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An isomer of B20H26, isolated from the autolysis of nido-B10H14 in a silent electrical discharge, is shown to be the title compound 1,1'-bis(nido-decaboranyl). The molecule has crystallographic inversion symmetry and a long intercage B-B bond of 1.704 (3) Å.
Supporting information
Decaborane(14) (0.472 g), contained in a small sample vial, was placed in a
glass high-voltage silent-discharge reaction tube [constructed in a similar
manner to the one used by Friedman et al. (1963)]. Silent electrical
discharge under dynamic vacuum (1500 V AC, ca 10-3 mm Hg) for 90 min
resulted in a substantial amount of yellow material being deposited on the
sides of the tube. The reaction vessel was opened to air and the material
extracted with dichloromethane. The extract was filtered through silica gel
and the filtrate subjected to preparative high-performance liquid
chromatograpic (HPLC) separation (25 × 2.12 cm column, Lichosorb SI 60,
15:85 CH2Cl2/n-hexane, 20 ml min-1) giving three products with
RT 6.9 (component A), 7.3 (component B) and 7.7 m (component C).
Components A and B were identified by 11B NMR spectroscopy as 2,2' and
1,2'-(nido-B10H13)2, respectively, by comparison with previously
characterized samples (Boocock et al., 1981). The 11B NMR
spectroscopic characterization of component C suggested the previously
unreported 1,1'-bis-decaboranyl isomer; CDCl3 solution 300 K, cluster
resonances ordered as, assignment δ(11B)/p.p.m. [2J(11B–1H)/Hz in
brackets]: B2,4 - 34.5 [156]; B5,7,8,10 + 0.8 [148]; B6,9 + 9.5 [165]; B3 +
12.8 [151]; B1 + 19.8 [site of conjuncto linkage]. Single crystals were grown
over a period of 2 months by sublimation in a sealed evacuated glass tube
placed on a warm oven.
Data collection procedures are described by Clegg et al. (1998). The data
set, derived from several series of exposures, is complete to θ = 26°.
Corrections were applied for the decay in the synchrotron primary beam
intensity. All H atoms were refined freely [B—H range 1.051 (16)–1.329 (17) Å].
Data collection: SMART (Siemens, 1997); cell refinement: SAINT (Siemens, 1997); data reduction: SAINT; program(s) used to solve structure: SHELXTL (Sheldrick, 1998); program(s) used to refine structure: SHELXTL; molecular graphics: SHELXTL; software used to prepare material for publication: SHELXTL and local programs.
1,1'-bis(
nido-decaboranyl)
top
Crystal data top
B20H26 | Dx = 0.983 Mg m−3 |
Mr = 242.41 | Synchrotron radiation, λ = 0.6890 Å |
Orthorhombic, Pbca | Cell parameters from 5421 reflections |
a = 10.6601 (5) Å | θ = 2.7–29.4° |
b = 10.5515 (5) Å | µ = 0.04 mm−1 |
c = 14.5604 (6) Å | T = 150 K |
V = 1637.75 (13) Å3 | Cuboid, colourless |
Z = 4 | 0.03 × 0.03 × 0.03 mm |
F(000) = 504 | |
Data collection top
Siemens SMART CCD diffractometer | 1746 reflections with I > 2σ(I) |
Radiation source: Daresbury SRS station 9.8 | Rint = 0.056 |
Silicon 111 monochromator | θmax = 29.4°, θmin = 2.7° |
ω rotation with narrow frames scans | h = −14→14 |
10589 measured reflections | k = −14→7 |
2301 independent reflections | l = −20→20 |
Refinement top
Refinement on F2 | Primary atom site location: structure-invariant direct methods |
Least-squares matrix: full | Secondary atom site location: difference Fourier map |
R[F2 > 2σ(F2)] = 0.056 | Hydrogen site location: difference Fourier map |
wR(F2) = 0.150 | All H-atom parameters refined |
S = 1.09 | w = 1/[σ2(Fo2) + (0.074P)2 + 0.3725P] where P = (Fo2 + 2Fc2)/3 |
2301 reflections | (Δ/σ)max < 0.001 |
143 parameters | Δρmax = 0.38 e Å−3 |
0 restraints | Δρmin = −0.18 e Å−3 |
Crystal data top
B20H26 | V = 1637.75 (13) Å3 |
Mr = 242.41 | Z = 4 |
Orthorhombic, Pbca | Synchrotron radiation, λ = 0.6890 Å |
a = 10.6601 (5) Å | µ = 0.04 mm−1 |
b = 10.5515 (5) Å | T = 150 K |
c = 14.5604 (6) Å | 0.03 × 0.03 × 0.03 mm |
Data collection top
Siemens SMART CCD diffractometer | 1746 reflections with I > 2σ(I) |
10589 measured reflections | Rint = 0.056 |
2301 independent reflections | |
Refinement top
R[F2 > 2σ(F2)] = 0.056 | 0 restraints |
wR(F2) = 0.150 | All H-atom parameters refined |
S = 1.09 | Δρmax = 0.38 e Å−3 |
2301 reflections | Δρmin = −0.18 e Å−3 |
143 parameters | |
Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top | x | y | z | Uiso*/Ueq | |
B1 | 0.46647 (12) | 0.55218 (12) | 0.46270 (9) | 0.0164 (3) | |
B2 | 0.55859 (14) | 0.67977 (13) | 0.41826 (10) | 0.0202 (3) | |
H2 | 0.6587 (16) | 0.6820 (15) | 0.4308 (11) | 0.031 (4)* | |
B3 | 0.49222 (14) | 0.56719 (14) | 0.34216 (9) | 0.0203 (3) | |
H3 | 0.5547 (17) | 0.5096 (18) | 0.3019 (11) | 0.038 (5)* | |
B4 | 0.35058 (13) | 0.49886 (13) | 0.38247 (9) | 0.0187 (3) | |
H4 | 0.3340 (15) | 0.3996 (15) | 0.3736 (10) | 0.023 (4)* | |
B5 | 0.44334 (14) | 0.70690 (14) | 0.50513 (10) | 0.0216 (3) | |
H5 | 0.4615 (15) | 0.7348 (16) | 0.5758 (11) | 0.028 (4)* | |
B6 | 0.47698 (15) | 0.81984 (15) | 0.41677 (12) | 0.0271 (3) | |
H6 | 0.5098 (16) | 0.9159 (16) | 0.4290 (12) | 0.035 (5)* | |
B7 | 0.48766 (15) | 0.72877 (15) | 0.31286 (11) | 0.0258 (3) | |
H7 | 0.5337 (16) | 0.7655 (16) | 0.2549 (12) | 0.033 (4)* | |
B8 | 0.34977 (16) | 0.60858 (15) | 0.28909 (11) | 0.0269 (3) | |
H8 | 0.3291 (16) | 0.5832 (15) | 0.2190 (12) | 0.036 (5)* | |
B9 | 0.22848 (14) | 0.60423 (15) | 0.37348 (11) | 0.0257 (3) | |
H9 | 0.1329 (15) | 0.5890 (15) | 0.3596 (11) | 0.030 (4)* | |
B10 | 0.30692 (13) | 0.58756 (14) | 0.48119 (10) | 0.0210 (3) | |
H10 | 0.2541 (14) | 0.5530 (14) | 0.5389 (10) | 0.023 (4)* | |
H11 | 0.3832 (18) | 0.7963 (17) | 0.4698 (13) | 0.044 (5)* | |
H12 | 0.4106 (16) | 0.8139 (16) | 0.3396 (12) | 0.035 (5)* | |
H13 | 0.2693 (17) | 0.6912 (16) | 0.3154 (11) | 0.038 (5)* | |
H14 | 0.2419 (18) | 0.6740 (16) | 0.4456 (12) | 0.043 (5)* | |
Atomic displacement parameters (Å2) top | U11 | U22 | U33 | U12 | U13 | U23 |
B1 | 0.0164 (6) | 0.0165 (6) | 0.0164 (6) | 0.0014 (5) | 0.0010 (4) | −0.0013 (5) |
B2 | 0.0209 (7) | 0.0161 (6) | 0.0235 (7) | −0.0002 (5) | −0.0003 (5) | 0.0009 (5) |
B3 | 0.0240 (7) | 0.0198 (7) | 0.0170 (6) | 0.0006 (5) | 0.0017 (5) | 0.0004 (5) |
B4 | 0.0201 (6) | 0.0168 (6) | 0.0192 (6) | 0.0008 (5) | −0.0027 (5) | −0.0008 (5) |
B5 | 0.0236 (7) | 0.0190 (7) | 0.0224 (7) | 0.0047 (5) | −0.0022 (5) | −0.0042 (5) |
B6 | 0.0267 (7) | 0.0194 (7) | 0.0351 (8) | 0.0013 (6) | −0.0033 (6) | 0.0002 (6) |
B7 | 0.0272 (7) | 0.0227 (8) | 0.0275 (7) | 0.0002 (6) | 0.0012 (6) | 0.0075 (6) |
B8 | 0.0315 (8) | 0.0261 (8) | 0.0232 (7) | −0.0015 (6) | −0.0077 (6) | 0.0036 (6) |
B9 | 0.0219 (7) | 0.0221 (7) | 0.0333 (8) | 0.0021 (5) | −0.0073 (6) | 0.0001 (6) |
B10 | 0.0190 (6) | 0.0219 (7) | 0.0221 (6) | 0.0031 (5) | 0.0005 (5) | 0.0004 (5) |
Geometric parameters (Å, º) top
B1—B1i | 1.704 (3) | B5—B10 | 1.955 (2) |
B1—B10 | 1.7620 (19) | B5—H5 | 1.088 (16) |
B1—B5 | 1.7628 (19) | B5—H11 | 1.251 (18) |
B1—B3 | 1.7836 (19) | B6—B7 | 1.796 (2) |
B1—B2 | 1.788 (2) | B6—H6 | 1.087 (17) |
B1—B4 | 1.7910 (19) | B6—H11 | 1.288 (19) |
B2—B6 | 1.715 (2) | B6—H12 | 1.329 (17) |
B2—B3 | 1.772 (2) | B7—B8 | 1.972 (2) |
B2—B5 | 1.787 (2) | B7—H7 | 1.051 (18) |
B2—B7 | 1.787 (2) | B7—H12 | 1.278 (17) |
B2—H2 | 1.083 (17) | B8—B9 | 1.784 (2) |
B3—B7 | 1.758 (2) | B8—H8 | 1.077 (17) |
B3—B8 | 1.759 (2) | B8—H13 | 1.282 (17) |
B3—B4 | 1.773 (2) | B9—B10 | 1.786 (2) |
B3—H3 | 1.075 (18) | B9—H9 | 1.051 (16) |
B4—B9 | 1.717 (2) | B9—H13 | 1.321 (17) |
B4—B10 | 1.777 (2) | B9—H14 | 1.290 (17) |
B4—B8 | 1.786 (2) | B10—H10 | 1.075 (15) |
B4—H4 | 1.070 (15) | B10—H14 | 1.258 (18) |
B5—B6 | 1.790 (2) | | |
| | | |
B1i—B1—B10 | 116.40 (12) | B2—B6—B5 | 61.24 (8) |
B1i—B1—B5 | 115.71 (12) | B2—B6—B7 | 61.15 (9) |
B10—B1—B5 | 67.37 (8) | B5—B6—B7 | 105.19 (10) |
B1i—B1—B3 | 128.32 (12) | B2—B6—H6 | 129.6 (9) |
B10—B1—B3 | 106.26 (9) | B5—B6—H6 | 124.6 (9) |
B5—B1—B3 | 106.51 (10) | B7—B6—H6 | 128.1 (9) |
B1i—B1—B2 | 119.14 (13) | B2—B6—H11 | 102.7 (8) |
B10—B1—B2 | 115.21 (10) | B5—B6—H11 | 44.3 (8) |
B5—B1—B2 | 60.42 (8) | B7—B6—H11 | 116.8 (8) |
B3—B1—B2 | 59.49 (8) | H6—B6—H11 | 109.4 (12) |
B1i—B1—B4 | 120.14 (13) | B2—B6—H12 | 103.9 (7) |
B10—B1—B4 | 60.02 (8) | B5—B6—H12 | 118.0 (7) |
B5—B1—B4 | 115.02 (10) | B7—B6—H12 | 45.3 (7) |
B3—B1—B4 | 59.48 (8) | H6—B6—H12 | 110.8 (11) |
B2—B1—B4 | 112.29 (9) | H11—B6—H12 | 94.8 (11) |
B6—B2—B3 | 111.54 (11) | B3—B7—B2 | 59.96 (8) |
B6—B2—B5 | 61.45 (9) | B3—B7—B6 | 108.43 (11) |
B3—B2—B5 | 106.00 (10) | B2—B7—B6 | 57.20 (8) |
B6—B2—B7 | 61.65 (9) | B3—B7—B8 | 55.91 (8) |
B3—B2—B7 | 59.21 (8) | B2—B7—B8 | 106.26 (10) |
B5—B2—B7 | 105.70 (10) | B6—B7—B8 | 116.40 (11) |
B6—B2—B1 | 112.02 (11) | B3—B7—H7 | 122.6 (9) |
B3—B2—B1 | 60.14 (8) | B2—B7—H7 | 126.8 (9) |
B5—B2—B1 | 59.10 (8) | B6—B7—H7 | 120.6 (9) |
B7—B2—B1 | 107.24 (10) | B8—B7—H7 | 116.4 (9) |
B6—B2—H2 | 118.9 (8) | B3—B7—H12 | 128.7 (8) |
B3—B2—H2 | 120.9 (8) | B2—B7—H12 | 102.3 (8) |
B5—B2—H2 | 123.7 (8) | B6—B7—H12 | 47.7 (8) |
B7—B2—H2 | 123.7 (8) | B8—B7—H12 | 91.5 (8) |
B1—B2—H2 | 119.8 (8) | H7—B7—H12 | 106.6 (12) |
B7—B3—B8 | 68.21 (9) | B3—B8—B9 | 108.47 (10) |
B7—B3—B2 | 60.83 (8) | B3—B8—B4 | 60.03 (8) |
B8—B3—B2 | 116.94 (11) | B9—B8—B4 | 57.49 (8) |
B7—B3—B4 | 116.81 (11) | B3—B8—B7 | 55.88 (8) |
B8—B3—B4 | 60.74 (8) | B9—B8—B7 | 115.84 (11) |
B2—B3—B4 | 113.93 (10) | B4—B8—B7 | 106.24 (10) |
B7—B3—B1 | 108.70 (10) | B3—B8—H8 | 122.1 (9) |
B8—B3—B1 | 108.75 (10) | B9—B8—H8 | 119.8 (9) |
B2—B3—B1 | 60.37 (8) | B4—B8—H8 | 124.1 (9) |
B4—B3—B1 | 60.47 (7) | B7—B8—H8 | 118.6 (9) |
B7—B3—H3 | 115.6 (10) | B3—B8—H13 | 128.0 (8) |
B8—B3—H3 | 115.8 (9) | B9—B8—H13 | 47.7 (8) |
B2—B3—H3 | 118.2 (10) | B4—B8—H13 | 102.5 (7) |
B4—B3—H3 | 118.6 (10) | B7—B8—H13 | 90.5 (8) |
B1—B3—H3 | 125.6 (9) | H8—B8—H13 | 108.4 (12) |
B9—B4—B3 | 110.92 (10) | B4—B9—B8 | 61.30 (9) |
B9—B4—B10 | 61.45 (8) | B4—B9—B10 | 60.94 (8) |
B3—B4—B10 | 106.06 (10) | B8—B9—B10 | 105.54 (10) |
B9—B4—B8 | 61.21 (9) | B4—B9—H9 | 130.6 (9) |
B3—B4—B8 | 59.23 (8) | B8—B9—H9 | 125.0 (9) |
B10—B4—B8 | 105.85 (10) | B10—B9—H9 | 127.4 (9) |
B9—B4—B1 | 111.67 (10) | B4—B9—H13 | 104.4 (8) |
B3—B4—B1 | 60.05 (8) | B8—B9—H13 | 45.8 (8) |
B10—B4—B1 | 59.18 (7) | B10—B9—H13 | 118.4 (8) |
B8—B4—B1 | 107.23 (10) | H9—B9—H13 | 107.6 (12) |
B9—B4—H4 | 120.0 (8) | B4—B9—H14 | 102.9 (8) |
B3—B4—H4 | 119.9 (8) | B8—B9—H14 | 117.7 (9) |
B10—B4—H4 | 124.7 (8) | B10—B9—H14 | 44.7 (8) |
B8—B4—H4 | 122.8 (8) | H9—B9—H14 | 110.6 (13) |
B1—B4—H4 | 120.0 (8) | H13—B9—H14 | 95.0 (11) |
B1—B5—B2 | 60.48 (8) | B1—B10—B4 | 60.80 (8) |
B1—B5—B6 | 109.67 (10) | B1—B10—B9 | 109.80 (10) |
B2—B5—B6 | 57.31 (8) | B4—B10—B9 | 57.61 (8) |
B1—B5—B10 | 56.29 (7) | B1—B10—B5 | 56.34 (7) |
B2—B5—B10 | 106.38 (9) | B4—B10—B5 | 106.78 (9) |
B6—B5—B10 | 116.72 (10) | B9—B10—B5 | 116.20 (10) |
B1—B5—H5 | 123.9 (9) | B1—B10—H10 | 123.6 (8) |
B2—B5—H5 | 126.2 (9) | B4—B10—H10 | 126.2 (8) |
B6—B5—H5 | 117.7 (9) | B9—B10—H10 | 118.3 (8) |
B10—B5—H5 | 118.4 (9) | B5—B10—H10 | 118.0 (8) |
B1—B5—H11 | 128.7 (9) | B1—B10—H14 | 128.5 (9) |
B2—B5—H11 | 100.5 (9) | B4—B10—H14 | 101.1 (8) |
B6—B5—H11 | 46.0 (9) | B9—B10—H14 | 46.2 (8) |
B10—B5—H11 | 91.8 (9) | B5—B10—H14 | 90.9 (8) |
H5—B5—H11 | 106.0 (12) | H10—B10—H14 | 106.3 (12) |
Symmetry code: (i) −x+1, −y+1, −z+1. |
Experimental details
Crystal data |
Chemical formula | B20H26 |
Mr | 242.41 |
Crystal system, space group | Orthorhombic, Pbca |
Temperature (K) | 150 |
a, b, c (Å) | 10.6601 (5), 10.5515 (5), 14.5604 (6) |
V (Å3) | 1637.75 (13) |
Z | 4 |
Radiation type | Synchrotron, λ = 0.6890 Å |
µ (mm−1) | 0.04 |
Crystal size (mm) | 0.03 × 0.03 × 0.03 |
|
Data collection |
Diffractometer | Siemens SMART CCD diffractometer |
Absorption correction | – |
No. of measured, independent and observed [I > 2σ(I)] reflections | 10589, 2301, 1746 |
Rint | 0.056 |
(sin θ/λ)max (Å−1) | 0.712 |
|
Refinement |
R[F2 > 2σ(F2)], wR(F2), S | 0.056, 0.150, 1.09 |
No. of reflections | 2301 |
No. of parameters | 143 |
H-atom treatment | All H-atom parameters refined |
Δρmax, Δρmin (e Å−3) | 0.38, −0.18 |
Selected geometric parameters (Å, º) topB1—B1i | 1.704 (3) | B3—B8 | 1.759 (2) |
B1—B10 | 1.7620 (19) | B3—B4 | 1.773 (2) |
B1—B5 | 1.7628 (19) | B4—B9 | 1.717 (2) |
B1—B3 | 1.7836 (19) | B4—B10 | 1.777 (2) |
B1—B2 | 1.788 (2) | B4—B8 | 1.786 (2) |
B1—B4 | 1.7910 (19) | B5—B6 | 1.790 (2) |
B2—B6 | 1.715 (2) | B5—B10 | 1.955 (2) |
B2—B3 | 1.772 (2) | B6—B7 | 1.796 (2) |
B2—B5 | 1.787 (2) | B7—B8 | 1.972 (2) |
B2—B7 | 1.787 (2) | B8—B9 | 1.784 (2) |
B3—B7 | 1.758 (2) | B9—B10 | 1.786 (2) |
| | | |
B1i—B1—B10 | 116.40 (12) | B1i—B1—B2 | 119.14 (13) |
B1i—B1—B5 | 115.71 (12) | B1i—B1—B4 | 120.14 (13) |
B1i—B1—B3 | 128.32 (12) | | |
Symmetry code: (i) −x+1, −y+1, −z+1. |
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Some time ago, the synthesis of the globular macropolyhedral megaloborane B20H26, from the passage of B10H14 through a silent electrical discharge, was reported, although precise reaction conditions were unspecified (Friedman et al., 1963). An alternative Me2BNHMe-catalysed thermolytic preparation was also reported (Miller & Muetterties, 1963; Miller et al., 1964). Since then (Miller & Muetterties, 1963, Enemark et al., 1966), this very interesting compound has been essentially unexamined. We have now developed an interest in B20H26 and in the possibilities of synthesizing other globular boranes (Kaur et al., 1997; Bould et al., 1999, 2000, Yao et al., 1999), and have consequently sought to duplicate the original synthesis that used a silent electrical discharge. A 1500 V AC silent discharge through a glass tube containing decaborane(14) yielded predominantly a yellow material which is a main focus of our investigations and which we have yet to identify. However, dichloromethane extraction of the material followed by high-performance liquid chromatographic (HPLC) separation yielded very small quantities of several substances, shown by NMR spectroscopy to be a variety of boron hydride species. Predominant among these was a series of compounds identified by NMR spectroscopy (compare with Boocock et al., 1980) as being in the bis(nido-decaboranyl) family, (B10H13)2. Two of these were identified as the known compounds, i.e. 2,2'- and 1,2'-(nido-B10H13)2 (after Boocock et al., 1981). A further previously unobserved bis(nido-decaboronyl) isomer was isolated and crystallized by slow sublimation in an evacuated tube. We report here its structure determination as the 1,1'-(nido-B10H13)2 isomer, i.e. the title compound. Crystals were small (0.03 mm micron cubes) and the single-crystal work required synchrotron-generated X-irradiation for sufficient diffraction intensity (Cernik et al., 1997, 2000; Clegg et al., 1998).
There are 15 possible isomers of (nido-B10H13)2, of which eight are four enantiomeric pairs (Boocock et al., 1980). Those previously characterized structurally by single-crystal X-ray work are the 1,2'- (Barrett et al., 1985), the 1,5'- (Brown et al., 1979), the 2,2'- and the 2,6'- species (Boocock et al., 1980). The 6,6'- (Boocock et al., 1979), 2,5'- and 5,5'-isomers (Boocock et al., 1981) have been characterized by NMR spectroscopy. The 1,1'-isomer (Fig. 1) contains an inversion centre in the midpoint of the intercage B—B linkage. The B—B linkage distance [B1—B1i; symmetry code: (i) 1 - x, 1 - y, 1 - z] of 1.704 (3) Å is at the top end of the range of values for reported bis(decaboranyl) isomers, which range from 1.698 (2) (1,5'-isomer; Brown et al., 1979) to 1.679 (3) Å (2,2'-isomer; Barrett et al., 1985). The basal intracluster B—B distances associated with the linkage B1 atom show small but significant lengthenings of ca 0.017 (2) Å compared to those around the unsubstituted B3 atom and are similar in magnitude to those noted previously (0.015 Å; Boocock et al., 1980). Other distances on the substituted side of the decaborane subcluster do not differ significantly from those on the unsubstituted side with the exception of the long B5—B10 `gunwale' interboron vector in the nido-decaboronyl `boat', which, at 1.955 (2) Å, is 0.016 (2) Å shorter than the opposing B7—B8 distance.