Effect of structural and thermodynamic factors on the sorption of hydrogen by metal–organic framework compounds

Kolotilov, Sergey V.; Pavlishchuk, V. V.

doi:10.1007/s11237-009-9068-7

Cited by 27 publications

(31 citation statements)

References 93 publications

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“…The assessment of hydrogen density in pores of these compounds at the max imum filling gives values 0.016 and 0.020 g cm -3 for 10 and 11, respectively, and equals 23 and 28% of the hydro gen density at 20 K. These values of H 2 density in pores of the coordination polymers are close to those found earlier. 18 In conclusion, in the present work we found the con ditions for the formation of coordination polymers Fe 2 MO(AcO) 6 (bpy) 1.5 ] n (M = Co, Ni) in the reaction of trinuclear acetate complexes Fe 2 MO(AcO) 6 (H 2 O) 3 with 4,4´ bipyridine. It was shown that the prepared compounds [Fe 2 MO(AcO) 6 (bpy) 1.5 ] n are able to adsorb nitrogen and hydrogen.…”

Section: Resultssupporting

confidence: 59%

Structures and sorption properties of the coordination polymers built up of 3d metal carboxylate polynuclear complexes

et al. 2010

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The reaction of trinuclear acetate complexes Fe 2 MO(AcO) 6 (H 2 O) 3 (M = Ni 2+ , Co 2+ ) with 4,4´ bipyridine (bpy) results, depending on the reaction conditions, in porous coordination polymers with the composition Fe 2 MO(AcO) 6 (bpy) 1.5 (with retention of the metal core Fe 2 MO(AcO) 6 ) or nonporous coordination polymers with the composition M 2 (AcO) 4 (bpy) 2 (with destruction of the metal core Fe 2 MO(AcO) 6 ). The adsorption and desorption properties of the compounds Fe 2 MO(AcO) 6 (bpy) 1.5 with respect to nitrogen and hydrogen were studied. The reaction of hexanuclear benzoate complex Mn 6 O 2 (PhCOO) 10 (MeCN) 4 with bpy or trans 1,2 bis(4 pyridyl)ethylene (bpe) in DMF results in destruction of the metal core Mn 6 O 2 (PhCOO) 10 and formation of nonporous coordination polymers, while the pivalate com plex Mn 6 O 2 (Piv) 10 (EtOH) 3 (HPiv) under the same conditions gives rise to the coordination polymer containing Mn 6 O 2 (Piv) 10 structural blocks.The interest in porous coordination polymers (PCP) built up of 3d metals is caused by several reasons, in par ticular, by the possibility of creation of polyfunctional materials on the base of such compounds that can find application as magnetic materials with controlled proper ties as well as active components of sensors. 1-3 The po rous coordination polymers can possess the combination of properties that is unattainable in the case of other class es of compounds, for example, the ability to adsorb cer tain substrates (including gases) along with nontrivial mag netic properties caused by the exchange interaction of un paired electrons. However, the problem of effective di rected synthesis of the compounds comprising predeter mined polynuclear structural units has not been solved to date. Therefore, the preparation of PCP by cross linking of polynuclear blocks by appropriate bridging ligands is of special interest. In the overwhelming majority of exam ples of PCP having polynuclear blocks published to date, crystal lattices are formed by self assembly in the reaction mixtures (for example, the polymers having trinuclear blocks Fe 3 O 7+ ). 4 The examples of the preparation of PCP using polynuclear complexes as the building blocks, in which the metal organic core is retained during the reac tion, are scarce. 5 As a rule, cross linking of polynuclear complexes (blocks) by bridging ligands results in nonpo rous structures. 6-8 Thus, the preparation of PCP where the basic structure of polynuclear blocks would be retained is topical. In this case, the physical properties of a polynu clear complex (for example, magnetic and spectral) will, at least partially, predetermine the properties of the result ing coordination polymer, which will allow obtaining the compounds with the desired properties.The aim of the present work was to study a possibility of using the polynuclear complexes with homonuclear (Mn 6 O 2 ) and heteronuclear (Fe 2 MO, where M = Co, Ni) cores for the preparation of PCP by cross linking with conformationally rigid ligands (4,4´ bipyridine (bpy)...

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Section: Resultssupporting

confidence: 59%

Structures and sorption properties of the coordination polymers built up of 3d metal carboxylate polynuclear complexes

et al. 2010

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“…In the crystal structure of this MOF there are S-shaped channels in which there are coordinated (to the Ni 2+ ions) and uncoordinated water molecules. It was shown by derivatography that the action of heat on NaNi 3 (L13) 2 (OH)(H 2 O) 5 to 350°C leads to the removal of all the water molecules; during dehydration the green color of the complex changes to yellow-brown [indicating changes in the coordination sphere of the nickel(II)], and the surface area increases sharply -the value of S, determined by the sorption of nitrogen, increases from zero (for the undehydrated sample) to 743 m 2 /g and then decreases to 640 m 2 /g for the samples dehydrated at 300 and 350°C respectively [91]. From the order of the signs it is possible to form an opinion about the presence of the coordination-unsaturated nickel ions in the dehydrated form of the complex -in NaNi 3 (L13) 2 (OH)(H 2 O) 5 there are four coordinated molecules of H 2 O for the three nickel ions, and it is unlikely that all the positions in the coordination spheres of the nickel ions will be occupied by donor atoms after dehydration; moreover, rehydration takes place very quickly and is accompanied by a change in the color of the complex.…”

Section: Location Of the Adsorption Centers (Binding Sites) Of H 2 Inmentioning

confidence: 99%

“…From the order of the signs it is possible to form an opinion about the presence of the coordination-unsaturated nickel ions in the dehydrated form of the complex -in NaNi 3 (L13) 2 (OH)(H 2 O) 5 there are four coordinated molecules of H 2 O for the three nickel ions, and it is unlikely that all the positions in the coordination spheres of the nickel ions will be occupied by donor atoms after dehydration; moreover, rehydration takes place very quickly and is accompanied by a change in the color of the complex. Dehydration leads to the formation of the compound NaNi 3 (L13) 2 (OH) (according to calculation from the loss in weight), the structure of which is evidently similar to the structure of NaNi 3 (L13) 2 (OH)(H 2 O) 5 , although it has not been possible to fully interpret the structure of the dehydrated phase [83]. [83] reached a conclusion about bonding of the hydrogen by the coordination-unsaturated nickel ions.…”

Section: Location Of the Adsorption Centers (Binding Sites) Of H 2 Inmentioning

confidence: 99%

“…Metal-organic framework compounds (MOF) or porous coordination polymers are regarded as one of the most promising sorbents for the storage of hydrogen [1][2][3][4][5][6][7][8][9]. The problem of achieving an acceptable sorption capacity for MOFs with respect to hydrogen (9 wt.% and 81 g/L before 2015 [10]) can only be solved on the condition of an understanding of the factors influencing the ability of such compounds to sorb H 2 .…”

Section: Introductionmentioning

confidence: 99%

“…In a first approximation it is possible to distinguish two groups of factors influencing the sorption capacity of MOFs, and they can be called arbitrarily macroscopic (characteristics nor directly dependent on the chemical structure of the MOF -surface area, volume of pores) and microscopic (characteristics of the structural elements interacting directly with the H 2 molecule). Analysis of the array of accumulated data indicates that if only macroscopic physicochemical factors are taken into account the sorption capacity of the MOF for hydrogen is determined by the surface area and the volume of the pores in the compound [1, 4,5,9,[11][12][13]. Since such an approach does not take account of the characteristics of the chemical structure of these compounds the question remains open as to how much the structure of the ligands affects the ability of MOFs to sorb hydrogen.…”

Section: Introductionmentioning

confidence: 99%

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Role of the chemical structure of metal–organic framework compounds in the adsorption of hydrogen

Kolotilov

Pavlishchuk

2009

Theor Exp Chem

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The effect of the chemical structure of metal-organic framework compounds (MOF) (the presence of coordination-unsaturated metal ions, the nature of the metal ions, the presence of electron donor and electron acceptor groups in the ligands) on the ability of such compounds to sorb hydrogen is examined. It is shown that the macroscopic parameters (the surface area and pore size) make a major contribution to the adsorption of hydrogen while the chemical structure of the MOF plays a subsidiary role by determining the structural characteristics of the adsorbent.Key words: metal-organic frameworks, porous coordination polymers, hydrogen sorption, coordination-unsaturated ions, effect of the nature of metal ions, effect of functional groups.

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A Simple Lithium(I) Salt with a Microporous Structure and Its Gas Sorption Properties

et al. 2010

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Effect of structural and thermodynamic factors on the sorption of hydrogen by metal–organic framework compounds

Cited by 27 publications

References 93 publications

Structures and sorption properties of the coordination polymers built up of 3d metal carboxylate polynuclear complexes

Structures and sorption properties of the coordination polymers built up of 3d metal carboxylate polynuclear complexes

Role of the chemical structure of metal–organic framework compounds in the adsorption of hydrogen

A Simple Lithium(I) Salt with a Microporous Structure and Its Gas Sorption Properties

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