 22: 28.9267 23: -24.2542 24: 14.4066 25: -5.32227 26: -4.03875 27: 10.7050 28: -13.4416 29: 11.1646 30: -9.08855 31: 2.53787 32: -0.292410 33: -1.46976 34: 0.544854 35: -1.31862 36: 0.893355
χ² = 1.769	Preferred orientation correction: March-Dollase AXIS 1 Ratio= 0.97385 h= 1.000 k= 0.000 l= 0.000 Prefered orientation correction range: Min= 0.96103, Max= 1.08275
4423 data points

Crystal data top

Ba(ClO₄)₂	V = 1218.1 (11) Å³
M_r = 336.23	Z = 8
Orthorhombic, Fddd	Cu Kα₁ radiation, λ = 1.54059 Å
a = 14.304 (9) Å	T = 298 K
b = 11.688 (7) Å	flat sheet, 20 × 20 mm
c = 7.2857 (4) Å

Data collection top

PANalytical Empyrean diffractometer	Scan method: step
Specimen mounting: packed powder	2θ_min = 14.992°, 2θ_max = 129.964°, 2θ_step = 0.026°
Data collection mode: reflection

Refinement top

R_p = 0.041	χ² = 1.769
R_wp = 0.060	4423 data points
R_exp = 0.045	25 parameters
R(F²) = 0.05733	0 restraints

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq
Ba1	0.125	0.125	0.125	0.0139 (2)*
Cl1	0.125	0.42875 (18)	0.125	0.0160 (7)*
O1	0.0471 (3)	0.3533 (3)	0.1575 (5)	0.0162 (11)*
O2	0.1412 (3)	0.5016 (4)	0.2807 (4)	0.0170 (12)*

Geometric parameters (Å, º) top

Ba1—O1	2.901 (4)	Ba1—O2^viii	2.903 (4)
Ba1—O1ⁱ	2.939 (4)	Ba1—O2^ix	2.903 (4)
Ba1—O1ⁱⁱ	2.939 (4)	Ba1—O2^x	2.903 (4)
Ba1—O1ⁱⁱⁱ	2.939 (4)	Ba1—O2^xi	2.903 (4)
Ba1—O1^iv	2.939 (4)	Cl1—O1	1.441 (4)
Ba1—O1^v	2.901 (4)	Cl1—O1^vii	1.441 (4)
Ba1—O1^vi	2.901 (4)	Cl1—O2	1.437 (4)
Ba1—O1^vii	2.901 (4)	Cl1—O2^vii	1.437 (4)

O1—Ba1—O1ⁱ	110.93 (10)	O1ⁱ—Ba1—O2^ix	110.87 (10)
O1—Ba1—O1ⁱⁱ	78.56 (7)	O1ⁱ—Ba1—O2^x	125.15 (10)
O1—Ba1—O1ⁱⁱⁱ	106.64 (7)	O1ⁱ—Ba1—O2^xi	63.76 (10)
O1—Ba1—O1^iv	63.56 (12)	O1^vi—Ba1—O1^vii	134.82 (15)
O1—Ba1—O1^v	134.82 (15)	O2^xii—Ba1—O2^ix	170.85 (15)
O1—Ba1—O1^vi	170.64 (14)	O2^viii—Ba1—O2^x	120.42 (15)
O1—Ba1—O1^vii	46.25 (15)	O2^viii—Ba1—O2^xi	60.43 (15)
O1—Ba1—O2^viii	60.21 (10)	O1—Cl1—O1^vii	104.5 (3)
O1—Ba1—O2^ix	123.92 (10)	O1—Cl1—O2	110.96 (19)
O1—Ba1—O2^x	65.35 (10)	O1—Cl1—O2^vii	111.6 (2)
O1—Ba1—O2^xi	110.84 (10)	O2—Cl1—O2^vii	107.3 (3)
O1ⁱ—Ba1—O1ⁱⁱ	170.09 (14)	Ba1—O1—Ba1^xiii	116.44 (12)
O1ⁱ—Ba1—O1ⁱⁱⁱ	66.21 (14)	Ba1—O1—Cl1	104.6 (2)
O1ⁱ—Ba1—O1^iv	114.73 (14)	Ba1^xiii—O1—Cl1	133.1 (2)
O1ⁱ—Ba1—O2^viii	60.66 (10)	Ba1^viii—O2—Cl1	164.5 (2)

Symmetry codes: (i) x+1/4, y−1/4, −z+1/2; (ii) −x, y−1/4, z−1/4; (iii) x+1/4, −y+1/2, z−1/4; (iv) −x, −y+1/2, −z+1/2; (v) x, −y+1/4, −z+1/4; (vi) −x+1/4, −y+1/4, z; (vii) −x+1/4, y, −z+1/4; (viii) x, −y+3/4, −z+3/4; (ix) x, y−1/2, z−1/2; (x) −x+1/4, −y+3/4, z−1/2; (xi) −x+1/4, y−1/2, −z+3/4; (xii) x, −y+7/4, −z+11/4; (xiii) −x, y+1/4, z+1/4.

Selected bond lengths (Å) top

Ba1—O1	2.901 (4)	Ba1—O2ⁱⁱⁱ	2.903 (4)
Ba1—O1ⁱ	2.939 (4)	Cl1—O1	1.441 (4)
Ba1—O1ⁱⁱ	2.901 (4)	Cl1—O2	1.437 (4)

Symmetry codes: (i) x+1/4, y−1/4, −z+1/2; (ii) x, −y+1/4, −z+1/4; (iii) x, −y+3/4, −z+3/4.

Experimental details

Crystal data
Chemical formula	Ba(ClO₄)₂
M_r	336.23
Crystal system, space group	Orthorhombic, Fddd
Temperature (K)	298
a, b, c (Å)	14.304 (9), 11.688 (7), 7.2857 (4)
V (Å³)	1218.1 (11)
Z	8
Radiation type	Cu Kα₁, λ = 1.54059 Å
Specimen shape, size (mm)	Flat sheet, 20 × 20

Data collection
Diffractometer	PANalytical Empyrean diffractometer
Specimen mounting	Packed powder
Data collection mode	Reflection
Scan method	Step
2θ values (°)	2θ_min = 14.992 2θ_max = 129.964 2θ_step = 0.026

Refinement
R factors and goodness of fit	R_p = 0.041, R_wp = 0.060, R_exp = 0.045, R(F²) = 0.05733, χ² = 1.769
No. of data points	4423
No. of parameters	25

Computer programs: X'Pert Data Collector (PANalytical, 2011), GSAS (Larson & Von Dreele, 2000), X'Pert HighScore-Plus (PANalytical, 2011), SHELXS97 (Sheldrick, 2008) and CRYSTALS (Betteridge et al., 2003), ATOMS (Dowty, 2000).

Acknowledgements

This work was supported by the DGIST R&D Program of the Ministry of Science, ICT and Future Planning of Korea (15-HRLA-01).

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