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Synthesis, Photoluminescence and Gas Adsorption Properties of a New Furan-Functionalized MOF and Direct Carbonization for Synthesis of Porous Carbon Jun Zhang, Wenbin Yang, Xiaoyuan Wu, Lei Zhang, and Can-Zhong Lu Cryst. Growth Des., Just Accepted Manuscript • DOI: 10.1021/acs.cgd.5b01481 • Publication Date (Web): 08 Dec 2015 Downloaded from http://pubs.acs.org on December 9, 2015
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Crystal Growth & Design
1
Synthesis, Photoluminescence and Gas Adsorption Properties of
2
a New Furan-Functionalized MOF and Direct Carbonization for
3
Synthesis of Porous Carbon
4
Jun Zhang
5
†Key Laboratory of Design and Assembly of Functional Nanostructures, Fujian
6
Institute of Research on the Structure of Matter, Chinese Academy of Sciences
7
Fuzhou, Fujian 350002, P.R. China
8
‡Fujian Provincial Key Laboratory of Nanomaterials, Fujian Institute of Research on
9
the Structure of Matter, Chinese Academy of Sciences
†,‡,§
†
†
†
†
, Wenbin Yang ,‡, Xiao-Yuan Wu ,‡, Lei Zhang ,‡, and Can-Zhong Lu*, , ‡
10
§University of Chinese Academy of Sciences Beijing, 100049, P.R. China
11
ABSTRACT
12
A new 3D zinc-organic framework of [ZnL]·5H2O (1, K2L = potassium
13
4'-furyl-2,2':6',2"-terpyridine-4,4"-dicarboxylate)
14
hydrothermal conditions. Complex 1 possesses a 3D two-fold interpenetrated
15
4-connected sra network with pores decorated by non-coordination furan rings, and
16
exhibits a broad blue luminescence emission band peaked at 450 nm. Due to the
17
chelating effect of trepyridyl moieties in L2- ligands and the absence of solvent
18
coordination sites on Zn(II), complex 1 exhibits a good thermal and acid-proof
19
stability, and can be directly carbonized at 1000 oC under argon atmosphere into a
20
new microporous carbon material C1000. The gas adsorption properties of desolvated
21
1a and microporous carbon C1000 have been studied by N2 and CO2 sorption
22
measurements.
has
been
synthesized
under
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INTRODUCTION
24
Metal-organic frameworks (MOFs) are a family of porous crystalline materials
25
assembled from metal centers/clusters and organic linkers.1-3 The recent decade has
26
witnessed a continuous and fast development in the research on MOFs due to their
27
structural versatility and chemical nature tunability. In particular, owing to their
28
exceptionally high surface areas and adjustable pore structures, MOFs have been
29
extensively noted as promising porous materials that can be effectively tailored to
30
specific functional applications, such as gas storage and separation,4, 5 catalysis,6, 7
31
proton conductors,8,
32
recently, considerable attention has been paid to the task-specific design and pore
33
surface decoration of MOFs with intriguing architectures and multifunctional
34
properties.15 In comparison with other types of porous materials, such as zeolites and
35
activated carbons, MOFs display many advantages (i. e. high surface area and pore
36
volume, structural tunability and functionalization, and easy synthesis). However, the
37
inherent drawbacks of relatively low thermal and chemical stability for most of MOFs
38
restrict their large-scale applications in practice and developments in industries.1, 3
39
Thermally, MOFs usually can stabilize up to 250 oC beyond which the framework
40
starts to collapse or decompose.16 Otherwise, most MOFs are sensitive to moisture,
41
especially in an acidic or basic medium; MOFs are poorly chemical resistant. Up to
42
date, only a few MOFs show high thermal and chemical stabilities.17, 18 Therefore, the
43
design and synthesis of MOFs with ultrahigh thermal and chemical stability is still
44
challengeable for chemists, but indispensible for practical applications.
9
luminescent sensing materials,10-12 drug delivery.13,
14
More
45
Very recently, MOFs with high thermal stability have been demonstrated as
46
attractive templates to prepare various porous carbon materials19-21 applied extensively
47
in odor absorbers, batteries, supercapacitors and full cells.22 By this pathway, the
48
carbonization of carbon sources (such as furfuryl alcohol) occurs in the pores of
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MOFs.23 However, owing to the large carbon content of origin components in MOFs, 2 ACS Paragon Plus Environment
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Crystal Growth & Design
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it may not be always necessary for introducing additional carbon sources as additives,
51
and MOFs can be carbonized directly in an inert atmosphere to form microporous or
52
nanoporous carbons. Comparing with the traditional methods (i. e. activation of
53
precursors and carbonization of polymer aerogels) for preparing porous carbon
54
materials, the above synthetic pathways using MOFs can produce uniformed porous
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carbons with high surface areas and high adsorption capacity, and therefore promote
56
the practical applications of such materials in H2 storage, CO2 uptake and
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supercapacitor.24
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It is well-known that the instability of MOFs is mostly caused by the change
59
of metal coordination geometry through loss of coordinated solvent molecules during
60
desolvation. One of possible solutions25-27 to this problem is to use multidentate
61
chelating ligands. In [Zn2(bptc)]·4H2O,27 the bptc4- ligand forms two very stable
62
tridentate chelating synthon with metal ions via two carboxylate O and one N donor,
63
and the donor atoms on the ligand occupy all the coordination sites of Zn(II). As a
64
result, the open framework of [Zn2(bptc)] can be stable up to 450oC, and only
65
decomposes in strong acid (e. g. pH < 2) or strong base (pH > 14) media. Our own
66
recent work has focused on the use of polytopic hetero-functional ligands to construct
67
unusual coordination polymers or MOFs.28 Herein, we report a new framework
68
material
69
4'-furyl-2,2':6',2"-terpyridine-4,4"-dicarboxylate (L2-, see Scheme 1). In this
70
multidenate hetero-functional ligand, there is one very stable N-N-N tridentate
71
chelating synthon with metal ions, while the two carboxylates can easily compete
72
with solvent molecules to fulfill the metal coordination geometry, and the furyl
73
moiety can serve as a non-coordination functional group dangling in the pores of
74
framework. As expected, the resulting framework material shows ultrahigh stability
75
(up to 450oC), especially in strong acidic aqueous media (e. g. aqueous HCl with pH
76
= 1), and reversibly absorbs gas molecules into the framework pores. Interestingly,
77
direct carbonization of 1 under argon atmosphere at 1000oC generates porous carbon
[Zn(L)]·5H2O
(1)
based
on
Zn(II)
bound
to
anionic
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C1000. Comparing with 1, although C1000 has a lower surface area, it shows a good
79
CO2 uptake capacity.
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EXPERIMENTAL SECTION
81
All of the regents not specifically listed below were obtained from commercial
82
sources
and
83
4'-furyl-2,2':6',2"-terpyridine-4,4"-dicarboxylic acid (K2L, Scheme 1) was prepared
84
according
85
for C, H, and N were performed on an EA1110 CHNS-0 CE elemental analyzer. The
86
IR spectra were recorded on KBr pellets 4000-500 cm-1 using a PECO (U.S.A.)
87
Spectrum One FT-IR spectrophotometer. Thermal stability studies were carried out on
88
a TGA/DSC 1 STARe system at a heating rate of 10 °C/min, from 35°C to 1000°C
89
under N2 atmosphere. Power X-ray diffraction (PXRD) patterns were measured on a
90
Rigaku Miniflex2 diffractometer with Cu-Kα radiation (λ=1.54056 Å). Fluorescence
91
spectroscopy data were recorded on a FLS920 fluorescence spectrophotometer. Gas
92
adsorption measurements were performed on the ASAP (Accelerated Surface Area
93
and Porosimetry) 2020 System. Scanning electron microscopy (SEM) was performed
94
on a Hitachi SU8010. High-resolution transmission electron microscopy (HR-TEM)
95
images were taken on an FEI Tecnai F20. Raman spectra were obtained using a
96
Renishaw UV-1000 Photon Design spectrometer at 532 nm excitation focused
97
through at 100 × microscope objective for a total interrogation spot size of ~ 1 µm.
98
Scheme 1. Structure of L2-
to
used
the
as
procedure
received.
described
The
potassium
salt
of
previously.29 The elemental analysis
99
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Crystal Growth & Design
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Synthesis of [ZnL]·5H2O (1). In a typical run, Zn(CH3COO)2·2H2O (0.044 g, 0.2
101
mmol), K2L (0.047 g, 0.1 mmol) and CH3COOH (2.0 ml) were stirred in H2O (10.0
102
ml) and sealed in a stainless steel autoclave with a Teflon-liner. The reaction mixture
103
was heated at 180 °C for 120 hours, and then slowly cooled to room temperature,
104
resulting in brown crystals of 1, which were washed several times with H2O, filtered
105
and dried. The yield of the reaction was 42%, based on Zn2+. Elemental analysis calcd
106
(%) for 1 (C21H21N3O10Zn): C 46.64, H 3.91, N 7.77; found: C 47.08, H 3.88, N 7.62;
107
Selected IR (KBr, cm−1): 3410 (br), 1608(s), 1551(s),1482(m), 1456(w) 1363(s),
108
1237(m), 1012(m), 871 (m), 778 (m), 700 (s).
109
Preparation of C1000. The carbonization of as-synthesized 1 was performed under a
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argon flow at a heating rate of 10°C min-1 up to 1000 oC, kept at this temperature for 8
111
h, and then slowly cooled to room temperature. The obtained carbon materials were
112
herein designated as C1000.
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X-ray Crystallography. Diffraction data of 1 were collected at 293 K on a
114
SuperNova Atlas diffractometer equipped with graphite-monochromated Cu-Kα
115
radiation (λ =1.54184 Å). The structure was solved by direct methods, and refined by
116
full-matrix least-squares methods with SHELXL-97 program package.30 All ordered
117
non-hydrogen atoms were refined anisotropically, and hydrogen atoms were placed
118
geometrically and refined with a riding model. One of two non-coordination furan
119
rings was modulated in disorder along the axis defined by the C-C bond between
120
furan ring and the central pyridine ring. The highly disordered guest solvents could
121
not be well modeled in the refinement, so they were removed by using the SQUEEZE
122
option in PLATON. 31 The diffuse electron density in the pore cavities, calculated
123
from SQUEEZE, was at 709 electrons per unit cell, corresponding to ca. 5H2O per
124
[ZnL], which has been confirmed by elemental analysis and TGA. Details for
125
structural analysis are summarized in Table S1.
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RESULTS AND DISCUSSION
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Synthesis and Structural Characterization. The hydrothermal reaction of
129
Zn(CH3COO)2·2H2O with K2L using CH3COOH to adjust pH = 2 at 180 °C for 72
130
hours afford a pure phase of brown block crystals of 1 (42% yield). A series of
131
experimental parameters, such as the reaction time, temperature, solvent and pH, were
132
tested for the formation of the resultant MOF. It was found that in all these factors the
133
pH value (adjusted with acetic acid) play the most important role in affecting the
134
quality of the final crystallized product. The pH value must be adjusted to 2.0 to
135
obtain pure crystalline products.
136
Compound 1 crystallizes in the orthorhombic Pnaa space group, with the
137
asymmetric unit consisting of two Zn2+ ions, two ligands L2−, and shows a new type
138
of two-fold interpenetrated three-dimensional (3D) framework constructed from Zn(II)
139
ions and anionic ligands L2-. Each Zn(1) or Zn(2) ion is coordinated by a tridendate
140
chelating array comprising three pyridyl N-donors all from the same terpyridyl moiety
141
of a L2- ligand, Figure 1a.
142
completed by two carboxylate oxygen atoms, O(7A) and O(9B) from two adjacent L2-
143
ligands, affording a distorted trigonal bipyramidal configuration with the
144
O(7A)-Zn(1)-O(9B) bond angle of 124.09(16)o and the two coordination planes
145
( O(7A)-Zn1-O(9B)-N2 and N1-Zn1-N3 in Figure 1a ) almost perpendicular to each
146
other (dihedral angle 83.991(2)o). The Zn(2) ion is further bound to three carboxylate
147
O atoms from two different L2- ligands, giving O(2C)-Zn(2)-O(3), O(2C)-Zn(2)-O(4)
148
and O(3)-Zn(2)-O(4) bond angles of 93.87(18), 151.2(2) and 57.38(19)o, respectively,
149
with the two coordination planes ( O(2C)-Zn(2)-O(3)-O(4)-N(5) and N(4)-Zn(2)-N(6)
150
in Figure 1a ) almost perpendicular to each other by symmetry ( dihedral angle
151
89.568(1)o ). Therefore, the Zn(2) ion adopts a distorted octahedral coordination
152
geometry. Both Zn-N [2.071(4) – 2.145(3) Å)] and Zn-O bond distances [1.957(3) to
The remaining two coordination sites of the Zn(1) ion are
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2.314(5) Å, see Table S2] are in the normal ranges compared to reported for Zn-O
154
bond lengths found in MOFs.32
155 156
Figure 1. Crystal structure of 1. (a) coordination geometries of Zn(II) and linking modes of L2- ligands
157
(symmetric modes: A, 1-x, -0.5+y, 0.5+z; B, 1-x, -0.5+y, -0.5+z; C, 0.5+x, 0.5-y, z; D, 1-x, 0.5+y,
158
-0.5+z, E, 1-x, 0.5+y, 0.5+z; F, -0.5+x, 0.5-y, z); (b) A schematic view of the polyhedral cage
159
[Zn(1)N3O2] and [Zn(2)N3O3] polyhedra are highlighted in green and turquoise, respectively. The
160
purple bold sticks between Zn(II) centers represent the linkage via pyrindyl-4-carboxylate moieties in
161
L2- ligands); (c) and (d) views of the 3D framework, along the b and c axis, respectively (the
162
non-coordination furan rings are highlighted in spacing mode).
163
In 1, there are two crystallographically independent L2- ligands sustaining the
164
3D framework through different linkages. The first one is almost co-planar, 7 ACS Paragon Plus Environment
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completely parallel to the ab plane, only chelated to the Zn(1) centre via the terpyridyl
166
moiety, and links two Zn(2) ions via carboxylate groups along the a axis of the unit
167
cell; the other is only chelated to the Zn(2) centre via the terpyridyl moiety, and links
168
two Zn(1) ions via carboxylate groups along the c axis of the unit cell. Such linkages
169
result in the formation of a 3D 4-connected sra-type framework (Figure 1c and 1d)
170
with 42.63.8 topology (Figure 2a and Figure S3),33 in which both Zn(1) and Zn(2)
171
centers act as a 4-connecting node, while the pyridyl-4-carboxylate moieties in L2-
172
ligands essentially serve as the linkers between Zn(1) and Zn(2) nodes (Figure 1b).
173
Interestingly, seven Zn(1) and seven Zn(2) centers are alternately bonded by 17
174
pyridyl-4-carboxylate moieties in L2- ligands to form a large irregular polyhedral cage
175
with cavity diameter of ca.10 Å (Figure 1b and Figure S1). Thus, the overall
176
framework of 1 can also be viewed as the closed packing of the irregular polyhedral
177
cages. Meanwhile, 1 shows interconnected channels along all three crystallographic
178
axes. However, both the irregularly hexagonal channels along the a axis (Figure S2a)
179
and the octagonal channels along the c axis (Figure 1d) are split and partly blocked by
180
non-coordination furan rings. The approximate dimension of the square channels
181
(Figure 1c) along the b axis is ca. 8 Å×8 Å, and is defined by the span of the
182
pyridyl-4-carboxylate linker of the bridging ligands. Upon two-fold interpenetration,
183
the square channels are divided into two types of smaller rectangular channels. If
184
considering the van der Waals radius of the nearest atoms, at least one type of
185
rectangular channels are too narrow to allow any solvent molecules to pass the
186
channels, which is clearly shown in the space-filling mode of Figure 2b. However, 1
187
still possesses effective 1D channel when viewed along the c axis (Figure 2c). In fact,
188
the solvent-accessible void for 1 was estimated using software PLATON to be 29.3%
189
of the unit cell volume, and the porosity of desolvated 1a has been confirmed by the
190
adsorption of N2 and CO2.
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Crystal Growth & Design
191 192
Figure 2. (a) the sra 42.63.8 network for 1 (Zn(1) and Zn(2) nodes highlighted in red and blue balls,
193
respectively). (b) and (c) the space-filling
194
viewed along b and c axis, respectively.
195
Thermal and Chemical Stabilities of 1. Remarkably, complex 1 possesses not only
196
open channels decorated with non-coordination furan groups, but also high thermal
197
and acid-proof stability relative to most of known MOFs.34 The thermal stability of 1
198
has been evaluated in the temperature range of 35 – 1000 oC under an N2 stream
199
(Supporting Information, Figure S5). TGA curve of 1 exhibits an initial weight loss of
200
16.1% from 35 to 150 oC, corresponding to the release of trapped molecules in pores
201
(calcd 16.6%), and followed by a relative steady plateau until 450 oC, beyond which
202
the framework of 1 starts to decompose. The crystalline phase purity of 1 was
203
confirmed by comparing experimental PXRD patterns with the simulated one from
204
single-crystal data. As shown in Figure 3a, although some diffraction peaks become
205
weaker along with the increase of acidity, the powder X-ray diffraction (PXRD)
206
patterns of 1 remain almost intact upon immersion in aqueous HCl solutions with
207
different pH values from 0.2 to 7 for 5 days, suggesting that no phase transition or
208
framework collapse occurs upon treatments in acidic aqueous solution. However,
209
complex 1 is unstable in basic solutions. To further evaluate the chemical stability of
210
1 in strong acid solution, as-synthesized samples were soaked in aqueous HCl
211
solution at pH=1 for different times. Strikingly, the results, as shown in Figure 3b,
212
indicated that 1 has good acid resistance even after 30 days. Due to the chelating
213
effect of trepyridyl moieties in L2- ligands and the absence of solvent coordination
mode of the two-fold interpenetrated structure
for 1,
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214
sites on Zn(II), the coordination bonds, as well as the whole framework of 1,
215
become highly resistant to the attack of water and even acid. However, in basic
216
aqueous solutions the strong coordinating ability of hydroxyl ions gradually results in
217
the collapse of framework.
218 219
Figure 3. (a) pH-dependant PXRD patterns of 1 at room temperature. (b) Time-dependant PXRD
220
patterns of 1 immersed in pH = 1 HCl solution.
221
Luminescent Properties of 1. Luminescent MOFs have been extensively
222
investigated owing to their potential applications in chemical sensors, photochemistry,
223
electroluminescent devices, and so on.35 The luminescent property of 1 was
224
investigated in the solid state at room temperature. Upon photo excitation at 370 nm,
225
complex 1 displays a broad blue luminescence emission band peaked at 450 nm
226
(Figure 4). In comparison to the emission peak at 460 nm (λex = 370 nm) of the salt of
227
ligand K2L, the maximum emission of 1 does not exhibit a significant shift, while, its
228
luminescent strength increases notably. The Zn(II) ion has a d10 configuration, which
229
is difficult to oxidize or reduce, and as a result, metal-to-ligand charge transfer
230
(MLCT) or ligand-to-metal charge transfer (LMCT) will not occur in emission.
231
Therefore, the luminescent emission band of 1 can be assigned to the intraligand
232
emission, and the luminescent enhancing is attributed to the coordination bonds
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Crystal Growth & Design
233
between the Zn2+ and the ligand, which adjust the conformational rigidity of ligands
234
and cause the decrease of non-radiation transition.36
235 236
Figure 4. Solid-state emission spectra for the K2L ligand and complex 1.
237
Microporous carbon C1000 prepared by direct carbonization of 1. Recently, high
238
thermal and chemical stable MOFs, such as MOF-5, Al-PCP, and ZIF-8, have been
239
extensively roasted in the presence of additional carbon sources (such as furfuryl
240
alcohol) to prepare porous carbons.37 Hu and co-workers carried out a systematic
241
investigation about the thermal decomposition of MOF-5. Through focusing on the
242
characteristics of decomposed products and study of relative mechanism, they
243
provided significant information of the carbonization of MOFs.38 Considering the
244
large carbon content, the high thermal stability, and the presence of non-coordination
245
furan rings (an analogue to the additional source in preparing porous carbons), a new
246
type of porous carbon materials (C1000) has been successfully prepared by direct
247
carbonation of 1 in argon atmosphere. To the best of our knowledge, this is the first
248
example of directly carbonizing 2-fold interpenetrated MOFs to prepare porous
249
carbon materials. The SEM images indicated that the obtained C1000 retained the
250
bulk morphology of 1 (Figure 5a and 5b). EDX analysis (Figure 5c) indicated that all
251
the Zn metal in 1 has been removed after carbonization at 1000oC. As shown in
252
Figure 5d, the PXRD
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253
and 44°, corresponding to carbon (002) and (101) diffraction peaks, respectively.39
254
The broad nature of diffraction peaks indicates the amorphous feature of C1000. In
255
order to get a better knowledge of C1000, TEM and Raman spectra characterizations
256
were conducted. As clearly observed in Figure 6a and b, C1000 has a porous structure,
257
which is consistent with the result of N2 gas adsorption-desorption isotherm. High
258
resolution TEM (HR-TEM) image (Figure 6c) reveals that C1000 possessed lots of
259
nanopores over the entire particle surface with a graphitic structure. This was
260
confirmed by Raman spectra shown in Figure 6d. The intensity ratio (IG/ID) of the
261
peaks roughly at 1367cm-1 (D band) and 1603cm-1 (G band) is 1.02, which indicates
262
that disordered and graphitic structures were developed in the C1000.40
263 264
Figure 5.(a), (b) SEM images; (c) EDS and (d) PXRD pattern of C1000.
265
Gas Adsorption Studies of desolvated 1a and microporous carbon C1000. The
266
as-synthesized crystals were heated at 120 oC for 24 h under high vacuum to obtain
267
the desolvated sample 1a, and the rigid framework of 1a has been verified by PXRD 12 ACS Paragon Plus Environment
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Crystal Growth & Design
268
pattern (Figure S6). The porosity of desolvated 1a and microporous carbon C1000 has
269
been examined by nitrogen and CO2 absorption experiments. As showed in Figure7a,
270
the N2 adsorption of 1a at 77 K shows a reversible type-I adsorption behavior
271
characteristic
272
Brunauer-Emmett-Teller (BET) and Langmuir surface area of 1a are calculated to be
273
523.6 and 774.7 m2g-1, respectively. Analysis with density functional theory (DFT)
274
from the N2 sorption curve indicates that the size of micropores mainly concentrated
275
around 0.8 nm, which is in accordance with the crystallographic data when van der
276
Waals contact is considered.
of
microporous
material.
Based
on
the
N2
isotherm,
the
277 278
Figure 6. (a), (b) TEM and (c) HR-TEM images of the as-synthesized C1000; (d) Raman spectra of
279
C1000.
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Figure 7. (a) N2 sorption isotherms at 77 K for 1a. Inset: Pore size distribution calculated by DFT. (b)
282
CO2 sorption isotherms for 1a at 273 and 298 K.
283
The CO2 sorption isotherms of 1a, measured at 273 and 298 K under ambient
284
pressure, also display type-I adsorption behavior without any hysteresis (Figure 7b).
285
At 1 bar, 1a shows a relatively high CO2 uptakes of 81.8 cm3g-1 (16.1 wt%) at 273 K
286
and 59.2 cm3g-1 (11.6 wt%) at 298K. These values can be well compared to those
287
reported for many MOFs structures under similar conditions.41 It is well documented
288
that open metal sites in MOFs are very beneficial for enhancing the adsorption
289
capacities of gases. It should be noted that 1a does not have any open metal sites. The
290
non-coordination furan rings, which are located on the wall of pores of 1a and can be
291
as functional group with electron rich property, may play a certain degree of
292
contribution to its relatively high CO2 uptake .42
293
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Crystal Growth & Design
294
Figure 8. (a) N2 sorption isotherms at 77 K for C1000. Inset : Pore size distribution calculated by DFT.
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(b) CO2 sorption isotherms for C1000 at 273 K.
296
The typical type-I isotherm of N2 sorption at 77 K for C1000 also exhibits a
297
steep increase in the very low P/P0 range, suggesting microporsity of the obtained
298
carbon material (Figure 8a). The BET and Langmuir surface areas of C1000 are
299
calculated to be 362.4 and 505.1 m2 g-1, respectively, slightly lower than those of
300
desolvated 1a. Microporous carbon C1000 still exhibits a certain degree of CO2
301
adsorption capacity, with uptake of 64.8 cm3g-1 (12.7 wt%) at 273 K and 1 bar.
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However, a slight hysteresis is observed in contrast to the completely reversible
303
adsorption for 1a, Figure 8b. The hysteresis sorption behavior of C1000 may be
304
attributed to the residual N atoms in carbon material, which derive from N-doped
305
ligand L2- and have a relatively strong interaction with absorbed CO2. Recently, Bai et
306
al used Co-MOF as precursors to prepare multiwalled carbon nanotubes with a high
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BET surface area (400-500m2 g-1) by direct pyrolysis of MOFs particles, in which the
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Co-MOF can provide both carbon sources and metal catalysts for the formation of
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carbon nanotubes during the carbonization. 43 Compared with the metal doped carbon
310
nanotubes, the metal-free C1000 has a lower BET surface area,while, its CO2
311
adsorption capacity (2.9 mol kg-1) doubled that of the CN-1 (1.4 mol kg-1) at 1 bar.
312
CONCLUSION
313
In summary, we have successfully synthesized a new 3D two-fold interpenetrated
314
metal-organic framework 1. Due to the chelating effect of trepyridyl moieties in L2-
315
ligands and the absence of solvent coordination sites on Zn(II), complex 1 exhibits a
316
good thermal and acid-proof stability, and can be directly carbonized into a new
317
microporous carbon material C1000. Both desolvated 1a and the obtained
318
microporous carbon C1000 show a relatively good CO2 sorption capacity. Further
319
studies on supercapacitor electrodes based on such carbon material are underway.
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ASSOCIATED CONTENT
321
Additional structures figures , IR spectra, TGA curve, PXRD patterns,
322
crystallographic data and structure refinement details for complex 1, selected bond
323
lengths and bond angles, TOPOS results, X-ray crystallographic files in CIF format
324
for complex 1 (CCDC: 1431933). This material is available free of charge via the
325
Internet at http://pubs.acs.org.
326
AUTHOR INFORMATION
327
Corresponding Author
328
*E-mail:
[email protected] (C.-Z. L).
329
Notes
330
The authors declare no competing financial interest.
331 332
ACKNOWLEDGMENT
333
This work was supported by the 973 key program of the Chinese Ministry of Science
334
and Technology (MOST) (2012CB821705), the Chinese Academy of Sciences
335
(KJCX2-YW-319, KJCX2-EW-H01), the National Natural Science Foundation of
336
China (21373221, 21221001, 91122027, 51172232, 21403236 ) and the Natural
337
Science Foundation of Fujian Province (2012J06006, 2014J05026, 2006L2005).
338
REFERENCES
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For Table of Contents Use Only
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Synthesis, Photoluminescence and Gas Adsorption Properties of a New Furan-Functionalized MOF and Direct Carbonization for Synthesis of Porous Carbon
428
Jun Zhang
429
†Key Laboratory of Design and Assembly of Functional Nanostructures, Fujian
430
Institute of Research on the Structure of Matter, Chinese Academy of Sciences
431
Fuzhou, Fujian 350002, P.R. China
432
‡Fujian Provincial Key Laboratory of Nanomaterials, Fujian Institute of Research on
433
the Structure of Matter, Chinese Academy of Sciences
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§University of Chinese Academy of Sciences Beijing, 100049, P.R. China
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Corresponding Author: E-mail:
[email protected] †,‡,§
, Wenbin Yang†,‡, Xiao-Yuan Wu†,‡, Lei Zhang†,‡, and Can-Zhong Lu*,†, ‡
436
437 438 439 440 441 442 443 444
We report the synthesis of a new ultra stable MOF with furan-functionalized pores, ZnL•5H2O (1), which can stabilize up to 450℃ and remain stable in HCl solution (pH=1) up o to a month. Direct carbonization of 1 under argon atmosphere at 1000 C generates porous carbon C1000, both complex 1 and C1000 have a rather good CO2 adsorption capacity. At 273 K, the uptake of complex 1 and C1000 under 1 bar reaches 81.8
cm3g-1 (16.1 wt%) and 64.8 cm3g-1 (12.7 wt%), respectively. In addition, complex 1 exhibits an interesting photoluminescence. 19 ACS Paragon Plus Environment
