Abstract
Na·Cu3(BTC)2 and Li·Cu3(BTC)2 (MOF) were synthesized using in situ sodium and lithium doping as hydrogen adsorbing materials. Phase stability and microstructure of the Na·Cu3(BTC)2 and Li·Cu3(BTC)2 materials were characterized by FT-IR, XRD, SEM, BET, and TGA. After in situ ions doping, the basic structures of Na·Cu3(BTC)2 and Li·Cu3(BTC)2 materials were not changed, but the surface area increased from 1300 to 1434 and 1445 m2 g−1, and the amount of hydrogen adsorbed increased from 1 to 1.4 and 1.6 wt% for Na·Cu3(BTC)2 and Li·Cu3(BTC)2 materials, respectively. Enhancement of hydrogen adsorption after sodium and lithium ion doping could be due to physical interaction (binding energy interaction) between hydrogen molecules and sodium ions and also due to increase of the surface area. It maybe that sodium and lithium ions act as an additional adsorption sites and adsorb hydrogen molecules.
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Introduction
Energy is an essential requirement for the development of the modern society. Therefore, energy is a key consideration in discussions of sustainable development. Renewable resources, such as solar energy, winds, waves, and tides are environmental friendly [1]. Hydrogen gas is the ideal energy carrier, due to its zero pollution and high energy density, which is nearly three times that of gasoline [2]. In April 2009, the DOE set the new targets for on-board hydrogen storage systems: 0.045 kg kg−1 for system gravimetric capacity and 0.028 kg L−1 for system volumetric capacity by the year 2010, and 0.055 kg kg−1 and 0.040 kg L−1 by 2011 [3] at an operating temperature of 233–333 K under a maximum delivery pressure of 100 bar [2]. Main challenge in developing this technology is hydrogen storage [4].
Two different storage technologies are conventionally used, i.e. hydrogen gas in high-pressure tanks made of steel or composite material, and liquid hydrogen in cryogenic vessels [5]. Scientists are looking for novel candidate materials which can hold sufficient hydrogen in terms of gravimetric and volumetric densities [3]. An optimum hydrogen storage material must have the following characteristics: (1) high volumetric/gravimetric hydrogen storage capacity, (2) fast absorption kinetics, (3) near room temperature and ambient pressure operation, (4) light weight materials, and (5) low-cost materials [6]. The promising methods include chemical and physical storage. The emergence of many relevant reviews reflects that the field of hydrogen storage materials is receiving much attention [5].
However, so far none is capable of satisfying all the requirements of DOE criteria of size, recharging, kinetics, cost, and safety required for use in transportation [7]. So, a great challenge is the design of new porous materials possessing strong adsorption sites which enable the storage of large amounts of H2 at low pressures [8]. Yaghi and co-workers first reported the hydrogen adsorption properties of MOF-5 at both 78 K and ambient temperature [9]. Metal–organic frameworks (MOFs) are crystalline solids that are assembled by the connection of metal ions or clusters through molecular bridges [10]. MOFs have the highest specific surface areas for porous materials (up to 6200 m2 g−1) and large internal pore volumes with well-defined pore size and apertures [11]. Another interesting feature of MOFs is the great variety of cations, which can participate in the framework [12]. MOFs have attracted worldwide attention in the area of hydrogen energy, particularly for hydrogen storage [3]. These materials store hydrogen in molecular form at low temperatures. Within the micropores the hydrogen is effectively compressed to a high density, resulting in an increase in the volumetric density of the hydrogen in comparison to free gas at the same temperature and pressure [13]. Although some MOFs exhibit remarkable hydrogen storage capacity with maximum hydrogen uptake up to 11 wt%, which exceeds the 2010 DOE hydrogen storage target of 6.0 wt%, and the required low adsorption temperature impedes onboard storage applications. The low uptake temperature is mainly ascribed to the low hydrogen binding energy between the guest H2 molecule and the MOF host framework, which governs adsorption in materials ranging from microporous solids to metal hydrides [14]. Cu3(BTC)2(H2O)3, the so-called Cu-BTC, consists of dimeric Cu(II) paddlewheel units with copper dimers as four connectors and benzene-1,3,5-tricarboxylate as three connectors, forming a cubic, wide-open framework [15]. Basolite™ C300 [16] has unsaturated Cu2+ sites and abundant micropores, e.g. 3.5, 5.0, and 9.0 Å small pores [17]. The shortening of the Cu–Cu distance and the distortion of the Cu–O bonds causes the appearance of coordinatively unsaturated Cu2+ ion sites. The large (hydrophilic) square-shaped pores, of about 0.9 nm diameter, are formed by 12 Cu2(COO)4 paddle-wheel subunits, forming a cuboctahedron. A second pore system of tetrahedron-shaped side pockets, of about 0.5 nm diameter, is built up from four benzene rings that constitute the inner surface with the centers of the rings forming a tetrahedron. These additional pockets are accessible from the larger pores through triangular windows of ca. 0.35 nm diameter [18]. Hydrogen molecules gradually fill the pores from 3.5 to 9.0 Å because the smaller pores have the stronger affinity towards hydrogen due to the overlap of potential fields of two opposing walls. Furthermore, the presence of a number of open metal sites in the Cu3(BTC)2 enhanced its adsorption ability. Therefore, the small pore size and open metal sites in the Cu3(BTC)2 material improve significantly the H2 adsorption capacity at low pressure and at 77 K [17]. The enthalpy of adsorption reflects the binding energy between a guest molecule and its host framework. If porous MOFs can bind hydrogen molecules via interactions stronger than Van der Waals forces but weaker than molecular hydrogen bonds, they offer a possible hydrogen storage option with improved temperature characteristics [14]. To enhance hydrogen binding energy on MOF frameworks, an important report on modified MOFs has changed the status of hydrogen storage in porous MOFs [14]. Various approaches have been pursued for improving the hydrogen adsorption characteristics in these materials [19]. Metal site exposure, metal doping, impregnation, hydrogen spillover, and catenation are currently being investigated [20]. Alkali metal atoms have been found to be good candidates for decorating the MOF structure, because of their low cohesive energies, which can avoid the clustering problem. Much of the recent work has thus been focused on Li-doped MOFs and COFs for hydrogen storage [19]. In this study, Na·Cu3(BTC)2 and Li·Cu3(BTC)2 materials were synthesized using in situ sodium and lithium doping and then the amount of hydrogen adsorbed was measured. So far, some studies report hydrogen adsorption in MMOFs at cryogenic temperatures. Very few ambient temperature hydrogen storage data on MMOFs are available [21]. Since the on-board storage of hydrogen at room temperature is most relevant for practical applications, we have systematically investigated hydrogen adsorption on Li·Cu3(BTC)2 and Na·Cu3(BTC)2 materials at ambient temperature and elevated pressures.
Experimental
Materials
Cupric nitrate trihydrate (Cu(NO3)2·3H2O, 99.5 %), trimesic acid (benzene-1,3,5-tricarboxylic acid (H3BTC, 95 %), sodium acetate trihydrate (CH3COONa·3H2O, 98 %), lithium acetate (C2H3LiO2·2H2O, 98 %), and ethanol (96 %,) were from E. Merck. Deionized water was used for the preparation of aqueous solutions and washing purposes.
In situ synthesis of Na·Cu3(BTC)2 and Li·Cu3(BTC)2 MOF materials
Na·Cu3(BTC)2 and Li·Cu3(BTC)2 materials were prepared using a hydrothermal method reported earlier [22]. The cupric nitrate trihydrate 2.327 g (9.6 mmol) was dissolved into 24 mL deionized water. It was followed by the addition of trimesic acid (benzene-1,3,5-tricarboxylic acid, 1.414 g (6.7 mmol)) to 24 mL of solvent consisting of equal parts of ethanol and deionized water and mixed thoroughly until it was completely dissolved. Sodium acetate, 0.5317 g (3.9 mmol), was added in situ during the synthesis of Cu3(BTC)2 along with the raw materials to synthesize Li·Cu3(BTC)2 and Na·Cu3(BTC)2 MOF. The resultant solution mixture was transferred into a 250-mL Teflon-lined stainless steel autoclave. It was kept at 393 K for 15 h in oven to yield small crystals. Then the autoclave was cooled down to room temperature, and the blue crystals were isolated by filtration. The materials were washed with the mixture of deionized water and ethanol (10:20) several times and then dried at 150 °C. The phase stability and microstructure of the Na·Cu3(BTC)2 and Li·Cu3(BTC)2 were characterized in terms of their properties and structures, using a number of analytical techniques including X-ray diffraction (XRD; BRUKER D8A,Germany, Cu-Kα radiation, 20–70) and scanning electron microscopy (SEM; Hitachi modelSEM3500, Japan) equipped with energy dispersive spectroscopy (EDS). The porosities and specific surface areas were measured with a Micromeritics ASAP 2020 using nitrogen gas at 77 K. Before the measurements, the samples were heated at 120 °C under vacuum for 1.5 h. The hydrogen adsorption measurement (volumetric method) was measured at 298 K and 15 bar pressure using the same gas sorption apparatus. Before the hydrogen-uptake measurement, the samples were heated at 120 °C in vacuum for 1.5 h.
Results and discussion
The phase stability was examined with XRD method. Figure 1 shows XRD patterns of (Li·Cu3(BTC)2 and Na·Cu3(BTC)2)MOF materials. The main peaks and the corresponding crystal planes are identified. The main peaks of the Li·Cu3(BTC)2 and Na·Cu3(BTC)2 materials appeared at 2θ = 11.6° corresponding to d = 7.6°. It should be noted that the positions of the XRD peaks of Cu3(BTC)2 doped with moderate quantities of Li, Na (Li·Cu3(BTC)2, and Na·Cu3(BTC)2) are similar to those of undoped Cu3(BTC)2 [23]. It can be inferred that both undoped Li·Cu3(BTC)2 and Cu3(BTC)2 doped with moderate quantities of Li and Na have the same main cubic structures.
The SEM images of the Li·Cu3(BTC)2 and Na·Cu3(BTC)2 samples are shown in Fig. 2. Dimensions of samples particles are approximately 2 μm. Variations in the crystal structure of the Li·Cu3(BTC)2 and Na·Cu3(BTC)2 samples are the main reason for the differences in their porous and textural properties.
The FT-IR spectra (4600–360 cm−1) were obtained with a resolution of 4 cm−1 at room temperature with a Shimadzu model of 8400S spectrometer, fitted with a DLATGS detector. The samples were previously prepared as KBr mixtures. Figure 3 shows the spectra of Li·Cu3(BTC)2 and Na·Cu3(BTC)2 samples. According to presence possibility of MOFs, sharp and strong bands in the range of 1400–1600 cm−1 refer to stretching vibrations band related to C=C bound in the aromatic ring. The presence of a weak band at 3070 cm−1 related to C–H is an evidence for the presence of aromatic ring. The presence of aromatic ring indicates that organic ligand used in the final sorbent structure has remained as such and not destroyed. The band around 1560–1650 cm−1 can be assigned to vibration of C=O group and the broad bands around 2400–3400 cm−1 can be associated with OH of water and ethanol. The FT-IR spectra in this figure are similar to those of the previous reports [24] and no certain change in the position and shape of the bands have been found, which indicates that the structure of the compound is preserved.
The thermal behavior of Li·Cu3(BTC)2 and Na·Cu3(BTC)2 samples (Fig. 4), shows that the initial weight loss up to 100 °C is due to the loss of water and other guest molecules from the framework. The molecular formula of Li·Cu3(BTC)2 and Na·Cu3(BTC)2 samples is assumed as Li·Cu3(BTC)2(H2O)3·xH2O and Li·Cu3(BTC)2(H2O)3·xH2O, respectively, and number of crystal water (x) about 3.0. After that, the sample does not show any significant weight change up to 320 °C and then gradually starts losing weight. This result confirms the stability of the framework at higher temperature and there are almost no impurities on the structure. A sudden weight change (around 30.08 wt%) is observed at 321 °C due to the total damage of BTC linker and the remaining product was CuO. This high thermal stability of Li·Cu3(BTC)2 and Na·Cu3(BTC)2 samples is favorable for use then in various applications, such as hydrogen gas storage unit integrated to a fuel cell processor.
EDAX spectrum of Na·Cu3(BTC)2 sample is shown in Fig. 5. It is observed that the content of Cu and Na is about 0.26 and 30.94 % in Na·Cu3(BTC)2 sample.
The pore size distribution, number of pores, and exposed surface area have been calculated using the results of N2 adsorption measurements performed on an ASAP 2020 analyzer with built-in software. The N2 adsorption/desorption isotherms of Li·Cu3(BTC)2 and Na·Cu3(BTC)2 samples at 77 K are shown in a type I curve (Fig. 6) [22]. The surface area of Cu3(BTC)2 doped with Li and Na increases from 1300 to 1434 and 1445 m2 g−1 for Li·Cu3(BTC)2 and Na·Cu3(BTC)2 samples, respectively (Table 1).
Hydrogen adsorption measurement
A homemade setup (Fig. 7) was used for the Li·Cu3(BTC)2 and Na·Cu3(BTC)2 samples’ hydrogen storage capacity measurement. The volumetric method for hydrogen uptake measurement is extensively adopted because of its simplicity, low cost, and easy assemblage [25]. At first, 1 g of a sample was loaded in the adsorption reactor (13) and attached to the system. Then, the existing gas inside the system was swept out with helium. To degas the system, the valves 8, 9, 11, and 18 were opened and other valves closed. Then the vacuum pump was turned on, and the system was vacuumed along with the heating temperature of 473 K for 1.5 h (without any loss of crystallinity under the given thermal conditions). After degassing, the system was cooled to ambient temperature. The hydrogen was adsorbed by opening the valves 3, 4, 5, 7, 8, 9, and 10, and closing all other valves. The pressure of HP vessel decreased due to some dead volume in the reactor (including hollow space and the connected tubes) and some adsorption. By measuring the dead volumes, the exact pressure decrease due to hydrogen adsorption is calculated.
The isotherms of hydrogen adsorption on Cu3(BTC)2, Na·Cu3(BTC)2, and Li·Cu3(BTC)2 samples are presented in Fig. 8. The data obtained for Cu3(BTC)2 doped with alkali metal cations (Li and Na) are compared with those obtained for unmodified Cu3(BTC)2. It is interesting to note that the H2 storage capacity of Cu3(BTC)2 doped with Lithium ions is higher than that of Cu3(BTC)2 and Na·Cu3(BTC)2 samples. The remarkable decrease in the surface area at high doping levels suggest that the dopant itself (Li and Na) may ultimately block pores and prevent access to some portions of the MOF, particularly if the dopant ions present with solvent molecules; therefore, in this study moderate amount of dopants were used. In addition, the argument against the dominant role of dopants as special sorption sites is based on the results of experiments in which the level of doping was varied. It is clear that the adsorption of hydrogen in MOF materials depends on the specific surface area and the density of pores within the adsorbent.
Conclusions
MOF are porous hydrogen adsorbents with unusually high surface area. In this study Cu3(BTC)2 (doped and undoped) MOFs were synthesized from readily available and cheap raw materials using a simple procedure. The results have shown that doping Li and Na alkali metals in the MOF structure does not change the main structure of the MOF, but causes an obvious increase in hydrogen adsorption performance of Cu3(BTC)2 at ambient conditions, and this improvement may be due to Van der Waals and charge-quadrupole interactions with hydrogen gas molecules. Due to low cost, simplicity, and high adsorption performance of the proposed adsorbent, it can be a good candidate for hydrogen storage at room temperature.
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Anbia, M., Faryadras, M. In situ Na·Cu3(BTC)2 and Li·Cu3(BTC)2 nanoporous MOFs synthesis for enhancing H2 storage at ambient temperature. J Nanostruct Chem 5, 357–364 (2015). https://doi.org/10.1007/s40097-015-0167-9
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DOI: https://doi.org/10.1007/s40097-015-0167-9