Crystal structure of rubidium methyl­diazo­tate

Grassl, T.; Korber, N.

doi:10.1107/S2056989016020429

research communications

CRYSTALLOGRAPHIC
COMMUNICATIONS

ISSN: 2056-9890

Volume 73| Part 2| February 2017| Pages 159-161

https://doi.org/10.1107/S2056989016020429

Open

access

Crystal structure of rubidium methyldiazotate

Tobias Grassl ^a and Nikolaus Korber ^a ^*

^aInstitut für Anorganische Chemie, Universität Regensburg, Universitätsstrasse 31, 93053 Regensburg, Germany
^*Correspondence e-mail: nikolaus.korber@chemie.uni-regensburg.de

Edited by S. Parkin, University of Kentucky, USA (Received 1 December 2016; accepted 23 December 2016; online 13 January 2017)

The title compound, Rb⁺·H₃CN₂O⁻, has been crystallized in liquid ammonia as a reaction product of the reductive ammonolysis of the natural compound streptozocin. Elemental rubidium was used as reduction agent as it is soluble in liquid ammonia, forming a blue solution. Reductive bond cleavage in biogenic materials under kinetically controlled conditions offers a new approach to gain access to sustainably produced raw materials. The anion is nearly planar [dihedral angle O—N—N—C = −0.4 (2)°]. The Rb⁺ cation has a coordination number of seven, and coordinates to five anions. One anion is bound via both its N atoms, one by both O and N, two anions are bound by only their O atoms, and the last is bound via the N atom adjacent to the methyl group. The diazotate anions are bridged by cations and do not exhibit any direct contacts with each other. The cations form corrugated layers that propagate in the (-101) plane.

Keywords: crystal structure; reductive ammonolysis; streptozocin; rubidium cation; methyldiazotate anion.

CCDC reference: 1524271

1. Chemical context

The crystal structure of the title compound was determined in the course of investigations regarding the reactivity of carbohydrates towards alkali metals and NH₃ in solutions where liquid ammonia itself is used as solvent. The starting material, streptozocin, was commercially available and used as shipped.

2. Structural commentary

The methyldiazotate anion is found to exist in the cis configuration, which is in correspondence with the equivalent potassium species (Müller et al., 1963 ; Huber et al., 1965 ). The structure of the diazotate anion has been further discussed by Suhr (1963 ) and by Kübler & Lüttke (1963 ).

The title compound does not contain any solvent molecules, which is unusual for ionic species crystallized from liquid ammonia. The anion is nearly planar, having an O1—N1—N2—C1 torsion angle of −0.4 (2)°. Five direct anion–cation contacts can be observed, with maximum bond lengths of d(Rb—O) = 2.9871 (12) Å and d(Rb—N) = 3.1656 (15) Å. The rubidium cation has a coordination number of seven, in which five anions can be observed in its direct environment (Fig. 1). The coordination to the cation is both side-on and terminal: one anion is bound via both its N atoms, one by both O and N, two anions are bound only via O, and the remaining anion is bound via the N atom adjacent to the methyl group.

Figure 1
The coordination environment of the Rb⁺ cation. Displacement ellipsoids are drawn at the 50% probability level. [Symmetry codes: (i) − $[{1\over 2}]$ + x, $[{3\over 2}]$ − y, $[{1\over 2}]$ + z; (ii) −1 + x, y, z; (iii) − $[{1\over 2}]$ + x, $[{3\over 2}]$ − y, $[{1\over 2}]$ + z; (iv) 1 − x, 1 − y, 1 − z.]

3. Supramolecular features

The diazotate anions are bridged by cations and do not exhibit any direct contacts to each other. The cations are found to form a corrugated-layer like arrangement within the structure, propagating in the ( $[\overline{1}]$ 01) plane (Fig. 2). Although the oxygen atom can act as a hydrogen-bridge acceptor, no such interactions can be found in the structure as the C—H bonds are not sufficiently polarized. As the compound is of an ionic nature, electrostatic interactions are the dominant driving force towards the arrangement of the ionic species. An aggregation of methyl groups is therefore not observed.

Figure 2
The extended arrangement formed by the cations in the crystal structure. Displacement ellipsoids are drawn at the 50% probability level.

4. Computational analysis

To get a more detailed understanding of the bonding situation in the anion, quantum chemical calculations were carried out at the DFT level (B3LYP functional) using def2-TZVP basis sets. To embed the results in a meaningful frame of reference, diazene and methylnitrosamine were used for comparison (Fig. 3). It was found that the methyldiazotate anion tends to have properties most similar to methylnitrosamine. This indicates a high ability to delocalize its sp² electrons.

Figure 3
Rotational potentials of diazene, methylnitrosamine and methyldiazotate. The energetic minima were geometrically optimized and are drawn as thick circles.

By analyzing the rotational potential, the energy barrier of the transition between the cis and trans form was determined to be 173.57 kJ mol⁻¹. The energetic difference between the two forms is 14.30 kJ mol⁻¹, wherein the cis form is energetically preferred. For comparison, the rotational barriers of diazene and methylnitrosamine are calculated to be 317.44 kJ mol⁻¹ and 174.58 kJ mol⁻¹, respectively. The various computational methods employed have been described by Neese (2012 ), Weigend & Ahlrichs (2005 ), Schäfer et al. (1992 , 1994 ), Eichkorn et al. (1997 ), Weigend et al. (2003 ), Metz et al. (2000 ), Dirac (1929 ), Slater (1951 ), Vosko et al. (1980 ), Becke (1988 , 1993 ), Lee et al. (1988 ).

5. Synthesis and crystallization

250 mg (0.94 mmol) of streptozocin and 322 mg (3.8 mmol) of rubidium were placed under an argon atmosphere in a reaction vessel and 20 ml of dry liquid ammonia was condensed. The mixture was stored at 237 K for two weeks to ensure that all substances were completely dissolved. The flask was then stored at 161 K for several months. After that period, clear colorless crystals of the title compound could be found at the bottom of the flask.

6. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 1. All hydrogen atoms could be located in a difference map and were refined freely.

Table 1
Experimental details

Crystal data
Chemical formula	Rb⁺·CH₃N₂O⁻
M_r	144.52
Crystal system, space group	Monoclinic, P2₁/n
Temperature (K)	123
a, b, c (Å)	6.8658 (1), 8.7614 (1), 7.2447 (1)
β (°)	114.219 (2)
V (Å³)	397.44 (1)
Z	4
Radiation type	Mo Kα
μ (mm⁻¹)	12.26
Crystal size (mm)	0.29 × 0.17 × 0.15

Data collection
Diffractometer	Agilent SuperNova Dual Source diffractometer with an Eos detector
Absorption correction	Analytical [CrysAlis PRO (Agilent, 2012 ) based on expressions derived by Clark & Reid (1995 )]
T_min, T_max	0.267, 0.267
No. of measured, independent and observed [I > 2σ(I)] reflections	13443, 1210, 1068
R_int	0.051
(sin θ/λ)_max (Å⁻¹)	0.714

Refinement
R[F² > 2σ(F²)], wR(F²), S	0.017, 0.042, 1.04
No. of reflections	1210
No. of parameters	58
H-atom treatment	All H-atom parameters refined
Δρ_max, Δρ_min (e Å⁻³)	0.56, −0.86
Computer programs: CrysAlis PRO (Agilent, 2012), olex2.solve (Bourhis et al., 2015 ), SHELXL2014 (Sheldrick, 2015 ), DIAMOND (Brandenburg & Putz, 2012 ) and OLEX2 (Dolomanov et al., 2009 ).

Supporting information

CCDC reference: 1524271

Crystal structure: contains datablock I. DOI: https://doi.org/10.1107/S2056989016020429/pk2593sup1.cif

Structure factors: contains datablock I. DOI: https://doi.org/10.1107/S2056989016020429/pk2593Isup2.hkl

checkCIF report

Computing details top

Data collection: CrysAlis PRO (Agilent, 2012); cell refinement: CrysAlis PRO (Agilent, 2012); data reduction: CrysAlis PRO (Agilent, 2012); program(s) used to solve structure: olex2.solve (Bourhis et al., 2015); program(s) used to refine structure: SHELXL2014 (Sheldrick, 2015); molecular graphics: DIAMOND (Brandenburg & Putz, 2012); software used to prepare material for publication: OLEX2 (Dolomanov et al., 2009).

Rubidium methyldiazotate top

Crystal data top

Rb⁺·CH₃N₂O⁻	F(000) = 272
M_r = 144.52	D_x = 2.415 Mg m⁻³
Monoclinic, P2₁/n	Mo Kα radiation, λ = 0.71073 Å
a = 6.8658 (1) Å	Cell parameters from 8481 reflections
b = 8.7614 (1) Å	θ = 3.1–32.1°
c = 7.2447 (1) Å	µ = 12.26 mm⁻¹
β = 114.219 (2)°	T = 123 K
V = 397.44 (1) Å³	Block, colourless
Z = 4	0.29 × 0.17 × 0.15 mm

Data collection top

Agilent SuperNova Dual Source diffractometer with an Eos detector	1210 independent reflections
Radiation source: SuperNova (Mo) X-ray Source	1068 reflections with I > 2σ(I)
Mirror monochromator	R_int = 0.051
Detector resolution: 15.9702 pixels mm^-1	θ_max = 30.5°, θ_min = 3.4°
phi and ω scans	h = −9→9
Absorption correction: analytical [CrysAlis PRO (Agilent, 2012) based on expressions derived by Clark & Reid (1995)]	k = −12→12
T_min = 0.267, T_max = 0.267	l = −10→10
13443 measured reflections

Refinement top

Refinement on F²	0 restraints
Least-squares matrix: full	Hydrogen site location: difference Fourier map
R[F² > 2σ(F²)] = 0.017	All H-atom parameters refined
wR(F²) = 0.042	w = 1/[σ²(F_o²) + (0.0256P)²] where P = (F_o² + 2F_c²)/3
S = 1.04	(Δ/σ)_max = 0.001
1210 reflections	Δρ_max = 0.56 e Å⁻³
58 parameters	Δρ_min = −0.86 e Å⁻³

Special details top

Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes.

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

	x	y	z	U_iso*/U_eq
Rb1	0.24027 (2)	0.64932 (2)	0.44893 (2)	0.01283 (6)
O1	0.6929 (2)	0.68315 (14)	0.5959 (2)	0.0159 (2)
N1	0.7933 (2)	0.67488 (17)	0.4770 (2)	0.0163 (3)
N2	0.8203 (2)	0.79640 (17)	0.3938 (2)	0.0159 (3)
C1	0.7331 (3)	0.9368 (2)	0.4396 (3)	0.0194 (3)
H2	0.583 (3)	0.928 (2)	0.408 (4)	0.027 (6)*
H3	0.753 (3)	1.018 (2)	0.352 (3)	0.016 (5)*
H1	0.812 (4)	0.967 (3)	0.587 (5)	0.049 (9)*

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
Rb1	0.01432 (9)	0.01265 (9)	0.01354 (9)	0.00103 (6)	0.00777 (6)	0.00118 (6)
O1	0.0194 (6)	0.0169 (6)	0.0160 (6)	−0.0005 (4)	0.0120 (5)	0.0004 (5)
N1	0.0190 (7)	0.0167 (8)	0.0158 (7)	0.0019 (5)	0.0098 (6)	0.0009 (6)
N2	0.0204 (7)	0.0145 (6)	0.0163 (7)	0.0029 (6)	0.0112 (6)	0.0019 (6)
C1	0.0294 (9)	0.0126 (8)	0.0223 (9)	0.0019 (7)	0.0167 (8)	0.0002 (7)

Geometric parameters (Å, º) top

Rb1—Rb1ⁱ	4.2210 (2)	N2—Rb1^v	3.0313 (14)
Rb1—Rb1ⁱⁱ	4.2365 (3)	N2—Rb1^vi	3.0761 (15)
Rb1—Rb1ⁱⁱⁱ	5.2757 (2)	N2—C1	1.465 (2)
Rb1—C1^iv	3.7471 (18)	C1—Rb1ⁱ	3.7471 (18)
O1—Rb1ⁱ	2.8496 (12)	C1—Rb1^vi	3.6538 (18)
O1—Rb1ⁱⁱ	2.9871 (12)	C1—Rb1^vii	3.7031 (19)
O1—N1	1.3074 (19)	C1—H2	0.97 (2)
N1—Rb1^v	3.1656 (15)	C1—H3	1.00 (2)
N1—Rb1ⁱⁱ	2.9173 (15)	C1—H1	1.02 (3)
N1—N2	1.274 (2)

Rb1ⁱⁱ—Rb1—Rb1ⁱⁱⁱ	113.582 (6)	Rb1^vii—C1—Rb1ⁱ	90.16 (4)
Rb1ⁱ—Rb1—Rb1ⁱⁱⁱ	85.861 (5)	Rb1^vi—C1—Rb1ⁱ	156.42 (6)
Rb1ⁱ—Rb1—Rb1ⁱⁱ	77.186 (4)	Rb1^vi—C1—Rb1^vii	113.28 (5)
C1^iv—Rb1—Rb1ⁱⁱ	73.60 (3)	Rb1^vii—C1—H2	94.8 (13)
C1^iv—Rb1—Rb1ⁱⁱⁱ	67.80 (3)	Rb1ⁱ—C1—H2	78.4 (15)
C1^iv—Rb1—Rb1ⁱ	127.36 (3)	Rb1^vi—C1—H2	101.1 (15)
Rb1ⁱ—O1—Rb1ⁱⁱ	129.33 (5)	Rb1^vi—C1—H3	58.0 (12)
N1—O1—Rb1ⁱⁱ	74.24 (8)	Rb1^vii—C1—H3	55.4 (12)
N1—O1—Rb1ⁱ	136.30 (10)	Rb1ⁱ—C1—H3	144.9 (12)
Rb1ⁱⁱ—N1—Rb1^v	95.44 (4)	Rb1^vii—C1—H1	63.8 (16)
O1—N1—Rb1^v	146.43 (12)	Rb1ⁱ—C1—H1	39.6 (15)
O1—N1—Rb1ⁱⁱ	80.21 (8)	Rb1^vi—C1—H1	149.8 (14)
N2—N1—Rb1^v	72.28 (9)	N2—C1—Rb1^vii	152.09 (11)
N2—N1—Rb1ⁱⁱ	159.82 (11)	N2—C1—Rb1ⁱ	102.26 (10)
N2—N1—O1	118.93 (13)	N2—C1—Rb1^vi	55.69 (8)
Rb1^v—N2—Rb1^vi	87.43 (4)	N2—C1—H2	112.1 (13)
N1—N2—Rb1^v	84.13 (10)	N2—C1—H3	106.3 (11)
N1—N2—Rb1^vi	128.81 (11)	N2—C1—H1	111.5 (16)
N1—N2—C1	116.27 (13)	H2—C1—H3	108.5 (17)
C1—N2—Rb1^v	141.49 (11)	H2—C1—H1	109 (2)
C1—N2—Rb1^vi	101.15 (10)	H3—C1—H1	109.3 (19)

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

References

Agilent (2012). CrysAlis PRO Agilent Technologies Ltd, Yarnton, England. Google Scholar
Becke, A. D. (1988). Phys. Rev. A, 38, 3098–3100. CrossRef CAS PubMed Web of Science Google Scholar
Becke, A. D. (1993). J. Chem. Phys. 98, 5648–5648. CrossRef CAS Web of Science Google Scholar
Bourhis, L. J., Dolomanov, O. V., Gildea, R. J., Howard, J. A. K. & Puschmann, H. (2015). Acta Cryst. A71, 59–75. Web of Science CrossRef IUCr Journals Google Scholar
Brandenburg, K. & Putz, H. (2012). DIAMOND. Crystal Impact, Bonn, Germany. Google Scholar
Clark, R. C. & Reid, J. S. (1995). Acta Cryst. A51, 887–897. CrossRef CAS Web of Science IUCr Journals Google Scholar
Dirac, P. A. M. (1929). Proc. R. Soc. London A, 123, 714–733. CrossRef CAS Google Scholar
Dolomanov, O. V., Bourhis, L. J., Gildea, R. J., Howard, J. A. K. & Puschmann, H. (2009). J. Appl. Cryst. 42, 339–341. Web of Science CrossRef CAS IUCr Journals Google Scholar
Eichkorn, K., Weigend, F., Treutler, O. & Ahlrichs, R. (1997). Theor. Chem. Acc. 97, 119–124. CrossRef CAS Web of Science Google Scholar
Huber, R., Langer, R. & Hoppe, W. (1965). Acta Cryst. 18, 467–473. CSD CrossRef IUCr Journals Web of Science Google Scholar
Kübler, R. & Lüttke, W. (1963). Ber. Bunsenges. Phys. Chem. 67, 2–16. Google Scholar
Lee, C., Yang, W. & Parr, R. G. (1988). Phys. Rev. B, 37, 786–786. Google Scholar
Metz, B., Stoll, H. & Dolg, M. (2000). J. Chem. Phys. 113, 2563–2563. Web of Science CrossRef CAS Google Scholar
Müller, E., Hoppe, W., Hagenmaier, H., Haiss, H., Huber, R., Rundel, W. & Suhr, H. (1963). Chem. Ber. 96, 1712–1719. Google Scholar
Neese, F. (2012). WIREs Comput. Mol. Sci. 2, 73–78. Web of Science CrossRef CAS Google Scholar
Schäfer, A., Horn, H. & Ahlrichs, R. (1992). J. Chem. Phys. 97, 2571–2577. CrossRef Google Scholar
Schäfer, A., Huber, C. & Ahlrichs, R. (1994). J. Chem. Phys. 100, 5829–5835. Google Scholar
Sheldrick, G. M. (2015). Acta Cryst. C71, 3–8. Web of Science CrossRef IUCr Journals Google Scholar
Slater, J. C. (1951). Phys. Rev. 81, 385–390. CrossRef CAS Web of Science Google Scholar
Suhr, H. (1963). Chem. Ber. 96, 1720–1724. CrossRef CAS Web of Science Google Scholar
Vosko, S. H., Wilk, L. & Nusair, M. (1980). Can. J. Phys. 58, 1200–1211. Web of Science CrossRef CAS Google Scholar
Weigend, F. & Ahlrichs, R. (2005). Phys. Chem. Chem. Phys. 7, 3297–3305. Web of Science CrossRef PubMed CAS Google Scholar
Weigend, F., Furche, F. & Ahlrichs, R. (2003). J. Chem. Phys. 119, 12753–12762. Web of Science CrossRef CAS Google Scholar