Water-induced pseudo-quadruple hydrogen-bonding motifs in xanthine–inorganic acid complexes

Sridhar, B.

doi:10.1107/S0108270111036493

organic compounds

STRUCTURAL
CHEMISTRY

ISSN: 2053-2296

Volume 67| Part 10| October 2011| Pages o382-o386

doi:10.1107/S0108270111036493

Water-induced pseudo-quadruple hydrogen-bonding motifs in xanthine–inorganic acid complexes

Balasubramanian Sridhar ^a ^*

^aLaboratory of X-ray Crystallography, Indian Institute of Chemical Technology, Hyderabad 500 007, India
^*Correspondence e-mail: sshiya@yahoo.com

(Received 1 July 2011; accepted 7 September 2011; online 15 September 2011)

In xanthinium nitrate hydrate [systematic name: 2,6-dioxo-1,2,3,6-tetrahydro-9H-purin-7-ium nitrate monohydrate], C₅H₅N₄O₂⁺·NO₃⁻·H₂O, (I), and xanthinium hydrogen sulfate hydrate [systematic name: 2,6-dioxo-1,2,3,6-tetrahydro-9H-purin-7-ium hydrogen sulfate monohydrate], C₅H₅N₄O₂⁺·HSO₄⁻·H₂O, (II), the xanthine molecules are protonated at the imine N atom with the transfer of an H atom from the inorganic acid. The asymmetric unit of (I) contains a xanthinium cation, a nitrate anion and one water molecule, while that of (II) contains two crystallographically independent xanthinium cations, two hydrogen sulfate anions and two water molecules. A pseudo-quadruple hydrogen-bonding motif is formed between the xanthinium cations and the water molecules via N—H⋯O and O—H⋯O hydrogen bonds in both structures, and leads to the formation of one-dimensional polymeric tapes. These cation–water tapes are further connected by the respective anions and aggregate into two-dimensional hydrogen-bonded sheets in (I) and three-dimensional arrangements in (II).

Comment

Quadruple hydrogen-bonding motifs (dimeric units held together by four hydrogen bonds between the self-complementary DADA arrays; D = donors and A = acceptor) have received considerable attention in recent decades due to their greater stability compared with double or triple hydrogen-bonding motifs (Beijer et al., 1998 ). This binding pattern is widely utilized to construct dynamic supramolecular polymers (Corbin & Zimmerman, 1998 , 2000 ). Recently, Lafitte et al. (2006 ) reported a new quadruple hydrogen-bonding module based on a ureido-substituted cytosine moiety. Xanthine (3,7-dihydropurine-2,6-dione) is a purine base found in most tissues and fluids in the human body and in other organisms. Xanthine and its nucleotide counterpart xanthosine monophosphate are important intermediates in the metabolism of purines and their nucleotides in cells. A number of mild stimulants are derived from xanthine, including caffeine and theobromine. Xanthine exists as the 2,6-diketone tautomer at neutral pH. It can adopt 14 tautomeric forms through either keto–enol transformation or proton exchange at the ring N atoms. X-ray experiments show that the sodium salt of xanthine is found mainly in the N9-H (ammonium) dioxo tautomeric form in the solid state (Mizuno et al., 1969 ). It was also predicted, on the basis of both semi-empirical and ab initio calculations, that the N7-H (iminium) dioxo tautomeric form of xanthine would be energetically favoured over the N9-H tautomer in the gas phase (Nonella et al., 1993 ). We report here two xanthine–inorganic acid complexes, namely xanthinium nitrate hydrate, (I), and xanthinium hydrogen sulfate hydrate, (II), in continuation of our ongoing studies of hydrogen-bonded interactions and molecular recognition of nucleobases in the solid state (Sridhar & Ravikumar, 2007 , 2008 , 2010 ; Sridhar et al., 2009 ).

In compounds (I) and (II), the bond lengths and angles (Tables 1 and 3) are all normal for their types (Allen et al., 1987 ). The asymmetric unit of (I) contains a xanthinium cation, a nitrate anion and one water molecule (Fig. 1). In (II), the asymmetric unit contains two crystallographically independent xanthinium cations (A and B), two hydrogen sulfate anions (A and B) and two water molecules (O1W and O2W) (Fig. 2). The sulfate anions of (II) exhibit a slightly distorted tetrahedral geometry, with bond lengths and angles typical of those found in several crystal structures of this kind (Cambridge Structural Database, Version 5.32; Allen, 2002 ). Within the anion, the S—OH distance (Table 3) and its participation in the hydrogen bond show that the H-atom site is static, rather than mobile between the O atoms. The O—S—O angles (Table 3) are typical of those found in hydrogen sulfate anions in crystalline salts.

As expected, xanthine forms protonated units in (I) and (II) with the transfer of an H atom from the inorganic acid. A similar situation is observed in xanthinium perchlorate dihydrate (Biradha et al., 2010 ).

Details of the hydrogen-bonding geometries in (I) and (II) are listed in Tables 2 and 4. A number of intermolecular hydrogen bonds stabilize the crystal structure of each compound.

In (I) and (II), the xanthinium cations and water molecules are interlinked by six hydrogen bonds (two N—H⋯O and four O—H⋯O), forming a pseudo-quadruple hydrogen-bonding motif. This motif can be defined in the form of three fused R₃²(8), R₂²(8) and R₃²(8) rings (Fig. 3), in order, using graph-set notation (Etter, 1990 ; Etter et al., 1990 ; Bernstein et al., 1995 ). The xanthinium cations of (I) are held together by N—H⋯O hydrogen bonds, forming a centrosymmetric dimer [R₂²(8) motif]. This centrosymmetric dimer is further connected to either side of the water molecules by O—H⋯O hydrogen bonds [R₃²(8) motifs]. In (II), the two symmetry-independent xanthinium cations are interlinked by two intermolecular N—H⋯O hydrogen bonds to form a noncentrosymmetric dimer, which is further linked by two water molecules through intermolecular O—H⋯O hydrogen bonds.

In (I), the pseudo-quadruple hydrogen-bonding motif is further connected to its translation-related motif at (x + 1, y + 1, z) by an N—H⋯O hydrogen bond involving atom N7 of the xanthinium cation and the water molecule, producing an R₄⁴(14) ring motif. This N—H⋯O hydrogen bond leads to the formation of a one-dimensional polymeric tape parallel to the [110] axis (Fig. 3a). Similarly, in (II), the pseudo-quadruple hydrogen-bonding motif is linked to its neighbouring motif by N—H⋯O hydrogen bonds [R₄⁴(14) motif], generating a one-dimensional polymeric tape parallel to the [10 $[\overline 1]$ ] axis (Fig. 3b).

The crystal packing of (I) reveals the involvement of the nitrate anion in crosslinking the stacks of one-dimensional polymeric tapes into two-dimensional hydrogen-bonded sheets parallel to the (1 $[\overline{1}]$ $[\overline{2}]$ ) plane (Fig. 4). The water molecule is involved in three-centred hydrogen bonding (Jeffrey & Saenger, 1991 ) with the cation and anion to produce an R₂²(6) motif (Fig. 1). Each pseudo-quadruple hydrogen-bonding motif is interlinked to its inversion-related motif by intermolecular N—H⋯O hydrogen bonds involving atom N9 of the xanthinium cation and atom O3 of the nitrate anion. This N—H⋯O hydrogen bond generates a centrosymmetric tetramer and produces a characteristic R₄⁴(16) ring motif. Thus, the combination of N—H⋯O and O—H⋯O hydrogen bonds involving the xanthinium cation, nitrate anion and water molecule forms a centrosymmetric hexamer to produce another R₆⁶(20) ring motif and these aggregate into supramolecular two-dimensional hydrogen-bonded sheets.

In (II), the O—H⋯O hydrogen bonds interconnect two hydrogen sulfate anions into an [–HOSO–HOSO–]_n chain along the c axis with a C₂²(8) graph set. Each anion is involved in two such hydrogen bonds, acting as an H-atom donor in one of them and as an H-atom acceptor in the other. Atoms N3A and N9A of the xanthinium cation link atoms O2A and O2B of the hydrogen sulfate chain through intermolecular N—H⋯O interactions, forming an R₃²(10) motif, while atoms N3B and N9B of the cation link the symmetry-related atoms O4B(−x + 3, y − $[{1\over 2}]$ , −z + 1) and O4A(−x + 3, y − $[{1\over 2}]$ , −z + 2) of the hydrogen sulfate anions to form an R₃³(12) motif. Thus, the infinite anion–anion chain along the crystallographic c axis interlinks the pairs of cation–cation dimers, leading to the formation of a three-dimensional hydrogen-bonded network (Fig. 5). The two water molecules are involved in three-centred hydrogen bonding with the cations and anions to produce an R₂³(8) motif, thus completing the three-dimensional hydrogen-bonded network (Fig. 6).

Overall, in (I), the stacking of the parallel molecular tapes is aligned parallel to the (1 $[\overline{1}]$ $[\overline{2}]$ ) plane, while in (II), the parallel cation–cation dimers are bridged by sulfate anions to form a three-dimensional structure. It is interesting to note that similar cation–cation dimers are observed in the structure of the dixanthinium tetrachloridozinc(II) complex (Hanggi et al., 1992 ), in which the cation–cation dimers are bridged by [ZnCl₄]²⁻ anions. Weak C—H⋯O interactions are also observed in both structures.

Figure 1
The molecular components of (I)

, showing the atom-labelling scheme. Displacement ellipsoids are drawn at the 30% probability level. Hydrogen bonds are shown as dashed lines.

Figure 2
The molecular components of (II)

, showing the atom-labelling scheme. Displacement ellipsoids are drawn at the 30% probability level. Hydrogen bonds are shown as dashed lines.

Figure 3
(a) A view of the one-dimensional polymeric tapes of (I)

, formed along [110] by N—H⋯O and O—H⋯O interactions involving the cations and water molecules. [Symmetry codes: (i) −x + 2, −y + 1, −z + 2; (ii) x + 1, y + 1, z.] (b). A view of the one-dimensional polymeric tapes of (II)

, formed along [10 $[\overline 1]$ ] by N—H⋯O and O—H⋯O interactions involving the cations and water molecules. [Symmetry codes: (i) x + 1, y, z − 1; (iii) x − 1, y, z + 1.] For the sake of clarity, the nitrate anion in (I)

, the two hydrogen sulfate anions in (II)

and H atoms not involved in hydrogen bonding have been omitted. Only atoms involved in hydrogen bonding are labelled.

Figure 4
The crystal structure of (I)

, showing the two-dimensional hydrogen-bonded sheets built from cations, anions and water molecules. For the sake of clarity, H atoms not involved in hydrogen bonding have been omitted. Only atoms involved in hydrogen bonding are labelled. [Symmetry codes: (i) −x + 2, −y + 1, −z + 2; (ii) x + 1, y + 1, z; (iii) −x + 1, −y + 2, −z + 1.]

Figure 5
Part of the crystal structure of (II)

, showing the three-dimensional hydrogen-bonded networks formed by pairs of cation–cation dimers and the infinite anion–anion chain along the crystallographic c axis. For the sake of clarity, the two water molecules (O1W and O2W) and H atoms not involved in hydrogen bonding have been omitted.

Figure 6
Part of the crystal structure of (II)

, showing the hydrogen-bonding interactions (dashed lines). H atoms not involved in hydrogen bonding have been omitted for clarity. [Symmetry codes: (i) x + 1, y, z − 1; (ii) −x + 3, y − $[{1\over 2}]$ , −z + 1; (iii) x − 1, y, z + 1; (iv) −x + 3, y − $[{1\over 2}]$ , −z + 2; (v) x, y, z − 1.]

Experimental

A hot aqueous solution (5 ml) of xanthine (0.150 g, 1 mmol) was mixed with either 65% nitric acid (5 ml) [for the preparation of (I)] or 98% sulfuric acid (5 ml) [for the preparation of (II)]. Crystals of both compounds were obtained from their respective solutions after several weeks by slow evaporation of the aqueous solvent at room temperature.

Compound (I)

Crystal data

C₅H₅N₄O₂⁺·NO₃⁻·H₂O
M_r = 233.16
Triclinic, $[P \overline 1]$
a = 5.0416 (7) Å
b = 7.4621 (10) Å
c = 12.1396 (16) Å
α = 80.248 (2)°
β = 80.800 (2)°
γ = 75.657 (2)°
V = 432.74 (10) Å³
Z = 2
Mo Kα radiation
μ = 0.16 mm⁻¹
T = 294 K
0.21 × 0.18 × 0.09 mm

Data collection

Bruker SMART APEX CCD area-detector diffractometer
4689 measured reflections
1801 independent reflections
1672 reflections with I > 2σ(I)
R_int = 0.019

Refinement

R[F² > 2σ(F²)] = 0.037
wR(F²) = 0.102
S = 1.15
1801 reflections
169 parameters
H atoms treated by a mixture of independent and constrained refinement
Δρ_max = 0.19 e Å⁻³
Δρ_min = −0.28 e Å⁻³

Table 1
Selected bond angles (°) for (I)

C8—N7—C5	107.89 (12)
C8—N9—C4	107.42 (12)

Table 2
Hydrogen-bond geometry (Å, °) for (I)

D—H⋯A	D—H	H⋯A	D⋯A	D—H⋯A
N1—H1N⋯O10ⁱ	0.88 (2)	1.99 (2)	2.8761 (15)	177 (2)
N3—H3N⋯O1	0.85 (2)	1.97 (2)	2.7604 (17)	153 (2)
N7—H7N⋯O1Wⁱⁱ	0.96 (2)	1.69 (2)	2.6233 (17)	162 (2)
N9—H9N⋯O3ⁱⁱⁱ	0.92 (2)	1.88 (3)	2.7878 (17)	168 (2)
O1W—H1W⋯O10	0.80 (3)	2.24 (3)	2.8873 (16)	139 (2)
O1W—H1W⋯O1	0.80 (3)	2.27 (3)	2.8986 (18)	136 (2)
O1W—H2W⋯O11ⁱ	0.80 (3)	2.02 (3)	2.8059 (16)	170 (3)
Symmetry codes: (i) -x+2, -y+1, -z+2; (ii) x+1, y+1, z; (iii) -x+1, -y+2, -z+1.

Compound (II)

Crystal data

C₅H₅N₄O₂⁺·HSO₄⁻·H₂O
M_r = 268.21
Monoclinic, P 2₁
a = 5.183 (5) Å
b = 24.805 (5) Å
c = 7.701 (5) Å
β = 103.510 (5)°
V = 962.7 (11) Å³
Z = 4
Mo Kα radiation
μ = 0.37 mm⁻¹
T = 294 K
0.18 × 0.15 × 0.07 mm

Data collection

Bruker SMART APEX CCD area-detector diffractometer
10396 measured reflections
3998 independent reflections
3939 reflections with I > 2σ(I)
R_int = 0.020

Refinement

R[F² > 2σ(F²)] = 0.030
wR(F²) = 0.080
S = 1.06
3998 reflections
364 parameters
4 restraints
H atoms treated by a mixture of independent and constrained refinement
Δρ_max = 0.46 e Å⁻³
Δρ_min = −0.34 e Å⁻³
Absolute structure: Flack & Bernardinelli (2000 ), with 1946 Friedel pairs
Flack parameter: 0.13 (5)

Table 3
Selected geometric parameters (Å, °) for (II)

S1A—O4A	1.425 (2)
S1A—O3A	1.4453 (17)
S1A—O2A	1.4574 (17)
S1A—O1A	1.5504 (18)
S1B—O3B	1.4148 (19)
S1B—O4B	1.449 (2)
S1B—O2B	1.4877 (16)
S1B—O1B	1.5430 (19)

C8A—N7A—C5A	108.34 (17)
C8A—N9A—C4A	107.53 (18)
C8B—N7B—C5B	107.72 (18)
C8B—N9B—C4B	107.56 (17)
O4A—S1A—O3A	114.17 (12)
O4A—S1A—O2A	112.27 (13)
O3A—S1A—O2A	110.13 (10)
O4A—S1A—O1A	109.33 (11)
O3A—S1A—O1A	104.69 (12)
O2A—S1A—O1A	105.62 (11)
O3B—S1B—O4B	116.08 (13)
O3B—S1B—O2B	113.06 (12)
O4B—S1B—O2B	108.30 (11)
O3B—S1B—O1B	105.74 (13)
O4B—S1B—O1B	108.26 (13)
O2B—S1B—O1B	104.67 (11)

Table 4
Hydrogen-bond geometry (Å, °) for (II)

D—H⋯A	D—H	H⋯A	D⋯A	D—H⋯A
N1A—H1N⋯O10B	0.83 (3)	2.12 (3)	2.949 (2)	173 (2)
N3A—H2N⋯O2A	0.88 (3)	1.83 (3)	2.703 (3)	169 (3)
N7A—H3N⋯O2Wⁱ	0.85 (2)	1.89 (2)	2.710 (3)	162 (4)
N9A—H4N⋯O2B	0.86 (3)	1.96 (3)	2.799 (3)	166 (2)
N1B—H5N⋯O10A	0.97 (4)	1.84 (4)	2.814 (2)	177 (3)
N3B—H6N⋯O4Bⁱⁱ	0.90 (3)	1.93 (3)	2.795 (3)	163 (2)
N7B—H7N⋯O1Wⁱⁱⁱ	0.97 (3)	1.70 (3)	2.657 (3)	167 (3)
N9B—H8N⋯O4A^iv	0.84 (2)	1.91 (2)	2.739 (3)	173 (3)
O1A—H1O⋯O2B	0.81 (2)	1.81 (2)	2.618 (3)	177 (3)
O1B—H2O⋯O3A^v	0.86 (5)	1.78 (5)	2.597 (2)	157 (4)
O1W—H1W⋯O11A	0.90 (3)	1.88 (3)	2.769 (3)	169 (3)
O1W—H2W⋯O10B	0.79 (4)	2.40 (4)	2.992 (3)	133 (4)
O1W—H2W⋯O3Bⁱⁱ	0.79 (4)	2.49 (4)	2.897 (3)	114 (4)
O2W—H3W⋯O2A	0.74 (5)	2.36 (5)	3.016 (3)	149 (4)
O2W—H3W⋯O10A	0.74 (5)	2.57 (5)	3.092 (3)	130 (4)
O2W—H4W⋯O11B	0.79 (4)	2.08 (4)	2.867 (3)	174 (4)
Symmetry codes: (i) x+1, y, z-1; (ii) $[-x+3, y-{\script{1\over 2}}, -z+1]$ ; (iii) x-1, y, z+1; (iv) $[-x+3, y-{\script{1\over 2}}, -z+2]$ ; (v) x, y, z-1.

N-bound H atoms of the xanthinium cations of (I) and (II), O-bound H atoms of the hydrogen sulfate anion of (II) and H atoms of the water molecules of (I) and (II) were located in difference Fourier maps and their positions and isotropic displacement parameters refined. All other H atoms were located in difference density maps, positioned geometrically and included as riding atoms, with C—H = 0.93 Å and U_iso(H) = 1.2U_eq(C). For (II), distance restraints were applied with a set value of 0.87 (2) Å for N7A—H3N and N9B—H8N, and 0.82 (2) Å for O1A—H1O. Compound (II) crystallizes in the noncentrosymmetric space group P2₁ but the structure shows pseudosymmetry, which is fulfilled for approximately 82% of the atoms. Systematic absences show the space group to be P2₁/c, even though the absence condition for a c-glide is not strictly satisfied. The structure was solved in both the P2₁ and P2₁/c space groups. However, the structure refined in the space group P2₁/c showed poor residual factors and abnormal geometric parameters, while the structure refined in the space group P2₁ did not show such problems. The asymmetric unit of (II) also does not show any inversion centre between the sulfate ions. Refinement in a higher symmetric space group is not possible. The value of the Flack parameter (Flack & Bernardinelli, 2000) of (II) may be indicative of a small amount of inversion twinning, although the precision of the value does not allow any definitive conclusion to be drawn.

For both compounds, data collection: SMART (Bruker, 2001 ); cell refinement: SAINT (Bruker, 2001); data reduction: SAINT; program(s) used to solve structure: SHELXS97 (Sheldrick, 2008 ); program(s) used to refine structure: SHELXL97 (Sheldrick, 2008); molecular graphics: DIAMOND (Brandenburg & Putz, 2005 ); software used to prepare material for publication: SHELXL97.

Supporting information

Crystal structure: contains datablocks I, II, global. DOI: 10.1107/S0108270111036493/dn3164sup1.cif

Structure factors: contains datablock I. DOI: 10.1107/S0108270111036493/dn3164Isup2.hkl

Structure factors: contains datablock II. DOI: 10.1107/S0108270111036493/dn3164IIsup3.hkl

Supporting information file. DOI: 10.1107/S0108270111036493/dn3164Isup4.cml

Supporting information file. DOI: 10.1107/S0108270111036493/dn3164IIsup5.cml

Comment top

Quadruple hydrogen-bonding motifs have received considerable attention in recent decades, due to their more stable nature compared with double or triple hydrogen-bonding motifs (Beijer et al., 1998). This binding pattern is widely utilized to construct dynamic supramolecular polymers (Corbin & Zimmerman, 1998, 2000). Recently, Lafitte et al. (2006) reported a new quadruple hydrogen-bonding module based on a ureido-substituted cytosine moiety. Xanthine (3,7-dihydropurine-2,6-dione) is a purine base found in most tissues and fluids in the human body and in other organisms. Xanthine and its nucleotide counterpart xanthosine monophosphate are important intermediates in the metabolism of purines and their nucleotides in cells. A number of mild stimulants are derived from xanthine, including caffeine and theobromine. Xanthine exists as the 2,6-diketone tautomer at neutral pH. It can adopt 14 tautomeric forms through either keto–enol transformation or proton exchange on the ring N atoms. X-ray experiments show that the sodium salt of xanthine is found mainly in the N9H dioxo tautomeric form in the solid state (Mizuno et al., 1969). It was also predicted, on the basis of both semi-empirical and ab initio calculations, that the N7H dioxo tautomeric form of xanthine would be energetically favoured over the N9H tautomer in the gas phase (Nonella et al., 1993). We report here two xanthine–inorganic acid complexes, namely xanthinium nitrate hydrate, (I, and xanthinium hydrogen sulfate hydrate, (II), in continuation of our ongoing studies of hydrogen-bonded interactions and molecular recognition of nucleobases in the solid state (Sridhar & Ravikumar, 2007, 2008, 2010; Sridhar et al., 2009).

In compounds (I) and (II), the bond lengths and angles (Tables 1 and 3) are all normal for their types (Allen et al., 1987). The asymmetric unit of (I) contains a xanthinium cation, a nitrate anion and one water molecule (Fig. 1). In (II), the asymmetric unit contains two crystallographically independent xanthinium cations (A and B), two hydrogen sulfate anions (A and B) and two water molecules (O1W and O2W) (Fig. 2).The sulfate anions of (II) exhibit a slightly distorted tetrahedral geometry, with bond lengths and angles typical of those found in several crystal structures of this kind (Cambridge Structural Database, Version?; Allen, 2002). Within the anion, the S—OH distance (Table 3) and its participation in the hydrogen bond show that the H-atom site is static, rather than mobile between the O atoms. The O—S—O angles (Table 3) are typical of those found in hydrogen sulfate anions in crystalline salts.

As expected, xanthine forms protonated units with the transfer of an H atom from the inorganic acid. Comparison of the bond lengths N7—C8 [1.3125 (19) for (I), and 1.307 (3) and 1.316 (3) for (II)] and C8—N9 [1.345 (2) for (I), and 1.338 (3) and 1.346 (3) for (II)] confirms the protonation of atom N7. A similar trend is also observed in xanthinium perchlorate dihydrate (Biradha et al., 2010)

Details of the hydrogen-bonding geometries in (I) and (II) are listed in Tables 2 and 4. A number of intermolecular hydrogen bonds stabilize the crystal structure of each compound.

In (I) and (II), the xanthinium cation and water molecule are interlinked by six hydrogen bonds (two N—H···O and four O—H···O), forming a pseudo-quadruple hydrogen-bonding motif. This motif can been defined in the form of three fused R₃²(8), R₂²(8) and R₃²(8) rings (Fig. 3), in order, using graph-set notation (Etter, 1990; Etter et al., 1990; Bernstein et al., 1995). The xanthinium cations of (I) are held together by N—H···O hydrogen bonds, forming a centrosymmetric dimer [R₂²(8) motif]. This centrosymmetric dimer is further connected to the water molecule by O—H···O hydrogen bonds [R₃²(8) motif]. In (II), the two xanthinium cations are interlinked by two intermolecular N—H···O hydrogen bonds to form a noncentrosymmetric dimer, which is further linked by two water molecules through intermolecular O—H..O hydrogen bonds.

In (I), the pseudo-quadruple hydrogen-bonding motif is further connected to its translation-related motif at (x + 1, y + 1, z) by an N—H···O hydrogen bond involving atom N7 of the xanthinium cation and the water, producing an R₄⁴(14) ring motif. This N—H···O hydrogen bond leads to the formation of a one-dimensional polymeric tape parallel to the [110] axis (Fig. 3a). Similarly, in (II), the pseudo-quadruple hydrogen-bonding motif is linked to its neighbouring motif by N—H···O hydrogen bonds [R₄⁴(14) motif], generating a one-dimensional polymeric tape parallel to the [101] axis (Fig. 3b).

The crystal packing of (I) reveals the involvement of the nitrate anion in cross-linking the stacks of one-dimensional polymeric tapes into two-dimensional hydrogen-bonded sheets parallel to the (112) plane (Fig. 4). The water molecule is involved in three-centred hydrogen bonding (Jeffrey & Saenger, 1991) with the cation and anion to produce an R₂²(6) motif. Each pseudo-quadruple hydrogen-bonding motif is interlinked to its inversion-related motif by intermolecular N—H···O hydrogen bonds involving atom N9 of the xanthinium cation and atom O3 of the nitrate anion. This N—H···O hydrogen bond generates a centrosymmetric tetramer and produces a characteristic R₄⁴(16) ring motif. Thus, the combination of N—H···O and O—H···O hydrogen bonds involving the xanthinium cation, nitrate anion and water molecule forms a centrosymmetric hexamer to produce another R₆⁶(20) ring motif and these aggregate into supramolecular two-dimensional hydrogen-bonded sheets.

In (II), the O—H···O hydrogen bonds interconnect two hydrogen sulfate anions into an [–HOSO-HOSO–]_n chain along the c axis with a C₂²(8) graph set. Each anion is involved in two such hydrogen bonds, acting as an H-atom donor in one of them and as an H-atom acceptor in the other. Atoms N3A and N9A of the xanthinium cation link atoms O2A and O2B of the hydrogen sulfate chain through intermolecular N—H···O interactions, forming an R₃²(10) motif, while atoms N3B and N9B of the cation link the symmetry-related atoms O4B(-x + 3, y - 1/2, -z + 1) and O4A(-x + 3,y - 1/2, -z + 2) of the hydrogen sulfate anions to form an R₃³(12) motif. Thus, the infinite anion–anion chain along the crystallographic c axis interlinks the pairs of cation–cation dimers, leading to the formation of a three-dimensional hydrogen-bonded network (Fig. 5). The two water molecules are involved in three-centred hydrogen bonding with the cations and anions to produce an R₂³(8) motif, thus completing the three-dimensional hydrogen-bonded network (Fig. 6).

In summary, in (I), the stacking of the parallel molecular tapes is aligned parallel to the (112) plane, while in (II), the parallel cation–cation dimers are bridged by sulfate anions to form a three-dimensional structure. It is interesting to note that similar cation–cation dimers are observed in the structure of the dixanthinium tetrachlorozinc(II) complex (Hanggi et al., 1992), in which the cation–cation dimers are bridged by ZnCl₄ anions. Weak C—H···O interactions are also observed in both structures.

Related literature top

For related literature, see: Allen (2002); Allen et al. (1987); Beijer et al. (1998); Bernstein et al. (1995); Biradha et al. (2010); Corbin & Zimmerman (1998, 2000); Etter (1990); Etter, MacDonald & Bernstein (1990); Flack & Bernardinelli (2000); Hanggi et al. (1992); Jeffrey & Saenger (1991); Lafitte et al. (2006); Mizuno et al. (1969); Nonella et al. (1993); Sridhar & Ravikumar (2007, 2008, 2010); Sridhar et al. (2009).

Experimental top

A hot aqueous solution (5 ml) of xanthine (0.150 g, 1 mmol) was mixed with either 65% nitric acid (5 ml) [for the preparation of (I)] or 98% sulfuric acid (5 ml) [for the preparation of (II)]. Crystals of both compounds were obtained from their respective solutions after several weeks, by slow evaporation of the aqueous solvent at room temperature.

Computing details top

For both compounds, data collection: SMART (Bruker, 2001); cell refinement: SAINT (Bruker, 2001); data reduction: SAINT (Bruker, 2001); program(s) used to solve structure: SHELXS97 (Sheldrick, 2008); program(s) used to refine structure: SHELXL97 (Sheldrick, 2008); molecular graphics: DIAMOND (Brandenburg & Putz, 2005); software used to prepare material for publication: SHELXL97 (Sheldrick, 2008).

Figures top

	Fig. 1. The molecular components of (I), showing the atom-labelling scheme. Displacement ellipsoids are drawn at the 30% probability level. Hydrogen bonds are shown as dashed lines.
	Fig. 2. The molecular components of (II), showing the atom-labelling scheme. Displacement ellipsoids are drawn at the 30% probability level. Hydrogen bonds are shown as dashed lines.
	Fig. 3. (a) A view of the one-dimensional polymeric tapes of (I), formed along [110] by N—H···O and O—H···O interactions involving the cations and water molecules. [Symmetry codes: (i) -x + 2, -y + 1, -z + 2; (ii) x + 1, y + 1, z.] (b). A view ofthe one-dimensional polymeric tapes of (II), formed along [101] by N—H···O and O—H···O interactions involving the cations and water molecules. [Symmetry codes: (i) x + 1, y, z - 1; (iii) x - 1, y, z + 1.] For the sake of clarity, the nitrate anion in (I), the two hydrogen sulfate anions in (II) and H atoms not involved in hydrogen bonding have been omitted. Only atoms involved in hydrogen bonding are labelled.
	Fig. 4. The crystal structure of (I), showing the two-dimensional hydrogen-bonded sheets built from cations, anions and water molecules. For the sake of clarity, H atoms not involved in hydrogen bonding have been omitted. Only atoms involved in hydrogen bonding are labelled. [Symmetry codes: (i) -x + 2, -y + 1, -z + 2; (ii) x + 1, y + 1, z; (iii) -x + 1, -y + 2, -z + 1.]
	Fig. 5. Part of the crystal structure of (II), showing the three-dimensional hydrogen-bonded networks formed by pairs of cation–cation dimers and the anion–anion infinite chain along the crystallographic c axis. For the sake of clarity, the two water molecules (O1W and O2W) and H atoms not involved in hydrogen bonding have been omitted. [Symmetry codes: (ii) -x + 3, y - 1/2, -z + 1; (iv) -x + 3, y - 1/2, -z + 2.]
	Fig. 6. Part of the crystal structure of (II), showing the hydrogen-bonding interactions (dashed lines). H atoms not involved in hydrogen bonding have been omitted for clarity. [Symmetry codes: (i) x + 1, y, z - 1; (ii) -x + 3, y - 1/2, -z + 1; (iii) x - 1, y, z + 1; (iv) -x + 3, y - 1/2, -z + 2; (v) x, y, z - 1.]

(I) 2,6-dioxo-1,2,3,6-tetrahydro-9H-purin-7-ium nitrate monohydrate top

Crystal data top

C₅H₅N₄O₂⁺·NO₃⁻·H₂O	Z = 2
M_r = 233.16	F(000) = 240
Triclinic, P1	D_x = 1.789 Mg m⁻³
Hall symbol: -P 1	Mo Kα radiation, λ = 0.71073 Å
a = 5.0416 (7) Å	Cell parameters from 3003 reflections
b = 7.4621 (10) Å	θ = 2.8–27.9°
c = 12.1396 (16) Å	µ = 0.16 mm⁻¹
α = 80.248 (2)°	T = 294 K
β = 80.800 (2)°	Block, colourless
γ = 75.657 (2)°	0.21 × 0.18 × 0.09 mm
V = 432.74 (10) Å³

Data collection top

Bruker SMART APEX CCD area-detector diffractometer	1672 reflections with I > 2σ(I)
Radiation source: fine-focus sealed tube	R_int = 0.019
Graphite monochromator	θ_max = 26.5°, θ_min = 1.7°
ω scans	h = −6→6
4689 measured reflections	k = −9→9
1801 independent reflections	l = −15→15

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)] = 0.037	Hydrogen site location: inferred from neighbouring sites
wR(F²) = 0.102	H atoms treated by a mixture of independent and constrained refinement
S = 1.15	w = 1/[σ²(F_o²) + (0.0573P)² + 0.0657P] where P = (F_o² + 2F_c²)/3
1801 reflections	(Δ/σ)_max < 0.001
169 parameters	Δρ_max = 0.19 e Å⁻³
0 restraints	Δρ_min = −0.28 e Å⁻³

Crystal data top

C₅H₅N₄O₂⁺·NO₃⁻·H₂O	γ = 75.657 (2)°
M_r = 233.16	V = 432.74 (10) Å³
Triclinic, P1	Z = 2
a = 5.0416 (7) Å	Mo Kα radiation
b = 7.4621 (10) Å	µ = 0.16 mm⁻¹
c = 12.1396 (16) Å	T = 294 K
α = 80.248 (2)°	0.21 × 0.18 × 0.09 mm
β = 80.800 (2)°

Data collection top

Bruker SMART APEX CCD area-detector diffractometer	1672 reflections with I > 2σ(I)
4689 measured reflections	R_int = 0.019
1801 independent reflections

Refinement top

R[F² > 2σ(F²)] = 0.037	0 restraints
wR(F²) = 0.102	H atoms treated by a mixture of independent and constrained refinement
S = 1.15	Δρ_max = 0.19 e Å⁻³
1801 reflections	Δρ_min = −0.28 e Å⁻³
169 parameters

Special details top

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

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

	x	y	z	U_iso*/U_eq
C2	0.8839 (3)	0.67326 (18)	0.85469 (11)	0.0317 (3)
C4	0.9133 (3)	0.95057 (18)	0.73263 (10)	0.0303 (3)
C5	1.0807 (3)	0.99502 (18)	0.79615 (11)	0.0318 (3)
C6	1.1646 (3)	0.87723 (18)	0.89663 (11)	0.0306 (3)
C8	1.0093 (3)	1.2173 (2)	0.65574 (12)	0.0379 (3)
H8	1.0142	1.3270	0.6068	0.045*
N1	1.0543 (2)	0.72169 (16)	0.91742 (10)	0.0335 (3)
H1N	1.098 (4)	0.641 (3)	0.9773 (17)	0.044 (5)*
N3	0.8151 (2)	0.79268 (16)	0.75885 (10)	0.0327 (3)
H3N	0.723 (4)	0.763 (3)	0.7147 (17)	0.050 (5)*
N7	1.1373 (2)	1.16338 (17)	0.74592 (10)	0.0362 (3)
H7N	1.248 (4)	1.231 (3)	0.7721 (16)	0.049 (5)*
N9	0.8699 (2)	1.09049 (16)	0.64468 (10)	0.0345 (3)
H9N	0.766 (5)	1.102 (3)	0.587 (2)	0.067 (6)*
O10	0.7987 (2)	0.53016 (14)	0.88339 (9)	0.0428 (3)
O11	1.3161 (2)	0.90595 (15)	0.95805 (9)	0.0405 (3)
N10	0.3861 (2)	0.67465 (16)	0.58981 (10)	0.0347 (3)
O1	0.5039 (3)	0.60312 (17)	0.67433 (10)	0.0572 (4)
O2	0.2181 (3)	0.60354 (19)	0.56025 (10)	0.0538 (3)
O3	0.4391 (3)	0.82339 (16)	0.53603 (10)	0.0506 (3)
O1W	0.4474 (3)	0.29587 (19)	0.85104 (12)	0.0535 (3)
H1W	0.515 (5)	0.384 (4)	0.8293 (19)	0.064 (6)*
H2W	0.501 (5)	0.231 (4)	0.906 (2)	0.077 (8)*

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
C2	0.0366 (7)	0.0315 (6)	0.0301 (6)	−0.0105 (5)	−0.0122 (5)	−0.0013 (5)
C4	0.0325 (6)	0.0329 (6)	0.0256 (6)	−0.0058 (5)	−0.0083 (5)	−0.0023 (5)
C5	0.0355 (7)	0.0321 (6)	0.0301 (6)	−0.0099 (5)	−0.0100 (5)	−0.0021 (5)
C6	0.0330 (6)	0.0322 (6)	0.0284 (6)	−0.0074 (5)	−0.0094 (5)	−0.0040 (5)
C8	0.0435 (7)	0.0366 (7)	0.0346 (7)	−0.0123 (6)	−0.0114 (6)	0.0033 (5)
N1	0.0418 (6)	0.0333 (6)	0.0287 (6)	−0.0120 (5)	−0.0161 (5)	0.0027 (5)
N3	0.0393 (6)	0.0348 (6)	0.0289 (6)	−0.0127 (5)	−0.0157 (5)	−0.0006 (4)
N7	0.0417 (6)	0.0350 (6)	0.0355 (6)	−0.0142 (5)	−0.0125 (5)	0.0008 (5)
N9	0.0398 (6)	0.0365 (6)	0.0283 (6)	−0.0099 (5)	−0.0128 (5)	0.0022 (5)
O10	0.0563 (6)	0.0379 (6)	0.0425 (6)	−0.0226 (5)	−0.0242 (5)	0.0062 (4)
O11	0.0467 (6)	0.0431 (6)	0.0391 (6)	−0.0168 (5)	−0.0223 (4)	−0.0007 (4)
N10	0.0418 (6)	0.0349 (6)	0.0311 (6)	−0.0123 (5)	−0.0122 (5)	−0.0016 (4)
O1	0.0828 (9)	0.0526 (7)	0.0462 (7)	−0.0292 (6)	−0.0386 (6)	0.0150 (5)
O2	0.0597 (7)	0.0643 (7)	0.0501 (7)	−0.0322 (6)	−0.0199 (5)	−0.0031 (6)
O3	0.0658 (7)	0.0421 (6)	0.0487 (6)	−0.0233 (5)	−0.0212 (5)	0.0106 (5)
O1W	0.0699 (8)	0.0486 (7)	0.0548 (7)	−0.0349 (6)	−0.0342 (6)	0.0145 (6)

Geometric parameters (Å, º) top

C2—O10	1.2247 (17)	C8—N9	1.345 (2)
C2—N3	1.3759 (18)	C8—H8	0.9300
C2—N1	1.3799 (17)	N1—H1N	0.88 (2)
C4—N3	1.3588 (18)	N3—H3N	0.85 (2)
C4—C5	1.3604 (18)	N7—H7N	0.96 (2)
C4—N9	1.3645 (17)	N9—H9N	0.92 (2)
C5—N7	1.3761 (18)	N10—O2	1.2298 (16)
C5—C6	1.4342 (18)	N10—O1	1.2420 (16)
C6—O11	1.2256 (16)	N10—O3	1.2550 (16)
C6—N1	1.3770 (18)	O1W—H1W	0.80 (3)
C8—N7	1.3134 (18)	O1W—H2W	0.80 (3)

O10—C2—N3	121.77 (12)	C6—N1—H1N	117.2 (12)
O10—C2—N1	121.24 (12)	C2—N1—H1N	114.8 (12)
N3—C2—N1	117.00 (12)	C4—N3—C2	118.83 (12)
N3—C4—C5	122.92 (12)	C4—N3—H3N	121.2 (13)
N3—C4—N9	129.65 (12)	C2—N3—H3N	119.8 (13)
C5—C4—N9	107.43 (12)	C8—N7—C5	107.89 (12)
C4—C5—N7	107.28 (12)	C8—N7—H7N	125.5 (11)
C4—C5—C6	121.78 (13)	C5—N7—H7N	126.6 (11)
N7—C5—C6	130.94 (12)	C8—N9—C4	107.42 (12)
O11—C6—N1	122.53 (12)	C8—N9—H9N	123.9 (15)
O11—C6—C5	125.99 (13)	C4—N9—H9N	128.7 (15)
N1—C6—C5	111.49 (11)	O2—N10—O1	121.01 (12)
N7—C8—N9	109.99 (13)	O2—N10—O3	120.55 (12)
N7—C8—H8	125.0	O1—N10—O3	118.43 (12)
N9—C8—H8	125.0	H1W—O1W—H2W	116 (3)
C6—N1—C2	127.98 (11)

N3—C4—C5—N7	−179.41 (12)	N3—C2—N1—C6	0.5 (2)
N9—C4—C5—N7	0.20 (15)	C5—C4—N3—C2	1.0 (2)
N3—C4—C5—C6	−0.3 (2)	N9—C4—N3—C2	−178.52 (13)
N9—C4—C5—C6	179.26 (12)	O10—C2—N3—C4	179.04 (13)
C4—C5—C6—O11	179.42 (13)	N1—C2—N3—C4	−1.02 (19)
N7—C5—C6—O11	−1.8 (2)	N9—C8—N7—C5	0.04 (16)
C4—C5—C6—N1	−0.21 (18)	C4—C5—N7—C8	−0.15 (16)
N7—C5—C6—N1	178.61 (13)	C6—C5—N7—C8	−179.10 (14)
O11—C6—N1—C2	−179.51 (13)	N7—C8—N9—C4	0.08 (16)
C5—C6—N1—C2	0.1 (2)	N3—C4—N9—C8	179.41 (14)
O10—C2—N1—C6	−179.57 (13)	C5—C4—N9—C8	−0.17 (15)

Hydrogen-bond geometry (Å, º) top

D—H···A	D—H	H···A	D···A	D—H···A
N1—H1N···O10ⁱ	0.88 (2)	1.99 (2)	2.8761 (15)	177 (2)
N3—H3N···O1	0.85 (2)	1.97 (2)	2.7604 (17)	153 (2)
N7—H7N···O1Wⁱⁱ	0.96 (2)	1.69 (2)	2.6233 (17)	162 (2)
N9—H9N···O3ⁱⁱⁱ	0.92 (2)	1.88 (3)	2.7878 (17)	168 (2)
O1W—H1W···O10	0.80 (3)	2.24 (3)	2.8873 (16)	139 (2)
O1W—H1W···O1	0.80 (3)	2.27 (3)	2.8986 (18)	136 (2)
O1W—H2W···O11ⁱ	0.80 (3)	2.02 (3)	2.8059 (16)	170 (3)
C8—H8···O2ⁱⁱ	0.93	2.47	3.277 (2)	145
C8—H8···O2ⁱⁱⁱ	0.93	2.42	2.999 (2)	120

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

(II) 2,6-dioxo-1,2,3,6-tetrahydro-9H-purin-7-ium hydrogen sulfate monohydrate top

Crystal data top

C₅H₅N₄O₂⁺·HO₄S⁻·H₂O	F(000) = 552
M_r = 268.21	D_x = 1.851 Mg m⁻³
Monoclinic, P2₁	Mo Kα radiation, λ = 0.71073 Å
Hall symbol: P 2yb	Cell parameters from 9350 reflections
a = 5.183 (5) Å	θ = 2.7–28.0°
b = 24.805 (5) Å	µ = 0.37 mm⁻¹
c = 7.701 (5) Å	T = 294 K
β = 103.510 (5)°	Block, colourless
V = 962.7 (11) Å³	0.18 × 0.15 × 0.07 mm
Z = 4

Data collection top

Bruker SMART APEX CCD area-detector diffractometer	3939 reflections with I > 2σ(I)
Radiation source: fine-focus sealed tube	R_int = 0.020
Graphite monochromator	θ_max = 26.5°, θ_min = 1.6°
ω scans	h = −6→6
10396 measured reflections	k = −31→31
3998 independent reflections	l = −9→9

Refinement top

Refinement on F²	Secondary atom site location: difference Fourier map
Least-squares matrix: full	Hydrogen site location: inferred from neighbouring sites
R[F² > 2σ(F²)] = 0.030	H atoms treated by a mixture of independent and constrained refinement
wR(F²) = 0.080	w = 1/[σ²(F_o²) + (0.0586P)² + 0.1425P] where P = (F_o² + 2F_c²)/3
S = 1.06	(Δ/σ)_max = 0.002
3998 reflections	Δρ_max = 0.46 e Å⁻³
364 parameters	Δρ_min = −0.34 e Å⁻³
4 restraints	Absolute structure: Flack & Bernardinelli (2000), with how many Friedel pairs?
Primary atom site location: structure-invariant direct methods	Absolute structure parameter: 0.13 (5)

Crystal data top

C₅H₅N₄O₂⁺·HO₄S⁻·H₂O	V = 962.7 (11) Å³
M_r = 268.21	Z = 4
Monoclinic, P2₁	Mo Kα radiation
a = 5.183 (5) Å	µ = 0.37 mm⁻¹
b = 24.805 (5) Å	T = 294 K
c = 7.701 (5) Å	0.18 × 0.15 × 0.07 mm
β = 103.510 (5)°

Data collection top

Bruker SMART APEX CCD area-detector diffractometer	3939 reflections with I > 2σ(I)
10396 measured reflections	R_int = 0.020
3998 independent reflections

Refinement top

R[F² > 2σ(F²)] = 0.030	H atoms treated by a mixture of independent and constrained refinement
wR(F²) = 0.080	Δρ_max = 0.46 e Å⁻³
S = 1.06	Δρ_min = −0.34 e Å⁻³
3998 reflections	Absolute structure: Flack & Bernardinelli (2000), with how many Friedel pairs?
364 parameters	Absolute structure parameter: 0.13 (5)
4 restraints

Special details top

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

	x	y	z	U_iso*/U_eq
C2A	1.3429 (4)	0.46306 (8)	0.6082 (3)	0.0278 (4)
C4A	1.3118 (4)	0.51974 (8)	0.3606 (3)	0.0253 (4)
C5A	1.4932 (4)	0.49060 (8)	0.2972 (2)	0.0260 (4)
C6A	1.6203 (4)	0.44469 (8)	0.3924 (3)	0.0279 (4)
C8A	1.3504 (4)	0.55589 (9)	0.1094 (3)	0.0310 (4)
H8A	1.3250	0.5785	0.0104	0.037*
N1A	1.5284 (4)	0.43415 (7)	0.5435 (2)	0.0297 (4)
H1N	1.588 (5)	0.4084 (10)	0.609 (3)	0.027 (6)*
N3A	1.2384 (3)	0.50759 (7)	0.5137 (2)	0.0279 (3)
H2N	1.119 (6)	0.5245 (12)	0.558 (4)	0.040 (7)*
N7A	1.5134 (3)	0.51486 (7)	0.1393 (2)	0.0292 (3)
H3N	1.600 (7)	0.5018 (15)	0.068 (4)	0.072 (11)*
N9A	1.2251 (3)	0.56058 (7)	0.2428 (2)	0.0281 (3)
H4N	1.122 (5)	0.5866 (11)	0.258 (3)	0.029 (6)*
O10A	1.2741 (3)	0.44953 (7)	0.7434 (2)	0.0397 (4)
O11A	1.7897 (3)	0.41685 (6)	0.3492 (2)	0.0379 (4)
C2B	1.6485 (4)	0.32564 (8)	0.8867 (3)	0.0286 (4)
C4B	1.6576 (4)	0.27282 (7)	1.1416 (2)	0.0238 (3)
C5B	1.4802 (4)	0.30477 (8)	1.1969 (2)	0.0260 (4)
C6B	1.3646 (4)	0.35067 (8)	1.0958 (3)	0.0267 (4)
C8B	1.5995 (4)	0.24141 (9)	1.3953 (3)	0.0316 (4)
H8B	1.6133	0.2200	1.4961	0.038*
N1B	1.4657 (4)	0.35717 (7)	0.9447 (2)	0.0313 (4)
H5N	1.402 (7)	0.3884 (16)	0.871 (5)	0.069 (10)*
N3B	1.7438 (3)	0.28130 (7)	0.9899 (2)	0.0277 (3)
H6N	1.825 (5)	0.2571 (11)	0.934 (3)	0.029 (6)*
N7B	1.4475 (4)	0.28433 (7)	1.3572 (2)	0.0299 (3)
H7N	1.332 (6)	0.2988 (13)	1.429 (4)	0.050 (8)*
N9B	1.7320 (3)	0.23320 (7)	1.2668 (2)	0.0287 (3)
H8N	1.812 (5)	0.2049 (9)	1.252 (4)	0.034 (7)*
O10B	1.7199 (3)	0.33619 (7)	0.7508 (2)	0.0396 (4)
O11B	1.1990 (3)	0.38113 (6)	1.1301 (2)	0.0381 (3)
S1A	0.80004 (9)	0.601453 (18)	0.72459 (6)	0.02656 (11)
O1A	0.5882 (3)	0.62314 (7)	0.5631 (2)	0.0412 (4)
H1O	0.660 (6)	0.6251 (13)	0.480 (3)	0.051 (8)*
O2A	0.8671 (4)	0.54763 (7)	0.6732 (2)	0.0469 (4)
O3A	0.6642 (3)	0.59808 (7)	0.8682 (2)	0.0401 (3)
O4A	1.0233 (4)	0.63669 (9)	0.7597 (3)	0.0578 (5)
S1B	0.84164 (9)	0.686166 (18)	0.22880 (6)	0.02849 (12)
O1B	0.6339 (4)	0.68530 (9)	0.0490 (2)	0.0511 (4)
H2O	0.658 (9)	0.6528 (19)	0.018 (6)	0.091 (14)*
O2B	0.8328 (3)	0.63096 (6)	0.3027 (2)	0.0389 (3)
O3B	0.7557 (4)	0.72644 (8)	0.3326 (3)	0.0573 (5)
O4B	1.1010 (4)	0.69425 (8)	0.1926 (3)	0.0554 (5)
O1W	2.0991 (4)	0.33165 (8)	0.5118 (3)	0.0468 (4)
H1W	2.014 (6)	0.3623 (13)	0.469 (4)	0.044 (8)*
H2W	2.066 (8)	0.3192 (18)	0.598 (6)	0.073 (12)*
O2W	0.8743 (4)	0.47062 (9)	0.9774 (3)	0.0450 (4)
H3W	0.923 (9)	0.4832 (18)	0.904 (6)	0.077 (13)*
H4W	0.973 (8)	0.4471 (17)	1.019 (5)	0.063 (10)*

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
C2A	0.0325 (9)	0.0253 (9)	0.0271 (10)	0.0030 (7)	0.0102 (8)	0.0004 (7)
C4A	0.0252 (8)	0.0219 (8)	0.0290 (9)	0.0010 (6)	0.0066 (7)	0.0007 (7)
C5A	0.0288 (8)	0.0267 (9)	0.0239 (8)	−0.0006 (7)	0.0088 (7)	−0.0003 (7)
C6A	0.0273 (9)	0.0271 (9)	0.0302 (9)	0.0004 (7)	0.0082 (7)	−0.0024 (7)
C8A	0.0329 (9)	0.0305 (9)	0.0298 (9)	−0.0027 (7)	0.0079 (8)	0.0068 (7)
N1A	0.0359 (9)	0.0234 (7)	0.0311 (9)	0.0098 (7)	0.0105 (7)	0.0047 (7)
N3A	0.0329 (8)	0.0260 (8)	0.0281 (8)	0.0069 (6)	0.0135 (6)	0.0010 (6)
N7A	0.0304 (8)	0.0330 (9)	0.0268 (8)	0.0004 (7)	0.0121 (6)	0.0007 (7)
N9A	0.0328 (8)	0.0235 (8)	0.0287 (8)	0.0033 (7)	0.0085 (6)	0.0022 (6)
O10A	0.0509 (9)	0.0389 (8)	0.0357 (8)	0.0152 (7)	0.0229 (7)	0.0137 (7)
O11A	0.0384 (8)	0.0366 (8)	0.0420 (9)	0.0148 (6)	0.0160 (7)	0.0020 (6)
C2B	0.0308 (9)	0.0284 (10)	0.0272 (10)	0.0006 (7)	0.0081 (8)	0.0018 (7)
C4B	0.0293 (8)	0.0195 (8)	0.0220 (8)	−0.0001 (7)	0.0047 (6)	−0.0012 (6)
C5B	0.0304 (9)	0.0249 (9)	0.0241 (8)	0.0025 (7)	0.0095 (7)	−0.0007 (7)
C6B	0.0311 (9)	0.0232 (8)	0.0264 (9)	0.0024 (7)	0.0082 (7)	−0.0006 (7)
C8B	0.0380 (10)	0.0314 (10)	0.0259 (9)	0.0011 (8)	0.0086 (7)	0.0037 (8)
N1B	0.0390 (9)	0.0269 (9)	0.0302 (9)	0.0080 (7)	0.0123 (7)	0.0062 (7)
N3B	0.0323 (8)	0.0256 (8)	0.0282 (8)	0.0064 (6)	0.0131 (6)	0.0015 (6)
N7B	0.0357 (9)	0.0287 (8)	0.0271 (8)	0.0009 (6)	0.0110 (6)	0.0006 (6)
N9B	0.0325 (8)	0.0233 (8)	0.0303 (8)	0.0051 (6)	0.0075 (6)	0.0037 (6)
O10B	0.0492 (8)	0.0413 (9)	0.0337 (8)	0.0089 (7)	0.0208 (7)	0.0076 (6)
O11B	0.0438 (8)	0.0349 (8)	0.0388 (8)	0.0146 (6)	0.0163 (6)	0.0034 (6)
S1A	0.0297 (2)	0.0275 (2)	0.0249 (2)	−0.00132 (17)	0.01116 (16)	0.00106 (16)
O1A	0.0383 (8)	0.0525 (10)	0.0343 (8)	0.0050 (7)	0.0115 (6)	0.0136 (7)
O2A	0.0589 (10)	0.0357 (8)	0.0546 (10)	0.0120 (8)	0.0307 (8)	0.0023 (7)
O3A	0.0559 (9)	0.0383 (8)	0.0333 (7)	−0.0014 (7)	0.0250 (6)	−0.0015 (7)
O4A	0.0542 (10)	0.0590 (12)	0.0581 (11)	−0.0254 (9)	0.0087 (8)	0.0045 (9)
S1B	0.0343 (2)	0.0267 (2)	0.0263 (2)	−0.00138 (19)	0.01083 (17)	−0.00025 (17)
O1B	0.0615 (10)	0.0481 (10)	0.0363 (8)	0.0256 (9)	−0.0034 (7)	−0.0068 (8)
O2B	0.0503 (8)	0.0338 (8)	0.0364 (8)	0.0013 (6)	0.0176 (6)	0.0065 (6)
O3B	0.0743 (13)	0.0462 (10)	0.0537 (10)	0.0033 (9)	0.0198 (9)	−0.0223 (8)
O4B	0.0523 (9)	0.0545 (11)	0.0670 (12)	−0.0115 (8)	0.0295 (9)	0.0065 (9)
O1W	0.0545 (10)	0.0447 (9)	0.0509 (10)	0.0205 (8)	0.0316 (8)	0.0173 (8)
O2W	0.0491 (10)	0.0473 (10)	0.0467 (10)	0.0164 (8)	0.0273 (8)	0.0150 (8)

Geometric parameters (Å, º) top

C2A—O10A	1.223 (3)	C5B—C6B	1.430 (3)
C2A—N3A	1.364 (3)	C6B—O11B	1.218 (3)
C2A—N1A	1.382 (3)	C6B—N1B	1.393 (3)
C4A—N3A	1.355 (3)	C8B—N7B	1.316 (3)
C4A—C5A	1.363 (3)	C8B—N9B	1.346 (3)
C4A—N9A	1.364 (3)	C8B—H8B	0.9300
C5A—N7A	1.383 (3)	N1B—H5N	0.97 (4)
C5A—C6A	1.429 (3)	N3B—H6N	0.90 (3)
C6A—O11A	1.222 (3)	N7B—H7N	0.97 (3)
C6A—N1A	1.382 (3)	N9B—H8N	0.835 (17)
C8A—N7A	1.309 (3)	S1A—O4A	1.425 (2)
C8A—N9A	1.343 (3)	S1A—O3A	1.4453 (17)
C8A—H8A	0.9300	S1A—O2A	1.4574 (17)
N1A—H1N	0.83 (3)	S1A—O1A	1.5504 (18)
N3A—H2N	0.88 (3)	O1A—H1O	0.813 (18)
N7A—H3N	0.851 (19)	S1B—O3B	1.4148 (19)
N9A—H4N	0.86 (3)	S1B—O4B	1.449 (2)
C2B—O10B	1.217 (3)	S1B—O2B	1.4877 (16)
C2B—N3B	1.379 (3)	S1B—O1B	1.5430 (19)
C2B—N1B	1.381 (3)	O1B—H2O	0.86 (5)
C4B—C5B	1.356 (3)	O1W—H1W	0.90 (3)
C4B—N3B	1.361 (2)	O1W—H2W	0.79 (4)
C4B—N9B	1.368 (2)	O2W—H3W	0.74 (5)
C5B—N7B	1.381 (3)	O2W—H4W	0.79 (4)

O10A—C2A—N3A	121.22 (19)	N7B—C5B—C6B	130.99 (17)
O10A—C2A—N1A	122.00 (19)	O11B—C6B—N1B	122.10 (18)
N3A—C2A—N1A	116.79 (18)	O11B—C6B—C5B	127.06 (19)
N3A—C4A—C5A	123.42 (18)	N1B—C6B—C5B	110.84 (17)
N3A—C4A—N9A	128.90 (18)	N7B—C8B—N9B	109.88 (19)
C5A—C4A—N9A	107.68 (18)	N7B—C8B—H8B	125.1
C4A—C5A—N7A	106.52 (17)	N9B—C8B—H8B	125.1
C4A—C5A—C6A	120.87 (18)	C2B—N1B—C6B	128.69 (17)
N7A—C5A—C6A	132.61 (17)	C2B—N1B—H5N	115 (2)
O11A—C6A—N1A	122.22 (19)	C6B—N1B—H5N	116 (2)
O11A—C6A—C5A	125.81 (19)	C4B—N3B—C2B	118.23 (17)
N1A—C6A—C5A	111.97 (17)	C4B—N3B—H6N	126.1 (16)
N7A—C8A—N9A	109.92 (18)	C2B—N3B—H6N	113.9 (16)
N7A—C8A—H8A	125.0	C8B—N7B—C5B	107.72 (18)
N9A—C8A—H8A	125.0	C8B—N7B—H7N	126.1 (19)
C6A—N1A—C2A	127.68 (17)	C5B—N7B—H7N	126.2 (19)
C6A—N1A—H1N	120.5 (18)	C8B—N9B—C4B	107.56 (17)
C2A—N1A—H1N	111.8 (18)	C8B—N9B—H8N	125.5 (19)
C4A—N3A—C2A	119.19 (17)	C4B—N9B—H8N	125.0 (19)
C4A—N3A—H2N	126.7 (19)	O4A—S1A—O3A	114.17 (12)
C2A—N3A—H2N	114.0 (19)	O4A—S1A—O2A	112.27 (13)
C8A—N7A—C5A	108.34 (17)	O3A—S1A—O2A	110.13 (10)
C8A—N7A—H3N	127 (3)	O4A—S1A—O1A	109.33 (11)
C5A—N7A—H3N	124 (3)	O3A—S1A—O1A	104.69 (12)
C8A—N9A—C4A	107.53 (18)	O2A—S1A—O1A	105.62 (11)
C8A—N9A—H4N	126.2 (16)	S1A—O1A—H1O	106 (2)
C4A—N9A—H4N	126.0 (16)	O3B—S1B—O4B	116.08 (13)
O10B—C2B—N3B	121.8 (2)	O3B—S1B—O2B	113.06 (12)
O10B—C2B—N1B	121.70 (19)	O4B—S1B—O2B	108.30 (11)
N3B—C2B—N1B	116.47 (18)	O3B—S1B—O1B	105.74 (13)
C5B—C4B—N3B	124.21 (17)	O4B—S1B—O1B	108.26 (13)
C5B—C4B—N9B	107.36 (17)	O2B—S1B—O1B	104.67 (11)
N3B—C4B—N9B	128.41 (18)	S1B—O1B—H2O	99 (3)
C4B—C5B—N7B	107.47 (17)	H1W—O1W—H2W	117 (4)
C4B—C5B—C6B	121.53 (18)	H3W—O2W—H4W	108 (4)

N3A—C4A—C5A—N7A	179.50 (18)	N3B—C4B—C5B—N7B	−178.45 (17)
N9A—C4A—C5A—N7A	0.1 (2)	N9B—C4B—C5B—N7B	0.1 (2)
N3A—C4A—C5A—C6A	−0.5 (3)	N3B—C4B—C5B—C6B	0.8 (3)
N9A—C4A—C5A—C6A	−179.92 (17)	N9B—C4B—C5B—C6B	179.43 (17)
C4A—C5A—C6A—O11A	−178.08 (19)	C4B—C5B—C6B—O11B	177.9 (2)
N7A—C5A—C6A—O11A	1.9 (4)	N7B—C5B—C6B—O11B	−3.0 (4)
C4A—C5A—C6A—N1A	2.3 (3)	C4B—C5B—C6B—N1B	−1.8 (3)
N7A—C5A—C6A—N1A	−177.7 (2)	N7B—C5B—C6B—N1B	177.35 (19)
O11A—C6A—N1A—C2A	178.6 (2)	O10B—C2B—N1B—C6B	−179.9 (2)
C5A—C6A—N1A—C2A	−1.8 (3)	N3B—C2B—N1B—C6B	0.7 (3)
O10A—C2A—N1A—C6A	179.2 (2)	O11B—C6B—N1B—C2B	−178.6 (2)
N3A—C2A—N1A—C6A	−0.6 (3)	C5B—C6B—N1B—C2B	1.0 (3)
C5A—C4A—N3A—C2A	−2.2 (3)	C5B—C4B—N3B—C2B	1.1 (3)
N9A—C4A—N3A—C2A	177.10 (19)	N9B—C4B—N3B—C2B	−177.21 (19)
O10A—C2A—N3A—C4A	−177.16 (19)	O10B—C2B—N3B—C4B	178.88 (19)
N1A—C2A—N3A—C4A	2.6 (3)	N1B—C2B—N3B—C4B	−1.7 (3)
N9A—C8A—N7A—C5A	1.1 (2)	N9B—C8B—N7B—C5B	0.5 (2)
C4A—C5A—N7A—C8A	−0.7 (2)	C4B—C5B—N7B—C8B	−0.4 (2)
C6A—C5A—N7A—C8A	179.3 (2)	C6B—C5B—N7B—C8B	−179.6 (2)
N7A—C8A—N9A—C4A	−1.0 (2)	N7B—C8B—N9B—C4B	−0.4 (2)
N3A—C4A—N9A—C8A	−178.83 (19)	C5B—C4B—N9B—C8B	0.1 (2)
C5A—C4A—N9A—C8A	0.5 (2)	N3B—C4B—N9B—C8B	178.65 (19)

Hydrogen-bond geometry (Å, º) top

D—H···A	D—H	H···A	D···A	D—H···A
N1A—H1N···O10B	0.83 (3)	2.12 (3)	2.949 (2)	173 (2)
N3A—H2N···O2A	0.88 (3)	1.83 (3)	2.703 (3)	169 (3)
N7A—H3N···O2Wⁱ	0.85 (2)	1.89 (2)	2.710 (3)	162 (4)
N9A—H4N···O2B	0.86 (3)	1.96 (3)	2.799 (3)	166 (2)
N1B—H5N···O10A	0.97 (4)	1.84 (4)	2.814 (2)	177 (3)
N3B—H6N···O4Bⁱⁱ	0.90 (3)	1.93 (3)	2.795 (3)	163 (2)
N7B—H7N···O1Wⁱⁱⁱ	0.97 (3)	1.70 (3)	2.657 (3)	167 (3)
N9B—H8N···O4A^iv	0.84 (2)	1.91 (2)	2.739 (3)	173 (3)
O1A—H1O···O2B	0.81 (2)	1.81 (2)	2.618 (3)	177 (3)
O1B—H2O···O3A^v	0.86 (5)	1.78 (5)	2.597 (2)	157 (4)
O1W—H1W···O11A	0.90 (3)	1.88 (3)	2.769 (3)	169 (3)
O1W—H2W···O10B	0.79 (4)	2.40 (4)	2.992 (3)	133 (4)
O1W—H2W···O3Bⁱⁱ	0.79 (4)	2.49 (4)	2.897 (3)	114 (4)
O2W—H3W···O2A	0.74 (5)	2.36 (5)	3.016 (3)	149 (4)
O2W—H3W···O10A	0.74 (5)	2.57 (5)	3.092 (3)	130 (4)
O2W—H4W···O11B	0.79 (4)	2.08 (4)	2.867 (3)	174 (4)
C8A—H8A···O3Aⁱ	0.93	2.33	2.933 (3)	122
C8B—H8B···O3B^vi	0.93	2.57	3.118 (3)	118
C8B—H8B···O4B^iv	0.93	2.59	3.398 (3)	146

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

Experimental details

	(I)	(II)
Crystal data
Chemical formula	C₅H₅N₄O₂⁺·NO₃⁻·H₂O	C₅H₅N₄O₂⁺·HO₄S⁻·H₂O
M_r	233.16	268.21
Crystal system, space group	Triclinic, P1	Monoclinic, P2₁
Temperature (K)	294	294
a, b, c (Å)	5.0416 (7), 7.4621 (10), 12.1396 (16)	5.183 (5), 24.805 (5), 7.701 (5)
α, β, γ (°)	80.248 (2), 80.800 (2), 75.657 (2)	90, 103.510 (5), 90
V (Å³)	432.74 (10)	962.7 (11)
Z	2	4
Radiation type	Mo Kα	Mo Kα
µ (mm⁻¹)	0.16	0.37
Crystal size (mm)	0.21 × 0.18 × 0.09	0.18 × 0.15 × 0.07

Data collection
Diffractometer	Bruker SMART APEX CCD area-detector diffractometer	Bruker SMART APEX CCD area-detector diffractometer
Absorption correction	–	–
No. of measured, independent and observed [I > 2σ(I)] reflections	4689, 1801, 1672	10396, 3998, 3939
R_int	0.019	0.020
(sin θ/λ)_max (Å⁻¹)	0.628	0.628

Refinement
R[F² > 2σ(F²)], wR(F²), S	0.037, 0.102, 1.15	0.030, 0.080, 1.06
No. of reflections	1801	3998
No. of parameters	169	364
No. of restraints	0	4
H-atom treatment	H atoms treated by a mixture of independent and constrained refinement	H atoms treated by a mixture of independent and constrained refinement
Δρ_max, Δρ_min (e Å⁻³)	0.19, −0.28	0.46, −0.34
Absolute structure	?	Flack & Bernardinelli (2000), with how many Friedel pairs?
Absolute structure parameter	?	0.13 (5)

Computer programs: SMART (Bruker, 2001), SAINT (Bruker, 2001), SHELXS97 (Sheldrick, 2008), SHELXL97 (Sheldrick, 2008), DIAMOND (Brandenburg & Putz, 2005).

Selected bond angles (º) for (I) top

C8—N7—C5

107.89 (12)

C8—N9—C4

107.42 (12)

Hydrogen-bond geometry (Å, º) for (I) top

D—H···A	D—H	H···A	D···A	D—H···A
N1—H1N···O10ⁱ	0.88 (2)	1.99 (2)	2.8761 (15)	177 (2)
N3—H3N···O1	0.85 (2)	1.97 (2)	2.7604 (17)	153 (2)
N7—H7N···O1Wⁱⁱ	0.96 (2)	1.69 (2)	2.6233 (17)	162 (2)
N9—H9N···O3ⁱⁱⁱ	0.92 (2)	1.88 (3)	2.7878 (17)	168 (2)
O1W—H1W···O10	0.80 (3)	2.24 (3)	2.8873 (16)	139 (2)
O1W—H1W···O1	0.80 (3)	2.27 (3)	2.8986 (18)	136 (2)
O1W—H2W···O11ⁱ	0.80 (3)	2.02 (3)	2.8059 (16)	170 (3)
C8—H8···O2ⁱⁱ	0.93	2.47	3.277 (2)	145
C8—H8···O2ⁱⁱⁱ	0.93	2.42	2.999 (2)	120

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

Selected geometric parameters (Å, º) for (II) top

S1A—O4A	1.425 (2)	S1B—O3B	1.4148 (19)
S1A—O3A	1.4453 (17)	S1B—O4B	1.449 (2)
S1A—O2A	1.4574 (17)	S1B—O2B	1.4877 (16)
S1A—O1A	1.5504 (18)	S1B—O1B	1.5430 (19)

C8A—N7A—C5A	108.34 (17)	O3A—S1A—O1A	104.69 (12)
C8A—N9A—C4A	107.53 (18)	O2A—S1A—O1A	105.62 (11)
C8B—N7B—C5B	107.72 (18)	O3B—S1B—O4B	116.08 (13)
C8B—N9B—C4B	107.56 (17)	O3B—S1B—O2B	113.06 (12)
O4A—S1A—O3A	114.17 (12)	O4B—S1B—O2B	108.30 (11)
O4A—S1A—O2A	112.27 (13)	O3B—S1B—O1B	105.74 (13)
O3A—S1A—O2A	110.13 (10)	O4B—S1B—O1B	108.26 (13)
O4A—S1A—O1A	109.33 (11)	O2B—S1B—O1B	104.67 (11)

Hydrogen-bond geometry (Å, º) for (II) top

D—H···A	D—H	H···A	D···A	D—H···A
N1A—H1N···O10B	0.83 (3)	2.12 (3)	2.949 (2)	173 (2)
N3A—H2N···O2A	0.88 (3)	1.83 (3)	2.703 (3)	169 (3)
N7A—H3N···O2Wⁱ	0.851 (19)	1.89 (2)	2.710 (3)	162 (4)
N9A—H4N···O2B	0.86 (3)	1.96 (3)	2.799 (3)	166 (2)
N1B—H5N···O10A	0.97 (4)	1.84 (4)	2.814 (2)	177 (3)
N3B—H6N···O4Bⁱⁱ	0.90 (3)	1.93 (3)	2.795 (3)	163 (2)
N7B—H7N···O1Wⁱⁱⁱ	0.97 (3)	1.70 (3)	2.657 (3)	167 (3)
N9B—H8N···O4A^iv	0.835 (17)	1.908 (18)	2.739 (3)	173 (3)
O1A—H1O···O2B	0.813 (18)	1.806 (18)	2.618 (3)	177 (3)
O1B—H2O···O3A^v	0.86 (5)	1.78 (5)	2.597 (2)	157 (4)
O1W—H1W···O11A	0.90 (3)	1.88 (3)	2.769 (3)	169 (3)
O1W—H2W···O10B	0.79 (4)	2.40 (4)	2.992 (3)	133 (4)
O1W—H2W···O3Bⁱⁱ	0.79 (4)	2.49 (4)	2.897 (3)	114 (4)
O2W—H3W···O2A	0.74 (5)	2.36 (5)	3.016 (3)	149 (4)
O2W—H3W···O10A	0.74 (5)	2.57 (5)	3.092 (3)	130 (4)
O2W—H4W···O11B	0.79 (4)	2.08 (4)	2.867 (3)	174 (4)
C8A—H8A···O3Aⁱ	0.93	2.33	2.933 (3)	122.2
C8B—H8B···O3B^vi	0.93	2.57	3.118 (3)	118.1
C8B—H8B···O4B^iv	0.93	2.59	3.398 (3)	146.1

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

Acknowledgements

The author thanks Dr J. S. Yadav, Director, IICT, Hyderabad, for his kind encouragement.

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Volume 67| Part 10| October 2011| Pages o382-o386

doi:10.1107/S0108270111036493

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organic compounds\(\def\hfill{\hskip 5em}\def\hfil{\hskip 3em}\def\eqno#1{\hfil {#1}}\)

Water-induced pseudo-quadruple hydrogen-bonding motifs in xanthine–inorganic acid complexes

Comment

Experimental

Compound (I)

Crystal data

Data collection

Refinement

Compound (II)

Crystal data

Data collection

Refinement

Supporting information

Acknowledgements

References

organic compounds