Crystal structure of poly[(4-amino-pyridine-κN)(N,N-di-methyl-formamide-κO)(μ3-pyridine-3,5-di-carboxyl-ato-κ(3) N:O (3):O (5))copper(II)].

The title compound, [Cu(C7H3NO4)(C5H6N2)(C3H7NO] n , is an amino-function-alized chiral metal-organic framework with (10,3)-a topology. It has been constructed via the assembly of the achiral triconnected pyridine-3,5-di-carboxyl-ate (3,5-PDC) building block and a triconnected Cu(II) atom. Each Cu(II) ion is coordinated by two O atoms and one N atom, respectively, of three crystallographically independent 3,5-PDC ligands. The square-pyramidal (CuN2O3) coordination geometry of the Cu(II) ion is completed by an N atom of a terminal 4-amino-pyridine (4-APY) ligand and the O atom of a terminal N,N-di-methyl-formamide (DMF) ligand to give a triconnected 'T'-shaped secondary building unit, which becomes trigonal in the resulting (10,3)-a topology. In the three-dimensional structure, weak N-H⋯O hydrogen bonds are observed in which the donor N-H groups are provided by the 4-APY ligands and the acceptor O atoms are provided by the non-coordinating carboxylate O atoms of the 3,5-PDC ligands.

Chemical context

Research on metal–organic frameworks (MOFs) has attracted much attention in recent years not only for their great potential applications, such as in gas storage, separation, fluorescence and magnetism, but also for their intriguing topologies and structural diversity (Allendorf et al., 2009 ▸). Of special inter­est is the rational design and synthesis of chiral networks, which offer great potential in non-linear optics, asymmetric catalysis, and chiral separation (Evans & Lin, 2002 ▸; Zhang & Xiong, 2012 ▸). Therefore, a logical target for synthesis would be a default structure that possesses chirality. The (10,3)-a network meets these requirements since it is mutually chiral and regarded as the default three-dimensional structure for the assembly of triconnected building blocks (Eubank et al., 2005 ▸; Han et al., 2013a ▸).

On the other hand, amino-functionalized porous metal-organic frameworks have also attracted much attention. Recent research on amino-functionalized MOFs revealed that they have high CO2 adsorption capacity at lower pressure due to the potential inter­action between amino groups and CO2 (Couck et al., 2009 ▸). Amino-functionalized MOFs can also act as reaction active sites for the post-synthesis modification of metal-organic frameworks (Shultz et al., 2011 ▸).

As a continuation of our group research on the assembly of amino-functionalized chiral metal–organic frameworks (Han et al., 2011 ▸, 2013b ▸; Pan et al., 2014 ▸), we herein report the preparation and crystal structure of Cu(3,5-PDC)(4-APY)(DMF), (3,5-PDC = pyridine-3,5-di­carboxyl­ate, 4-APY = 4-amino­pyridine, DMF = N,N-di­methyl­formamide), which was constructed via the assembly of the achiral triconnected building block pyridine-3,5-di­carboxyl­ate (3,5- PDC) and a triconnected CuII atom, CuN(CO2)2, synthesized in situ. The title compound is an inter­esting example of an amino-functionalized chiral metal-organic framework with (10,3)-a topology assembled from achiral ligands. This amino-functionalized chiral framework can be used for depositing small gold nanoparticles using a solution-based adsorption/reduction preparation method, and offer myriad opportunities for chiral catalysis.

Structural commentary

The asymmetric unit of the title compound, Cu(3,5-PDC)(4-APY)(DMF), contains one CuII ion, one 3,5-PDC anion, one 4-apy mol­ecule and one DMF mol­ecule. As shown in Fig. 1 ▸, each CuII ion adopts a square-pyramidal (CuN2O3) coordin­ation geometry. In the equatorial plane, the CuII ion is coord­inated by two oxygen atoms and one nitro­gen atom, respectively, of three crystallographically independent 3,5-PDC ligands, and one nitro­gen atom of a terminal 4-APY ligand. The oxygen atom of a terminal DMF mol­ecule is bonded to the CuII ion in the axial position to complete the square-pyramidal coordination geometry. The bond lengths and bond angles around the CuII ion are in good agreement with similar structures (Eubank et al., 2005 ▸; Lu et al., 2006 ▸). The axial Cu—ODMF bond length [2.396 (4) Å] is longer than the equatorial Cu—Ocarboxyl­ate and Cu—N4-APY bonds due to the Jahn–Teller effect of the Cu2+ atom.

Figure 1

The asymmetric unit of title compound, showing the atom-numbering scheme. Displacement ellipsoids are drawn at the 30% probability level. [Symmetry codes: (i) x − , −y + , −z + 1; (ii) −x, y − , −z + ; (iii) −x, y + , −z + ; (iv) x + , −y + , −z + 1.]

The three-dimensional structure of the title compound viewed along the a axis is shown in Fig. 2 ▸. To analyse the topology, the square-pyramidal coordination geometry of copper can act as a ‘T’-shaped triconnected secondary building unit (Fig. 2 ▸), which becomes trigonal in the resulting topology. At the same time, 3,5-PDC acts as another triconnected node since it possesses two deprotonated carb­oxy­lic acid coordin­ating sites, and a third, neutral aromatic nitro­gen coordinating site. As a result, the desired triconnected (10,3)-a network is obtained, as shown in Fig. 3 ▸. The terminally coordinated 4-APY and DMF ligands are oriented to the inter­ior of the channels and thus prevent self-inter­penetration. The (10,3)-a topology leads to an enanti­opure network of the title compound (Eubank et al., 2005 ▸; Han et al., 2013a ▸), despite being formed solely from achiral mol­ecular units.

Figure 2

Crystal packing of the title compound viewed along the a axis, showing hydrogen bonds as dashed lines.

Figure 3

A representation of the (10,3)-a topology.

Supra­molecular features

By introducing 4-amino­pyridine as co-ligand, the amino-functionalized chiral metal-organic framework was successfully designed and synthesized. Additionally, the –NH2 group of the 4-APY ligand can act as the donor N—H groups to form hydrogen bonds (Han et al., 2011 ▸). In the three-dimensional structure of the title compound, weak N—H⋯O hydrogen bonds are observed (Table 1 ▸) in which the acceptors are provided by the non-coordinating oxygen atoms of the carboxyl­ate groups of the 3,5-PDC ligands.

Table 1

Hydrogen-bond geometry (Å, °)

D—H⋯A	D—H	H⋯A	D⋯A	D—H⋯A
N3—H3A⋯O3i	0.86	2.28	3.101 (7)	159
N3—H3B⋯O1ii	0.86	2.23	2.933 (7)	139

Symmetry codes: (i) ; (ii) .

Synthesis and crystallization

The title compound was prepared by a solvothermal method. A mixture of pyridine-3,5-di­carb­oxy­lic acid (0.0339 g, 0.2 mmol), 4-amino­pyridine (0.0098 g, 0.10 mmol) and Cu(NO3)2·3H2O (0.0484 g, 0.20 mmol) in 6 ml DMF solution was stirred at room temperature for 30 minutes, and subsequently sealed in a 25 ml Teflon-lined stainless steel reactor. The reactor was heated at 363 K for 3 d. A crop of blue, block-shaped single crystals of the title compound was obtained after cooling the solution to room temperature. The yield was approximately 70% based on Cu salt.

Refinement details

Crystal data, data collection and structure refinement details are summarized in Table 2 ▸. All H atoms were placed in geometrically idealized positions and refined in a riding-model approximation on their parent atoms, with U iso(H) = 1.2U eq(C) (aromatic) and 1.5U eq(C) (meth­yl) with C—H = 0.93 Å (aromatic) and 0.96 Å (meth­yl), and U iso(H) = 1.2U eq(N) with N—H = 0.86 Å.

Table 2

Experimental details

Crystal data
Chemical formula	[Cu(C7H3NO4)(C5H6N2)(C3H7NO)]
M r	395.86
Crystal system, space group	Orthorhombic, P212121
Temperature (K)	293
a, b, c (Å)	8.3365 (17), 10.453 (2), 19.030 (4)
V (Å3)	1658.2 (6)
Z	4
Radiation type	Mo Kα
μ (mm−1)	1.35
Crystal size (mm)	0.24 × 0.20 × 0.19
Data collection
Diffractometer	Bruker APEXII DUO CCD
Absorption correction	Analytical [based on measured indexed crystal faces using SHELXL2014 (Sheldrick, 2015b ▸)]
T min, T max	0.716, 0.773
No. of measured, independent and observed [I > 2σ(I)] reflections	16376, 3799, 2926
R int	0.051
(sin θ/λ)max (Å−1)	0.649
Refinement
R[F 2 > 2σ(F 2)], wR(F 2), S	0.039, 0.132, 1.15
No. of reflections	3799
No. of parameters	226
H-atom treatment	H-atom parameters constrained
Δρmax, Δρmin (e Å−3)	0.79, −1.17
Absolute structure	Flack (1983 ▸), 1619 Friedel pairs
Absolute structure parameter	0.00 (2)

Computer programs: APEX2 and SAINT (Bruker, 2014 ▸), SHELXT (Sheldrick, 2015a ▸), SHELXL2014 (Sheldrick, 2015b ▸), XP in SHELXTL-Plus (Sheldrick, 2008 ▸) and publCIF (Westrip, 2010 ▸).

Crystal structure: contains datablock(s) I. DOI: 10.1107/S205698901600342X/lh5806sup1.cif

Structure factors: contains datablock(s) I. DOI: 10.1107/S205698901600342X/lh5806Isup2.hkl

CCDC reference: 1456364

Additional supporting information: crystallographic information; 3D view; checkCIF report

[Cu(C7H3NO4)(C5H6N2)(C3H7NO)]	Dx = 1.586 Mg m−3
Mr = 395.86	Mo Kα radiation, λ = 0.71073 Å
Orthorhombic, P212121	Cell parameters from 2974 reflections
a = 8.3365 (17) Å	θ = 3.1–27.5°
b = 10.453 (2) Å	µ = 1.35 mm−1
c = 19.030 (4) Å	T = 293 K
V = 1658.2 (6) Å3	Block, blue
Z = 4	0.24 × 0.20 × 0.19 mm
F(000) = 812

Bruker APEXII DUO CCD diffractometer	3799 independent reflections
Radiation source: fine-focus sealed tube	2926 reflections with I > 2σ(I)
Graphite monochromator	Rint = 0.051
ω–scans	θmax = 27.5°, θmin = 3.1°
Absorption correction: analytical [based on measured indexed crystal faces using SHELXL2014 (Sheldrick, 2015b)]	h = −10→10
Tmin = 0.716, Tmax = 0.773	k = −13→13
16376 measured reflections	l = −24→22

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)] = 0.039	H-atom parameters constrained
wR(F2) = 0.132	w = 1/[σ2(Fo2) + (0.0573P)2 + 1.9518P] where P = (Fo2 + 2Fc2)/3
S = 1.15	(Δ/σ)max = 0.013
3799 reflections	Δρmax = 0.79 e Å−3
226 parameters	Δρmin = −1.16 e Å−3
0 restraints	Absolute structure: Flack (1983), 1619 Friedel pairs
Primary atom site location: structure-invariant direct methods	Absolute structure parameter: 0.00 (2)

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.

Refinement. Refinement of F2 against ALL reflections. The weighted R-factor wR and goodness of fit S are based on F2, conventional R-factors R are based on F, with F set to zero for negative F2. The threshold expression of F2 > σ(F2) is used only for calculating R-factors(gt) etc. and is not relevant to the choice of reflections for refinement. R-factors based on F2 are statistically about twice as large as those based on F, and R- factors based on ALL data will be even larger.

	x	y	z	Uiso*/Ueq
Cu1	−0.23946 (7)	0.10503 (5)	0.62338 (2)	0.02797 (16)
O1	0.0648 (5)	0.3766 (4)	0.83488 (17)	0.0497 (10)
O2	0.2102 (4)	0.5278 (3)	0.78331 (16)	0.0348 (8)
O3	0.3228 (5)	0.4977 (4)	0.5253 (2)	0.0498 (11)
O4	0.2342 (5)	0.3222 (3)	0.47057 (14)	0.0337 (7)
O5	−0.4048 (6)	0.2700 (4)	0.6723 (3)	0.0605 (12)
N1	−0.0413 (5)	0.2178 (4)	0.63928 (18)	0.0284 (8)
N2	−0.4300 (5)	−0.0057 (4)	0.6043 (2)	0.0347 (10)
N3	−0.8209 (6)	−0.2450 (6)	0.5764 (3)	0.0705 (18)
H3A	−0.8050	−0.3239	0.5657	0.085*
H3B	−0.9170	−0.2170	0.5822	0.085*
N4	−0.3401 (8)	0.4804 (5)	0.6705 (3)	0.0625 (17)
C1	0.2489 (6)	0.3962 (4)	0.5239 (2)	0.0315 (9)
C2	0.0476 (6)	0.2565 (4)	0.5840 (2)	0.0291 (10)
H2A	0.0301	0.2180	0.5406	0.035*
C3	0.1883 (6)	0.4086 (5)	0.6536 (2)	0.0297 (10)
H3C	0.2624	0.4745	0.6582	0.036*
C4	0.1634 (6)	0.3505 (4)	0.5889 (2)	0.0267 (9)
C5	−0.0125 (6)	0.2721 (5)	0.7013 (2)	0.0310 (10)
H5A	−0.0716	0.2450	0.7400	0.037*
C6	0.1011 (6)	0.3670 (4)	0.7112 (2)	0.0278 (10)
C7	0.1250 (6)	0.4263 (5)	0.7828 (2)	0.0316 (11)
C8	−0.5796 (7)	0.0376 (5)	0.6086 (3)	0.0448 (13)
H8A	−0.5945	0.1240	0.6183	0.054*
C9	−0.7126 (7)	−0.0366 (5)	0.5999 (3)	0.0502 (15)
H9A	−0.8141	−0.0008	0.6045	0.060*
C10	−0.6962 (7)	−0.1657 (6)	0.5839 (3)	0.0458 (14)
C11	−0.5405 (7)	−0.2092 (5)	0.5747 (3)	0.0521 (15)
H11A	−0.5225	−0.2933	0.5608	0.062*
C12	−0.4130 (7)	−0.1294 (5)	0.5860 (3)	0.0454 (13)
H12A	−0.3100	−0.1621	0.5808	0.055*
C13	−0.3972 (9)	0.3755 (6)	0.7001 (4)	0.0610 (17)
H13A	−0.4348	0.3824	0.7460	0.073*
C14	−0.330 (2)	0.5962 (7)	0.7100 (5)	0.164 (7)
H14A	−0.3715	0.5821	0.7564	0.246*
H14B	−0.3920	0.6616	0.6872	0.246*
H14C	−0.2201	0.6229	0.7130	0.246*
C15	−0.2832 (11)	0.4792 (7)	0.5991 (4)	0.076 (2)
H15A	−0.2989	0.3957	0.5793	0.114*
H15B	−0.1711	0.5001	0.5983	0.114*
H15C	−0.3418	0.5411	0.5720	0.114*

	U11	U22	U33	U12	U13	U23
Cu1	0.0355 (3)	0.0291 (3)	0.0193 (2)	−0.0032 (3)	−0.0035 (2)	0.0024 (2)
O1	0.054 (2)	0.074 (3)	0.0212 (16)	−0.017 (2)	0.0063 (16)	−0.0070 (18)
O2	0.044 (2)	0.0349 (16)	0.0254 (15)	−0.0002 (16)	−0.0046 (15)	−0.0092 (14)
O3	0.064 (3)	0.049 (2)	0.0366 (19)	−0.0273 (19)	0.0124 (19)	−0.0012 (17)
O4	0.051 (2)	0.0313 (15)	0.0188 (12)	0.0015 (17)	0.0056 (16)	0.0016 (12)
O5	0.058 (3)	0.047 (2)	0.077 (3)	−0.005 (2)	0.005 (2)	−0.022 (2)
N1	0.033 (2)	0.034 (2)	0.0183 (17)	−0.0005 (17)	0.0000 (15)	0.0018 (16)
N2	0.033 (2)	0.038 (2)	0.033 (2)	0.0032 (17)	−0.0033 (18)	−0.0002 (17)
N3	0.038 (3)	0.061 (3)	0.113 (5)	−0.018 (3)	0.012 (3)	−0.036 (3)
N4	0.101 (5)	0.037 (3)	0.050 (3)	0.003 (3)	−0.014 (3)	−0.001 (2)
C1	0.035 (2)	0.036 (2)	0.0233 (17)	−0.001 (3)	0.001 (2)	0.0029 (18)
C2	0.036 (3)	0.034 (2)	0.0174 (19)	−0.002 (2)	0.0006 (18)	−0.0017 (19)
C3	0.031 (2)	0.032 (2)	0.026 (2)	−0.001 (2)	0.0001 (17)	−0.002 (2)
C4	0.031 (2)	0.027 (2)	0.022 (2)	0.0041 (18)	0.0027 (18)	−0.0020 (18)
C5	0.038 (3)	0.038 (3)	0.0168 (19)	−0.002 (2)	−0.0006 (19)	0.0007 (19)
C6	0.031 (2)	0.033 (2)	0.0201 (19)	0.0017 (19)	−0.0031 (17)	0.0007 (18)
C7	0.025 (2)	0.046 (3)	0.024 (2)	0.001 (2)	0.0020 (18)	−0.006 (2)
C8	0.047 (3)	0.032 (3)	0.056 (4)	−0.002 (2)	−0.003 (3)	−0.007 (3)
C9	0.036 (3)	0.044 (3)	0.070 (4)	0.004 (3)	0.000 (3)	−0.014 (3)
C10	0.036 (3)	0.046 (3)	0.056 (3)	−0.005 (2)	0.004 (2)	−0.015 (3)
C11	0.047 (3)	0.038 (3)	0.071 (4)	−0.001 (3)	−0.003 (3)	−0.016 (3)
C12	0.038 (3)	0.033 (3)	0.065 (4)	−0.004 (2)	−0.002 (3)	−0.016 (3)
C13	0.069 (4)	0.057 (4)	0.057 (4)	0.004 (3)	−0.005 (3)	−0.011 (3)
C14	0.37 (2)	0.047 (4)	0.079 (6)	−0.036 (8)	−0.019 (9)	−0.014 (4)
C15	0.096 (7)	0.053 (4)	0.079 (5)	0.029 (4)	0.008 (4)	0.011 (3)

Cu1—O4i	1.955 (3)	C2—C4	1.381 (7)
Cu1—O2ii	1.966 (3)	C2—H2A	0.9300
Cu1—N2	1.999 (4)	C3—C6	1.384 (6)
Cu1—N1	2.052 (4)	C3—C4	1.388 (6)
Cu1—O5	2.396 (4)	C3—H3C	0.9300
O1—C7	1.226 (6)	C5—C6	1.384 (7)
O2—C7	1.277 (6)	C5—H5A	0.9300
O2—Cu1iii	1.966 (3)	C6—C7	1.511 (6)
O3—C1	1.228 (6)	C8—C9	1.362 (8)
O4—C1	1.281 (5)	C8—H8A	0.9300
O4—Cu1iv	1.955 (3)	C9—C10	1.390 (8)
O5—C13	1.225 (7)	C9—H9A	0.9300
N1—C5	1.332 (6)	C10—C11	1.387 (8)
N1—C2	1.349 (6)	C11—C12	1.368 (8)
N2—C8	1.330 (7)	C11—H11A	0.9300
N2—C12	1.346 (6)	C12—H12A	0.9300
N3—C10	1.337 (7)	C13—H13A	0.9300
N3—H3A	0.8600	C14—H14A	0.9600
N3—H3B	0.8600	C14—H14B	0.9600
N4—C13	1.322 (8)	C14—H14C	0.9600
N4—C14	1.428 (9)	C15—H15A	0.9600
N4—C15	1.440 (9)	C15—H15B	0.9600
C1—C4	1.506 (6)	C15—H15C	0.9600
O4i—Cu1—O2ii	178.46 (14)	N1—C5—H5A	118.4
O4i—Cu1—N2	88.29 (16)	C6—C5—H5A	118.4
O2ii—Cu1—N2	91.42 (16)	C3—C6—C5	118.5 (4)
O4i—Cu1—N1	90.10 (14)	C3—C6—C7	121.1 (4)
O2ii—Cu1—N1	90.16 (14)	C5—C6—C7	120.4 (4)
N2—Cu1—N1	177.93 (16)	O1—C7—O2	125.0 (5)
O4i—Cu1—O5	90.59 (16)	O1—C7—C6	120.1 (4)
O2ii—Cu1—O5	90.93 (16)	O2—C7—C6	114.9 (4)
N2—Cu1—O5	91.74 (16)	N2—C8—C9	124.2 (5)
N1—Cu1—O5	89.57 (16)	N2—C8—H8A	117.9
C7—O2—Cu1iii	114.6 (3)	C9—C8—H8A	117.9
C1—O4—Cu1iv	118.5 (3)	C8—C9—C10	119.9 (5)
C13—O5—Cu1	141.8 (5)	C8—C9—H9A	120.0
C5—N1—C2	117.7 (4)	C10—C9—H9A	120.0
C5—N1—Cu1	121.4 (3)	N3—C10—C11	120.7 (5)
C2—N1—Cu1	120.0 (3)	N3—C10—C9	123.3 (5)
C8—N2—C12	116.2 (5)	C11—C10—C9	116.0 (5)
C8—N2—Cu1	122.5 (3)	C12—C11—C10	120.5 (5)
C12—N2—Cu1	121.3 (4)	C12—C11—H11A	119.8
C10—N3—H3A	120.0	C10—C11—H11A	119.8
C10—N3—H3B	120.0	N2—C12—C11	123.0 (5)
H3A—N3—H3B	120.0	N2—C12—H12A	118.5
C13—N4—C14	120.0 (7)	C11—C12—H12A	118.5
C13—N4—C15	121.0 (6)	O5—C13—N4	125.5 (6)
C14—N4—C15	119.0 (7)	O5—C13—H13A	117.3
O3—C1—O4	126.0 (4)	N4—C13—H13A	117.3
O3—C1—C4	119.6 (4)	N4—C14—H14A	109.5
O4—C1—C4	114.4 (4)	N4—C14—H14B	109.5
N1—C2—C4	123.0 (4)	H14A—C14—H14B	109.5
N1—C2—H2A	118.5	N4—C14—H14C	109.5
C4—C2—H2A	118.5	H14A—C14—H14C	109.5
C6—C3—C4	119.1 (4)	H14B—C14—H14C	109.5
C6—C3—H3C	120.5	N4—C15—H15A	109.5
C4—C3—H3C	120.5	N4—C15—H15B	109.5
C2—C4—C3	118.4 (4)	H15A—C15—H15B	109.5
C2—C4—C1	120.1 (4)	N4—C15—H15C	109.5
C3—C4—C1	121.3 (4)	H15A—C15—H15C	109.5
N1—C5—C6	123.3 (4)	H15B—C15—H15C	109.5

D—H···A	D—H	H···A	D···A	D—H···A
N3—H3A···O3v	0.86	2.28	3.101 (7)	159
N3—H3B···O1vi	0.86	2.23	2.933 (7)	139