Next Article in Journal
Catalytic Thermochemical Conversion of Algae and Upgrading of Algal Oil for the Production of High-Grade Liquid Fuel: A Review
Previous Article in Journal
In Situ Investigations on the Facile Synthesis and Catalytic Performance of CeO2-Pt/Al2O3 Catalyst
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Catalysts
Volume 10
Issue 2
10.3390/catal10020144
catalysts-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Oxygen Adsorption and Activation on Cobalt Center in Modified Keggin Anion-DFT Calculations

by
Renata Tokarz-Sobieraj
1,* and
Piotr Niemiec
2
1
Jerzy Haber Institute of Catalysis and Surface Chemistry, Polish Academy of Sciences, Niezapominajek 8, 30239 Krakow, Poland
2
Faculty of Mathematical and Natural Sciences, Department of Chemistry, University of Applied Sciences in Tarnow, Mickiewicza 8, 33100 Tarnow, Poland
*
Author to whom correspondence should be addressed.
Catalysts 2020, 10(2), 144; https://doi.org/10.3390/catal10020144
Submission received: 11 December 2019 / Revised: 10 January 2020 / Accepted: 14 January 2020 / Published: 21 January 2020
(This article belongs to the Section Biocatalysis)
Browse Figures
Review Reports Versions Notes

Abstract

:
The influence of the cobalt cation geometric environment on catalytic activity, namely, oxygen adsorption and its activation, was investigated by exploring two groups of systems. The first group was formed by cobalt cation complexes, in which the Co2+ was surrounded by water-H2O or acetonitrile-CH3CN solvent molecules. This represents heteropolyacids salts (ConH3-nPW(Mo)12O40), where the Co2+ acts as a cation that compensates for the negative charge of the Keggin anion and is typically surrounded by solvent molecules in that system. The second group consisted of tungsten or molybdenum Keggin anions (H5PW11CoO39 and H5PMo11CoO39), having the Co2+ cation incorporated into the anion framework, in the position of one addenda atom. Detailed NOCV (Natural Orbitals for Chemical Valence) analysis showed that, for all studied systems, the σ-donation and σ-backdonation active channels of the electron transfer were responsible for the creation of a single Co-OO bond. Depending on the chemical/geometrical environment of the Co2+ cation, the different quantities of electrons were flown from the Co2+ 3d orbital to the π* antibonding molecular orbitals of the oxygen ligand, as well as in the opposite direction. In molybdenum and tungsten heteropolyacids, modified by Co2+ in the position of the addenda atom, activation of O2 was supported by a π-polarization process. Calculated data show that the oxygen molecule activation changed in the following order: H5PMo11CoO39 = H5PW11CoO39 > Co(CH3CN)52+ > Co(H2O)52+.

Graphical Abstract

1. Introduction

The acid-base and redox properties of heteropoly compounds (POM–PolyOxoMetalate) are particularly attractive from a catalytic and research point of view [1,2,3]. In recent years, in addition to commonly used 12-tungsto and 12-molybdo-phosphoric acids and their salts, systems modified by transition metal cations have been used [4,5,6]. The transition metal cation may be introduced into the heteropoly compounds in a position of compensating/counter cation, central ion/heteroatom or addenda atom(s). Depending on its location in the geometric structure, new elements may discern acidic and/or oxidizing properties.
One of the elements commonly used in POM modification is cobalt, and the catalysts obtained in this way are successfully used in many different catalytic reactions [7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45]. Keggin-type catalysts, with a cobalt cation (Co2+) in the position of the central ion, were tested in catalytic reactions, primarily as an acid (H6CoW12O40) [7,8] or as salts, e.g., potassium (K5CoW12O40*3H2O) [9,10,11,12]. The acid properties of the systems were tested in reactions, such as: MTBE (Methyl tert-butyl ether) synthesis [7], decomposition of isobutyl propionate (IBP) [8], acetylation of alcohols and phenols [9], deprotonation of THP (Tetrahydropyranyl) esters [10], alcoholysis and acetolysis of epoxides, and conversion of epoxides to thiiranes [11], and formation of 1, 3-dioxolanes from epoxides [12]. Since the change in the central ion position results in the change in the oxidizing potential of the heteropoly anion [1,13,14,15], CoW12O406− systems were successfully used in the oxidation of benzol alcohol [16].
A review of the literature shows greater attention given to systems where the cobalt cation (Co2+) occupies the position of the addenda atom [17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39]. Modified systems, usually synthesized as various salts, as well as the comparison with systems modified by other transition metals, were tested in oxidation reactions in the presence of hydrogen peroxide [17,18,19,20,21,22], molecular oxygen [23,24,25,26,27,28], air [29,30,31,32,33], iodosylarenes [35,36], or t-butyl hydroperoxide [37,38]. Cobalt-modified Keggin heteropolyanin exhibits high catalytic activity and selectivity in processes such as oxidation of cyclohexane [26,27,35,37,38,40], esterification of n-butanol [25,39], epoxidation of olefins (cyclohexane, 1-hexene, norbornene, cyclooctene) [25], phenol oxidation [23], oxidation of methyl isobutyrate [24], oxidation of alpha-pinene [40], oxidation of alcohols 2-propanol [19] and hexanol [20], and lactonization of diols [22].
Cobalt heteropolyacids salts, where Co2+ occupies the position of the counter cation in the secondary structure of heteropoly compounds, were tested in the oxidation reaction. As shown by experimental data, the electronegativity of the counter-cations is very important in determining the reduction potentials of HPAs (Heteropolyacids). Pamin et al. [41] examined the aerobic oxidation of cyclooctane of free and chitosan-supported cobalt 12-tungstophosphates and 12-molybdophosphates, showing that the introduction of Co2+ cations into the PW12O403− HPA causes a significant increase in its oxidizing power, whereas the same cation introduced into the PMo12O403− system minimally increases its oxidizing abilities. Karcz et al. [42] compared heteropolyacid systems, modified by a cobalt cation in the position of the central ion and addenda atom, which showed that both cobalt locations and the chemical character of other addenda atoms factor into the catalytic activity of the aerobic liquid-phase oxidation of cyclooctane.
In recent years, the ability of heteropoly systems, modified by transition metal, to form complexes with CO2 has been studied. As shown by Chen et al. [43] and Yasada et al. [44], the highest catalytic activity was derived from systems modified by the Co2+ cation. In addition, the Szczepankiewicz [45] studied systems, where Co2+ was located in various heteropoly anions, namely the alfa-Keggin (XW11O39TM), alfa1/alfa2-Dawson (P2W17O61TM), and Weakley and Finkey (P2W18O68Co4) showed that the ability to bind the CO2 molecule strongly depended on the geometric environment of the cobalt cation.
The theoretical calculations concerning this topic are rather poor [46,47,48]. Zhang and Maestre [46,47] studied the thermal stability and redox properties of the CoW12O405− alpha/beta Keggin anion. In Reference [48], the scope of the research was extended to Co3+ systems, in which the cobalt cation replaces the central ion and one of the addenda atoms in tungsten Keggin anions. For the studied systems, several lower-lying electronic states, as well as a vibrational analysis, were calculated. In our previous calculations [42], the effect of cobalt location in Keggin-type heteropoly acts as a catalyst for the aerobic oxidation of cyclooctane.
The aforementioned examples indicate that the location of the transition metal cation in the structure of the heteropoly systems had a significant bearing on the resulting catalytic properties. Therefore, the present paper describes our findings concerning the role of geometric structure on the catalytic properties of Co2+ cation, in the process of oxygen adsorption and its activation on the metal center. Using theoretical methods, both processes were tested using two groups of cobalt modified systems. The first group was formed by cobalt cation complexes, where the Co2+ cation is surrounded by water (H2O) or acetonitrile (CH3CN) solvent molecules. This represents heteropolyacids salts (ConH3−nPW(Mo)12O40), where the Co2+ acts as a cation that compensates for the negative charge of the Keggin anion, and which is typically surrounded by solvent molecules. The second group consisted of tungsten or molybdenum Keggin anions (H5PW11CoO39 and H5PMo11CoO39), having the Co2+ cation incorporated in the position of one addenda atom. The purpose of the presented calculations is to explain the mechanism of the interaction of cobalt–oxygen complexes in the vicinity of various ligands. The calculations do not take into account the stability of complexes with various ligands and the energy of the ligand exchange process. These issues will be the subject of a separate publication (in preparation), where cobalt complexes will be compared with other transition metal complexes. From the literature and our unpublished calculations, it follows that some ligands, especially those containing nitrogen moieties, favor the exchange with the O2 molecule [49,50]. Our unpublished calculations of HPA complexes show that, e.g., water and acetonitrile are not exchanged with the O2 molecule, but are exchanged with OOH or H2O2.

2. Results and Discussion

The optimized geometries, obtained as a result of the interaction between the oxygen molecule and the studied systems, are shown in Figure 1. Table 1 presents the theoretical parameters describing the metal–oxygen (Co-O) and oxygen–oxygen (O-O) bonds, namely the bond distance, d [Å], and Mayer bond order indexes, BO [51,52]. In addition, in the first row, the binding energy, ΔEB [kJ/mol], which was calculated for the processes (1–3) presented below is summarized.
Co(H2O)52+ + O2 = OO-Co(H2O)52+
Co(CH3CN)52+ + O2 = OO-Co(CH3CN)52+
HPW(Mo)11Co + O2 = HPW(Mo)11Co-OO
Binding energy, presented in Table 1 (first row), shows that all studied systems exhibit the ability to adsorb molecular oxygen. The calculated EB values show that adsorption of the O2 molecule is more energy efficient on cobalt cation introduced in tungsten/molybdenum Keggin anions than in the cobalt cation surrounded by both (water/acetonitrile) types of solvent molecules.
In all systems, molecular oxygen adsorbs on the cobalt center in a side-on geometry, and the result of this adsorption is that the formation of a single Co-O bond is observed. Bond lengths are smaller (equal 1.92/1.94 [Å]) between oxygen and cobalt built-in tungsten/molybdenum Keggin anions than between oxygen and cobalt surrounded by water/acetonitrile solvent molecules (equal 2.09/2.06 [Å], respectively). The calculated bond order index values (equal 0.8) suggest the formation of a stronger Co-O bond in HPW(Mo)11Co-OO than in Co(H2O)52+ and Co(CH3CN)52+ systems (where BO are equal about 0.6).
The comparison of the geometric and electronic parameters allows for the characterization of the isolated O2 molecule (d = 1.22 [Å], BO = 1.72), with values obtained after adsorption to the cobalt center, which clearly indicates that adsorption leads to oxygen activation. The interaction of the O2 molecule with the Co2+ results in the elongation and weakening of the O-O bond. The O-O bond length changes from 1.22 in the isolated O2 molecule to 1.25 [Å], following adsorption of the Co2+ built-in Keggin anion and 1.24 Å, following adsorption on Co2+ coordinated with acetonitrile molecules. Adsorption at the metal center goes to weakening of the O-O bonds, observed as a lowering of the Mayer bond order indexes (from the value of 1.75 in the isolated molecule to 1.40 in the HPW11Co and HPMo11Co and ca. 1.50 in the Co(H2O)52+ and Co(CH3CN)52+ systems, respectively).
Is the mechanism of activation the same for all studied systems? To answer this question, the NOCV method, carried out at a spin resolution (SR), was used. All the studied systems had to be divided into two fragments, between which of the Co-OO bonds are formed. The first fragment contained the cobalt cation with its geometric environment (HPW11Co/HPMo11Co Keggin anions and Co(H2O)52+/Co(CH3CN)52+ complexes), and the second contained the oxygen molecule (O-O). Defining the multiplicity of all fragments and the whole system was another step taken prior to performing the NOCV-SR (Natural Orbitals for Chemical Valence in Spin Resolution) analysis. Taking into consideration the abovementioned calculations, it was stated that multiplicity for every cobalt-containing fragment is 2 (before and after adsorption of O2) and the multiplicity of the oxygen molecule is a triplet (oxygen molecule behaves as paramagnetic).
We begin the discussion with the Co(H2O)52+-OO complex. Figure 2 presents four (2a,b,d,e) NOCV contours, describing the bond between the cobalt cation and O-O ligand in the Co(H2O)52+-OO complex. Considering that NOCV can be grouped in pairs of complementary orbitals, corresponding to the same eigenvalue with the opposite sign [53], the Co-OO bond can be described by two (2a2b and 2d2e) pairs of complementary NOCVs.
As shown in Figure 2, both pairs (ϕϕ- and ϕϕ-) exhibit σ character, and each NOCV contains a contribution from both fragments (Co(H2O)52+ and OO molecule). Generally, all NOCVs are built from anti-bonding (π*) oxygen orbitals and 3d orbitals from the cobalt atom as well as the 2p orbitals of oxygen atoms from water molecules. The orbitals ϕ- and ϕ- exhibit anti-bonding characteristics, whereas the second orbital pairs are clearly a σ-bonding orbital, localized predominantly in the bond region. The contribution from the first pair of orbitals to the deformation density, Δ1αρ(r) (Figure 2c), clearly shows that this pair of orbitals participates in the process of donation from the O-O molecule to the cobalt complex. Analysis of eigenvalues shows that oxygen losses are 0.74 e, while the cobalt complex gains 0.74 e in this process. In contrast, the contributions from the second pair of complementary NOCVs to the deformation density Δ1βρ(r) (Figure 2f), corresponds to the backdonation process from the Co(H2O)52+ complex to the O2 molecule. The second pair (ϕϕ-) is characterized by |ν| = 0.76 and describes the process of 0.76 electron inflow to antibonding oxygen orbitals.
Identical analysis was carried out for the Co(CH3CN)52+-OO system (Figure 3). Similar to the previous system, the bond between the cobalt complex and oxygen molecule describes the two pairs of complementary NOCV (Figure 3a,b,d,e), both (ϕϕ- and ϕϕ-) with σ symmetry. The first pair (ϕϕ-) describes the transfer from the oxygen ligand to the cobalt complex, whereas the second pair (ϕϕ-) of NOCV participates in the backdonation process, in which electrons transfer from the cobalt complex to the anti-bonding oxygen orbitals. The obtained eigenvalues (|ν| = 0.40 characterize the donation process (Figure 3c) and |ν| = 0.51 for backdonation (Figure 3f)) show that the backdonation process is predominated in the overall deformation density Δρ(r). Detailed analysis of NOCV contours show that not only the oxygen atom and metal ion participate in the formation of Co-O bond, but also nitrogen atoms from acetonitryle solvent molecules.
Preliminary analysis of the HPW11Co-O2 and HPMo11Co-O2 systems show that the quality description of the interaction between the O2 molecule with cobalt-modified tungsten and molybdenum heteropolyacids is identical. Thus, Figure 4 presents the contours of NOCV and the contribution to the deformation density for both W(Mo)Co systems, while the differentiating electron flow data are given in Table 2.
In contrast to the presented cobalt complexes, the bond between molecular oxygen and HPW11Co/ HPMo11Co systems is described by three pairs, which are complementary to NOCVs. Two pairs (ϕϕ- and ϕϕ-) exhibit σ character, whereas the third one (ϕϕ-) is characterized by orbitals with π symmetry. As shown in Figure 4, the formation of the Co-OO bond participates not only the orbitals of adsorbed 2p oxygen and 3d cobalt orbitals but also the 2p orbitals of the oxygen atoms from the Keggin framework (the orbitals of internal (Oa) and bridging (Ob, Oc) oxygen atoms). Detailed analysis of NOCV contributions to the deformation density shows that orbitals from the first pair of NOCVs participate in donation from adsorbed O2 to the Keggin anion, where the cobalt cation is introduced. The negative contribution (outflow of electrons) is localized on the oxygen orbitals, and positive changes (increase in the number of electrons) are visible on the Keggin anion (primarily on the cobalt cation and its surroundings). The second pair of NOCV describes the backdonation process, in which electrons flow from the Keggin anion to the ligand orbitals (adsorbed molecular oxygen). The third active electron channel shows the internal polarization inside the adsorbed oxygen molecules, which can be described as a π donation from the Keggin skeleton to the oxygen molecule. Calculated eigenvalues describe the electron flow between two defined fragments (HPW11Co/HPMo11Co and the O-O molecule), the result of which is the creation of the Co-OO bond, as seen from Table 2. Calculated data are very similar for both tungsten and molybdenum systems.
The data presented in Table 2 clearly show that, in all studied systems, the formation of the Co-OO bond is the result of several processes, in which two processes dominated: (a) The donation from ligand to the metal center, and (b) the backdonation from metal to the oxygen ligand. Interaction between the oxygen molecule and cobalt center, introduced in the Keggin anion, is additionally supported by polarization inside the oxygen molecule. The obtained eigenvalues show that the sum of the electron flow in donation and backdonation processes are similar for all studied systems, except for the water complex Co(H2O)52+. Another parameter differentiating the systems is the observed polarization in HPW11Co and HPMo11Co systems.
Activation of the oxygen molecule, observed in NOCV analysis, can be confirmed by calculations of the IR spectra. The values of stretching O-O bond frequencies, before and after adsorption on the cobalt center, in different geometrical surroundings, were analyzed. The obtained values are presented in Table 3.
In all cases, the lowering of the stretching O-O bond frequencies was observed in the direction of longer wavelengths (redshift), relative to the position defined for the isolated O2 molecule (1555 cm−1). The obtained values show that the strongest O-O activation (the largest redshift) is observed for the Co2+ cation built into the Keggin heteropolyacid. The values obtained for tungsten and molybdenum system are close to each other (redshift in HPMoCo is slightly bigger than in the case of HPWoCo). The weakest activation is observed after adsorption of O2 on the Co2+ cation in water complexes. The obtained data confirmed, (obtained using the NOCV analysis theoretical parameters such as bond length and bond orders), that the activation of oxygen molecule adsorbed on Co2+, built into the Keggin heteropolyacid, is stronger than after adsorption on Co2+ complexes with solvent (water/acetonitrile) molecules. The obtained results, by differentiating the Co(CH3CN)52+ and HPW11Co/HPW11Co systems (for which almost identical electron flow values were obtained in the donation and backdonation processes) indicate the role of the polarization process, which was only observed in systems with cobalt cation embedded in the Keggin anion.

3. Methods

The oxidation ability of the Co2+ cation was investigated with the DFT (Density Functional Theory) method (package Turbomole) [54] using a cluster model. The exchange and correlation energies were calculated using the Becke–Perdew–Ernzerhof (PBE) functional [55,56,57], where all electron basis sets of def-TZVP quality were used. The relativistic effects are already noticeable for post 3d elements; therefore, it is better to use effective core potentials (ECPs) with relativistic corrections, instead of all electron basis sets [58]. The resolution of identity (RI) approach was applied for computing the electronic Coulomb interactions [59,60]. For all studied species, the calculations were performed for all possible spin states, and the one with the lowest energy was chosen for further investigation.
All structures were optimized as a spin unrestricted open-shell system. Geometry optimization was performed in accordance with the quasi-Newton-Raphsod method [61]. Geometry was considered converged for the following conditions: (a) The energy change between two optimization cycles drops below 10−6 a.u., (b) the maximum displacement element drops below 10−3 a.u., and the maximum gradient element drops below 10−3 a.u.
To characterize the process of bond formation between the metallic center (Co2+) and oxygen molecule, Natural Orbital Chemical Valences in Spin Resolution (NOCV-SR) was performed [53,62,63,64]. Natural orbitals for the chemical valence were defined as the eigenvectors of the chemical valence operator of the Nalewajski–Mrozek theory:
i = νφi I = 1….N
with the valence operator given by a matrix
V = 1/2ΔP
where ΔP corresponds to a difference between the charge-and-bond-order matrices of a molecule and promolecule (set of isolated atoms, or molecular fragments, ligands, etc.).
It has been found that NOCV leads to a very compact description of the fragment-ligand bond, with only a few orbitals exhibiting non-zero eigenvalues. The results of the NOCV analysis allow for the separation of the σ, π donation, and backdonation contributions to the ligand-fragment bond. They can also be useful in the comparison of these contributions in different complexes.
For theoretical modeling, three geometric structures (see Figure 5a–c) were taken into consideration. The first two geometries (see Figure 5a,b) represent a simplified structure, in which the cation is surrounded by five solvent (H2O or CH3CN) molecules, creating the Co(H2O)52+ and Co(CH3CN)52+ complexes, with a total charge equal to +2 (as a result of the Co2+ charge and neutral water/acetonitrile molecules). Both models were used to show the influence of the solvent environment on the oxidation ability of Co2+ in the system, where the cobalt cation plays the role of a counter cation. The third geometry (Figure 5c) presents the Keggin anion, where one of the tungsten or molybdenum atoms (W/Mo), from the anion framework, was replaced by the Co2+ cation. This model represents the H5PW11CoO39 (referred as a HPW11Co) and H5PMo11CoO39 (referred as a HPMo11Co) systems, modified in the addenda atom position. The total charge of that modified heteropolyacid is zero, since the global heteropolyanion charge (−5) was compensated by 5 hydrogen atoms. This model may show how the properties of Co2+ depend on the chemical composition (tungsten/molybdenum) of the Keggin anion. The comparison of the models, with each other, allows for the determination of the effect of geometry on cobalt’s ability to adsorb and activate oxygen molecule.

4. Conclusions

This article examines the chemical environmental role in the oxidizing capacity of Co2+ located in different geometrical environments. For this purpose, H5PMo11CoO39, H5PW11CoO39, Co(H2O)52+, and Co(CH3CN)52+ systems were examined.
It has been shown that both the adsorption and activation process of the molecular oxygen molecule depend on the environment in which the cobalt is found. Adsorption energy for bonding O2 onto the Co2+ center is much higher in the case of the modified heteropolyacids systems (H5PMo11CoO39, H5PW11CoO39) than in complexes with solvent molecules (Co(H2O)52+ and Co(CH3CN)52+). Both electronic (bond order) and geometrical (bond length) parameters imply that the activation process of the oxygen molecule is stronger in the molybdenum and tungsten modified heteropolyacids (H5PMo11CoO39, H5PW11CoO39) than in both solvated systems (Co(H2O)52+ and Co(CH3CN)52+).
Detailed NOCV-SR analysis shows that, for all studied systems, the σ-donation and σ-backdonation active channels of electron transfer are responsible for the creation of a single Co-OO bond and the activation of the oxygen molecule. Depending on the chemical/geometrical environment of the Co2+ cation, different quantities of electrons are flown from the 3d cobalt orbitals to the π* antibonding molecular orbitals, as well as in the opposite direction. In the modified molybdenum and tungsten heteropolyacids, activation of the O2 molecule is supported by a π-polarization process.
The calculated redshift values confirmed that the ability of Co2+ ion for adsorption and activation of the oxygen molecule changes in the following order: H5PMo11CoO39 = H5PW11CoO39 > Co(CH3CN)52+ > Co(H2O)52+. The obtained theoretical results show that the cobalt cation acts as an addenda atom (introduced in the primary structure of HPA), which is more likely to activate the molecular oxygen molecule than a compensating cation (in the secondary structure of HPA, in the solvent environment). The process of oxygen activation is easier when oxygen is adsorbed on the cobalt center introduced into the Keggin anion, where the large environment of the metal center may create a reservoir of electron outflow/inflow.

Author Contributions

Conceptualization, R.T.-S.; Data curation, P.N.; Formal analysis, R.T.-S. and P.N.; Investigation, R.T.-S.; Methodology, R.T.-S. and P.N.; Supervision, R.T.-S.; Visualization, P.N.; Writing—original draft, R.T.-S. and P.N.; Writing—review & editing, R.T.-S. All authors have read and agreed to the published version of the manuscript.

Funding

This research was done within the statutory funds of the Jerzy Haber Institute of Catalysis and Surface Chemistry, Polish Academy of Sciences.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Pope, M.T. Heteropoly and Isopoly Oxometalates; Springer: New York, NY, USA, 1983. [Google Scholar]
  2. Kozhevnikov, I.V. Catalysis by polyoxometalates. In Catalysts for Fine Chemical Synthesis; John Wiley and Sons Ltd.: Hoboken, NJ, USA; The Atrium: Chichester, UK, 2002; Volume 2. [Google Scholar]
  3. Misono, M. Heterogeneous Catalysis by Heteropoly Compounds of Molybdenum and Tungsten. Catal. Rev. Sci. Eng. 1987, 29, 269–321. [Google Scholar] [CrossRef]
  4. Timofeeva, M.N. Acid Catalysis by Heteropoly Acids. Appl. Catal. A Gen. 2003, 256, 19–35. [Google Scholar] [CrossRef]
  5. Sun, M.; Zhang, J.; Putaj, P.; Caps, V.; Lefebvre, F.; Pelletier, J.; Basset, J.M. Catalytic Oxidation of Light Alkanes (C1–C4) by Heteropoly Compounds. Chem. Rev. 2014, 114, 981–1019. [Google Scholar] [CrossRef] [PubMed]
  6. Oms, O.; Delbecq, A.; Mialane, P. Diversity in structures and properties of 3d-incorporating polyoxotungstates. Chem. Soc. Rev. 2012, 41, 7497–7536. [Google Scholar] [CrossRef] [PubMed]
  7. Shikata, S.; Okuhara, T.; Misono, M. Catalysis by hetropoly compounds. Part XXVI. Gas phase synthesis of methyl tert-butyl ether over heteropolyacids. J. Mol. Catal. A Chem. 1995, 100, 49–59. [Google Scholar] [CrossRef]
  8. Hu, C.; Hashimoto, M.; Okuhara, T.; Misono, M. Catalysis by Heteropoly Compounds. XXII. Reactions of Esters and Esterification Catalyzed by Heteropolyacids in a Homogeneous Liquid-Phase Effects of the Central Atom of Heteropolyanions Having Tungsten as the Addenda Atom. J. Catal. 1993, 143, 437–448. [Google Scholar] [CrossRef]
  9. Habibi, M.H.; Tangestaninejad, S.; Mirkhani, V.; Yadollahi, B. Catalytic Acetylation of Alcohols and Phenols with Potassium Dodecatungstocobaltate Trihydrate. Monatshefte Chemie 2002, 133, 323–327. [Google Scholar] [CrossRef]
  10. Habibi, M.H.; Tangestaninejad, S.; Mohammadpoor-Baltork, I.; Mirkhani, V.; Yadollahi, B. Potassium Dodecatangestocobaltate Trihydrate (K5CoW12O40·3H2O): A Mild and Efficient Catalyst for the Tetrahydropyranylation of Alcohols and their Detetrahydropyranylation. Tetrahedron Lett. 2001, 42, 2851–2853. [Google Scholar] [CrossRef]
  11. Tangestaninejad, S.T.; Moghadam, M.; Mirkhani, V.; Yadollahi, B.; Mohammad, S.; Mirmohammadi, R. Mild and Efficient Ring Opening of Epoxides Catalyzed by Potassium Dodecatungstocobaltate(III). Monatshefte Chemie 2006, 137, 235–242. [Google Scholar] [CrossRef]
  12. Habibi, M.H.; Tangestaninejad, S.T.; Mirkhani, V.; Yadollahi, B. K5CoW12O40·3H2O: A Novel Cobalt Polyoxometalate Catalyst for Conversion of Epoxides to Acetonides. Catal. Lett. 2001, 75, 205–207. [Google Scholar] [CrossRef]
  13. Nakajima, K.; Eda, K.; Himeno, S. Effect of the Central Oxoanion Size on the Voltammetric Properties of Keggin-Type [XW12O40]n− (n = 2–6) Complexes. Inorg. Chem. 2010, 49, 5212–5215. [Google Scholar] [CrossRef] [PubMed]
  14. Gao, G.G.; Xu, L.; Wang, W.J.; Qu, X.S.; Liu, H.; Yang, Y.Y. Cobalt (II)/nickel (II)-centered Keggin-type heteropolymolybdates: Syntheses, crystal structures, magnetic and electrochemical properties. Inorg. Chem. 2008, 47, 2325–2333. [Google Scholar] [CrossRef] [PubMed]
  15. Song, I.K.; Bertau, M.A. Redox properties of keggin-type heteropolyacid (HPA) catalysts: Efect of counter-cation, heteroatom, and polyatom substitution. J. Mol. Catal. A Chem. 2004, 212, 229–236. [Google Scholar] [CrossRef]
  16. Maradur, S.P.; Gokavi, G.S.; Selvam, P. Poly (Vinyl Alcohol) Supported 12-Tungstocobaltate (II) as a Novel Heterogeneous Catalyst for Oxidation of Benzyl Alcohols. Bull. Catal. Soc. India 2007, 6, 42–49. [Google Scholar]
  17. Simoes, M.M.Q.; Conceicao, C.M.M.; Gamelas, J.A.F.; Domingues, P.M.D.N.; Cavaleiro, A.M.V.; Cavaleiro, J.A.S.; Ferrer-Correia, A.J.V.; Johnstone, R.A.W. Keggin-type polyoxotungstates as catalysts in the oxidation of cyclohexane by dilute aqueous hydrogen peroxide. J. Mol. Catal. A Chem. 1999, 144, 461–468. [Google Scholar] [CrossRef]
  18. Trakarnpruk, W. Heterogeneous Catalytic Oxidation of Cyclohexane with H2O2 Catalyzed by Cs- and TBA-salts of Cu- and Mn-Polyoxotungstates on MCM-41. Int. J. Chem. Eng. Appl. 2015, 6, 120–124. [Google Scholar] [CrossRef] [Green Version]
  19. Choi, J.H.; Kim, J.K.; Park, D.R.; Kang, T.H.; Song, J.H.; Song, I.K. Redox properties and oxidation catalysis of transition metal-substituted α-K5PW11O39(M·OH2) (M = MnII, CoII, NiII, and ZnII) Keggin heteropolyacid catalysts for liquid-phase oxidation of 2-propanol. J. Mol. Catal. A Chem. 2013, 371, 111–117. [Google Scholar] [CrossRef]
  20. Guangdong, Z.; Zhalin, X.; Xiaohong, G.; Hong, Z.; Yanan, L.; Xueju, L.; Tiexin, C.; Wenxing, L.; Kaiji, Z. Transition metal substituted tungstophosphoric compound catalyzed oxidation of hexanol to hexanal with hydrogen peroxide. React. Kinet. Catal. Lett. 2005, 8, 57–64. [Google Scholar] [CrossRef]
  21. Chen, J.; Liu, J.; Zhang, Y.; Gao, S. Transition metal substituted polyoxometalates and their application in the direct hydroxylation of benzene to phenol with hydrogen peroxide. Res. Chem. Intermed. 2010, 36, 959–968. [Google Scholar] [CrossRef]
  22. Bamoharram, F.F.; Heravi, M.M.; Roshani, M.; Heravi, H.M.; Gharib, A.; Jahangir, M. Lactonization of various diols, using transition metal-substituted keggin catalysts [PW11MO40]7−, (M = Co(II), Ni(II), Cu(II), Zn(II). Iran. J. Org. Chem. 2009, 1, 110–117. [Google Scholar]
  23. Karcz, R.; Pamin, K.; Połtowicz, J.; Haber, J. Selective Oxidation of Phenol in the Presence of Transition-Metal Substituted Polyoxometalates. Catal. Lett. 2009, 132, 159–167. [Google Scholar] [CrossRef]
  24. Ellis, S.; Kozhevnikov, I.V. Homogeneous oxidation of methyl isobutyrate with oxygen catalysed by metal complexes: Polyoxometalates versus metalloporphyrins and metallophthalocyanines. J. Mol. Catal. A Chem. 2002, 187, 227–235. [Google Scholar] [CrossRef]
  25. Neumann, R.; Dahan, M. Transition metal substituted Keggin type polyoxomolybdates as bifunctional catalysts for the epoxidation of alkenes by molecular oxygen. J. Chem. Soc. Chem. Commun. 1995, 2, 171–172. [Google Scholar] [CrossRef]
  26. Neumann, R.; Levin, M. Molecular Oxygen as Oxidant in Heteropolyanion Catalysed Oxidations. Stud. Surf. Sci. Catal. 1991, 66, 121–127. [Google Scholar] [CrossRef]
  27. Qin, D.; Wang, G.; Wu, Y. Selective oxidation of cyclohexene with molecular oxygen catalyzed by transition metal substituted polyoxometalates. Stud. Surf. Sci. Catal. 1994, 82, 603–608. [Google Scholar] [CrossRef]
  28. Liu, Y.; Murata, K.; Inaba, M. Liquid-phase oxidation of benzene to phenol by molecular oxygen over transition metal substituted polyoxometalate compounds. Catal. Commun. 2005, 6, 679–683. [Google Scholar] [CrossRef]
  29. Kholdeeva, O.A.; Vanina, M.P.; Timofeeva, M.N.; Maksimovskaya, R.I.; Trubitsina, T.A.; Melgunov, M.S.; Burgina, E.B.; Mrowiec-Bialon, J.; Jarzebski, A.B.; Hill, C.L. Co-containing polyoxometalate-based heterogeneous catalysts for the selective aerobic oxidation of aldehydes under ambient conditions. J. Catal. 2004, 226, 363–371. [Google Scholar] [CrossRef]
  30. Maksimchuk, N.V.; Melgunov, M.S.; Chesalov, Y.A.; Mrowiec-Białoń, J.; Jarzębski, A.B.; Kholdeeva, O.A. Aerobic oxidations of α-pinene over cobalt-substituted polyoxometalate supported on amino-modified mesoporous silicates. J. Catal. 2007, 246, 241–248. [Google Scholar] [CrossRef]
  31. Mizuno, N.; Hirose, T.; Iwamoto, M. Highly selective epoxidation of olefins on mono-transition-metal-substituted Keggin-type heteropolytungstates by molecular oxygen in the presence of aldehyde. Stud. Surf. Sci. Catal. 1994, 82, 593–601. [Google Scholar] [CrossRef]
  32. Mizuno, N.; Werner, H.; Finke, R.G. Co-oxidative epoxidation of cyclohexene with molecular oxygen, isobutyraldehyde reductant, and the polyoxoanion-supported catalyst precursor [(n-C4H9)4N]5Na3[(1,5-COD)Ir·P2W15Nb3O62]. The importance of key control experiments including omitting the catalyst and adding radical-chain initiators. J. Mol. Catal. 1996, 114, 15–28. [Google Scholar] [CrossRef]
  33. Mizuno, N.; Misono, M. Heteropolyacid catalysts. Curr. Opin. Solid State Mater. Sci. 1997, 2, 84–89. [Google Scholar] [CrossRef]
  34. Kholdeeva, O.A.; Grigoriev, V.A.; Maksimov, G.M.; Fedotov, M.A.; Golovin, A.V.; Zamaraev, K.I. Polyfunctional action of transition metal substituted heteropolytungstates in alkene epoxidation by molecular oxygen in the presence of aldehyde. J. Mol. Catal. A Chem. 1996, 114, 123–130. [Google Scholar] [CrossRef]
  35. Mansuy, D.; Bartoli, J.F.; Battioni, P.; Lyon, D.K.; Finke, R.G. Highly oxidation resistant inorganic-porphyrin analog polyoxometalate oxidation catalysts. 2. Catalysis of olefin epoxidation and aliphatic and aromatic hydroxylations starting from alpha.2-P2W17O61(Mn+.cntdot.Br)(n-11) (Mn+ = Mn3+,Fe3+,Co2+,Ni2+,Cu2+), including quantitative comparisons to metalloporphyrin catalysts. J. Am. Chem. Soc. 1991, 113, 7222–7226. [Google Scholar] [CrossRef]
  36. Hill, C.L.; Brown, R.B., Jr. Sustained epoxidation of olefins by oxygen donors catalyzed by transition metal-substituted polyoxometalates, oxidatively resistant inorganic analogs of metalloporphyrins. J. Am. Chem. Soc. 1986, 108, 536–538. [Google Scholar] [CrossRef]
  37. Faraj, M.; Hill, L.C. Sustained catalytic homogenous oxo-transfer oxidation of alkanes. Interaction of alkyl hydroperoxides with transition metal-substituted polyoxometalates. J. Chem. Soc. Chem. Commun. 1987, 19, 1487–1489. [Google Scholar] [CrossRef]
  38. Matsumoto, Y.; Asami, M.; Hashimoto, M.; Misono, M. Alkane oxidation with mixed addenda heteropoly catalysts containing Ru(III) and Rh(III). J. Mol. Catal. A Chem. 1996, 114, 161–168. [Google Scholar] [CrossRef]
  39. Li, B.; Ma, W.; Han, C.; Liu, J.; Pang, X.; Gao, X. Preparation of MCM-41 incorporated with transition metal substituted polyoxometalate and its catalytic performance in esterification. Microporous Mesoporous Mater. 2012, 156, 73–79. [Google Scholar] [CrossRef]
  40. Maksimchuk, N.V.; Timofeeva, M.N.; Melgunov, M.S.; Shmakov, A.N.; Chesalov, Y.A.; Dybtsev, D.N.; Fedin, V.P.; Kholdeeva, O.A. Heterogeneous Selective Oxidation Catalysts Based on Coordination Polymer MIL-101 and Transition Metal-Substituted Polyoxometalates. J. Catal. 2008, 257, 315–323. [Google Scholar] [CrossRef]
  41. Pamin, K.; Jachimska, B.; Onik, K.; Połtowicz, J.; Grabowski, R. Electrostatic Self-assembly of Polyoxometalates on Chitosan as Catalysts of Oxidation of Cyclic Hydrocarbons. Catal. Lett. 2009, 127, 167–174. [Google Scholar] [CrossRef]
  42. Karcz, R.; Niemiec, P.; Pamin, K.; Połtowicz, J.; Kryściak-Czerwenka, J.; Napruszewska, B.D.; Michalik-Zym, A.; Witko, M.; Tokarz-Sobieraj, R.; Serwicka, E.M. Effect of Cobalt Location in Keggin-Type Heteropoly Catalysts on Aerobic Oxidation of Cyclooctane: Experimental and Theoretical Study. Appl. Catal. A Gen. 2017, 542, 317–326. [Google Scholar] [CrossRef]
  43. Chen, F.; Li, X.; Wang, B.; Xu, T.; Chen, S.L.; Liu, P.; Hu, C. Mechanism of the Cycloaddition of Carbon Dioxide and Epoxides Catalyzed by Cobalt-Substituted 12-Tungstenphosphate. Chem. Eur. J. 2012, 18, 9870–9876. [Google Scholar] [CrossRef] [PubMed]
  44. Yasada, H.; He, L.-N.; Sakakura, T.; Hu, C. Efficient synthesis of cyclic carbonate from carbon dioxide catalyzed by polyoxometalate: The remarkable effects of metal substitution. J. Catal. 2005, 233, 119–122. [Google Scholar] [CrossRef]
  45. Szczepankiewicz, S.H.; Ippolito, C.M.; Santora, B.P.; Van de Ven, T.J.; Ippolito, G.A.; Fronckowiak, L.; Wiatrowski, F.; Power, T.; Kozik, M. Interaction of Carbon Dioxide with Transition-Metal-Substituted Heteropolyanions in Nonpolar Solvents. Spectroscopic Evidence for Complex Formation. Inorg. Chem. 1998, 37, 4344–4352. [Google Scholar] [CrossRef] [PubMed]
  46. Zhang, F.Q.; Zhang, X.M.; Wu, H.S.; Jiao, H. Structural and Electronic Properties of Hetero-Transition-Metal Keggin Anions:  A DFT Study of α/β-[XW12O40]n− (X = CrVI, VV, TiIV, FeIII, CoIII, NiIII, CoII, and ZnII) Relative Stability. J. Phys. Chem. A 2007, 111, 159–166. [Google Scholar] [CrossRef] [PubMed]
  47. Maestre, J.M.; Lopez, X.; Bo, C.; Poblet, J.M.; Casan-Pastor, N. Electronic and Magnetic Properties of α-Keggin Anions:  A DFT Study of [XM12O40]n−, (M = W, Mo; X = AlIII, SiIV, PV, FeIII, CoII, CoIII) and [SiM11VO40]m− (M = Mo and W). J. Am. Chem. Soc. 2001, 123, 3749–3758. [Google Scholar] [CrossRef] [PubMed]
  48. Glass, E.N.; Fielden, J.; Kaledin, A.L.; Musaev, D.G.; Lian, T.; Hill, C.L. Extending Metal-to-Polyoxometalate Charge Transfer Lifetimes: The Effect of Heterometal Location. Chem. A Eur. J. 2014, 20, 4297–4307. [Google Scholar] [CrossRef] [Green Version]
  49. Fathizadeh, M.; Khivantsev, K.; Pyrzynski, T.J.; Klinghoffer, N.B.; Shakouri, A.N.; Yu, M.; Li, S. Bio-mimetic oxygen separation via a hollow fiber membrane contactor with O2 carrier solutions. Chem. Commun. 2018, 54, 9454–9457. [Google Scholar] [CrossRef]
  50. Pamin, K.; Tabor, E.; Górecka, S.; Kubiak, W.; Rutkowska-Zbik, D.; Połtowicz, J. Three Generations of Cobalt Porphyrins as Catalysts in the Oxidation of Cycloalkanes. ChemSusChem 2019, 12, 684–691. [Google Scholar] [CrossRef]
  51. Mayer, I. Charge, bond order and valence in the AB initio SCF theory. Chem. Phys. Lett. 1983, 97, 270–274. [Google Scholar] [CrossRef]
  52. Mayer, I. Bond order and valence: Relations to Mulliken’s population analysis. Int. J. Quantum Chem. 1984, 26, 151–154. [Google Scholar] [CrossRef]
  53. Nalewajski, R.F.; Mrozek, J.; Michalak, A. Two-electron valence indices from the Kohn-Sham orbitals. Int. J. Quantum Chem. 1997, 61, 589–601. [Google Scholar] [CrossRef]
  54. TURBOMOLE V6.4 2012, a Development of University of Karlsruhe and Forschungszentrum Karlsruhe GmbH, 1989–2007, TURBOMOLE GmbH, Since 2007. Available online: http://www.turbomole.com (accessed on 17 February 2011).
  55. Perdew, J.P.; Burke, K.; Ernzerhof, M. Generalized Gradient Approximation Made Simple. Phys. Rev. Lett. 1996, 77, 3865–3868. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. Slater, J.C. Quantum Theory of Molecular and Solids; McGraw-Hill: New York, NY, USA, 1974; Volume 4. [Google Scholar]
  57. Perdew, J.P.; Wang, Y. Accurate and simple analytic representation of the electron-gas correlation energy. Phys. Rev. B 1992, 45, 13244–13249. [Google Scholar] [CrossRef] [PubMed]
  58. Christiansen, P.A.; Ermler, W.C.; Pitze, K.S. Relativistic Effects in Chemical Systems. Ann. Rev. Phys. Chem. 1985, 36, 407–432. [Google Scholar] [CrossRef]
  59. Eichkorn, K.; Treutler, O.; Ohm, H.; Haser, M.; Ahlrichs, R. Auxiliary basis sets to approximate Coulomb potentials. Chem. Phys. Lett. 1995, 240, 283–289. [Google Scholar] [CrossRef]
  60. Eichkorn, K.; Weigend, F.; Treutler, O.; Ahlrichs, R. Auxiliary basis sets for main row atoms and transition metals and their use to approximate Coulomb potentials. Theor. Chem. Acc. 1997, 97, 119–124. [Google Scholar] [CrossRef]
  61. Fletcher, R. Practical Methods of Optimization: Uncostrained Optimization; Band 1; Wiley: New York, NY, USA, 1980. [Google Scholar]
  62. Mitoraj, M.; Michalak, A. Natural orbitals for chemical valence as descriptors of chemical bonding in transition metal complexes. J. Mol. Model. 2007, 13, 347–355. [Google Scholar] [CrossRef]
  63. Michalak, A.; Mitoraj, M.; Ziegler, T. Bond Orbitals from Chemical Valence Theory. J. Phys. Chem. A 2008, 112, 1933–1939. [Google Scholar] [CrossRef]
  64. Mitoraj, M.; Michalak, A.; Ziegler, T. A Combined Charge and Energy Decomposition Scheme for Bond Analysis. J. Chem. Theory Comput. 2009, 5, 962–975. [Google Scholar] [CrossRef]
Catalysts 10 00144 g001 550
Figure 1. The geometric structure of complexes were obtained as a result of the molecular oxygen interaction with the studied systems: OO-Co(H2O)52+ (a), OO-Co(CH3CN)62+ (b), and HPW(Mo)11Co-OO (c).
Figure 1. The geometric structure of complexes were obtained as a result of the molecular oxygen interaction with the studied systems: OO-Co(H2O)52+ (a), OO-Co(CH3CN)62+ (b), and HPW(Mo)11Co-OO (c).
Catalysts 10 00144 g001
Catalysts 10 00144 g002 550
Figure 2. NOCV (pair for α electrons (a,b) and for β electrons (d,e)) and the contribution to the deformation density Δρ(r) (c,f) originated from the pairs complementary to NOCV, characterizing the bond between the Co(H2O)52+ fragment and OO ligand. The |Δρ| = 0.05 a.u. contours are shown. White orbitals describe the outflow, and purple, the inflow of electrons.
Figure 2. NOCV (pair for α electrons (a,b) and for β electrons (d,e)) and the contribution to the deformation density Δρ(r) (c,f) originated from the pairs complementary to NOCV, characterizing the bond between the Co(H2O)52+ fragment and OO ligand. The |Δρ| = 0.05 a.u. contours are shown. White orbitals describe the outflow, and purple, the inflow of electrons.
Catalysts 10 00144 g002
Catalysts 10 00144 g003 550
Figure 3. NOCV (pair for α electrons (a,b) and for β electrons (d,e)) and contribution to the deformation density Δρ(r) (c,f) originated from the pairs of complementary of NOCVs, characterizing the bond between the Co(CH3CN)52+ fragment and OO ligand. The |Δρ| = 0.05 a.u. contours are shown. White orbitals describe the outflow, and purple describes the inflow of electrons.
Figure 3. NOCV (pair for α electrons (a,b) and for β electrons (d,e)) and contribution to the deformation density Δρ(r) (c,f) originated from the pairs of complementary of NOCVs, characterizing the bond between the Co(CH3CN)52+ fragment and OO ligand. The |Δρ| = 0.05 a.u. contours are shown. White orbitals describe the outflow, and purple describes the inflow of electrons.
Catalysts 10 00144 g003
Catalysts 10 00144 g004 550
Figure 4. NOCV(pair for α electrons (a,b) and for β electrons (d,e,g,h)) and the contribution to the deformation density Δρ(r) (c,f,i) originated from the pairs of complementary of NOCV, characterizing the bond between the HPW(Mo)11Co fragment and OO ligand. The |Δρ| = 0.05 a.u. contours are shown. White orbitals describe the outflow, and purple describes the inflow of electrons.
Figure 4. NOCV(pair for α electrons (a,b) and for β electrons (d,e,g,h)) and the contribution to the deformation density Δρ(r) (c,f,i) originated from the pairs of complementary of NOCV, characterizing the bond between the HPW(Mo)11Co fragment and OO ligand. The |Δρ| = 0.05 a.u. contours are shown. White orbitals describe the outflow, and purple describes the inflow of electrons.
Catalysts 10 00144 g004
Catalysts 10 00144 g005 550
Figure 5. Structure of studied systems: Co-water complex (a), co-acetonitrile complex (b), and tungsten/molybdenum Keggin anion with cobalt introduced as one addenda atom (c).
Figure 5. Structure of studied systems: Co-water complex (a), co-acetonitrile complex (b), and tungsten/molybdenum Keggin anion with cobalt introduced as one addenda atom (c).
Catalysts 10 00144 g005
Table
Table 1. The energetic (binding energy ΔEB [kJ/mol] for the reactions (1–3)), geometric (bond length d(Co-O/O-O) [Å]) and electronic (Mayer bond order indexes BO) parameters characterize the bond between the metallic center (Co2+) and the oxygen molecule.
Table 1. The energetic (binding energy ΔEB [kJ/mol] for the reactions (1–3)), geometric (bond length d(Co-O/O-O) [Å]) and electronic (Mayer bond order indexes BO) parameters characterize the bond between the metallic center (Co2+) and the oxygen molecule.
SystemCo(H2O)52+Co(CH3CN)52+HPW11CoHPMo11Co
ΔEB−30.15−32.61−53.62−51.07
d(Co-O)2.092.061.921.94
BO(Co-O)0.640.630.800.78
d(O-O)1.221.241.251.25
BO(O-O)1.481.501.401.41
Table
Table 2. NOCV-eigenvalues describe the σ-donation, σ-backdonation, and π-polarization processes observed as a result of the interaction between the studied systems and the O2 molecule.
Table 2. NOCV-eigenvalues describe the σ-donation, σ-backdonation, and π-polarization processes observed as a result of the interaction between the studied systems and the O2 molecule.
SystemCo(H2O)52+Co(CH3CN)52+HPW11CoHPMo11Co
σ donation 0.740.400.490.46
σ backdonation 0.760.510.560.57
σ backdonation–σ donation 0.020.110.070.11
π polarization of O-O--0.240.21
Table
Table 3. The difference (redshift) between the vibration wave number [cm−1] of O-O bond in the O2 molecule, before and after adsorption of O2 on the cobalt center in the studied systems.
Table 3. The difference (redshift) between the vibration wave number [cm−1] of O-O bond in the O2 molecule, before and after adsorption of O2 on the cobalt center in the studied systems.
SystemCo(H2O)52+Co(CH3CN)52+HPW11CoHPMo11Co
Redshift96.40179.37203.77205.59

Share and Cite

MDPI and ACS Style

Tokarz-Sobieraj, R.; Niemiec, P. Oxygen Adsorption and Activation on Cobalt Center in Modified Keggin Anion-DFT Calculations. Catalysts 2020, 10, 144. https://doi.org/10.3390/catal10020144

AMA Style

Tokarz-Sobieraj R, Niemiec P. Oxygen Adsorption and Activation on Cobalt Center in Modified Keggin Anion-DFT Calculations. Catalysts. 2020; 10(2):144. https://doi.org/10.3390/catal10020144

Chicago/Turabian Style

Tokarz-Sobieraj, Renata, and Piotr Niemiec. 2020. "Oxygen Adsorption and Activation on Cobalt Center in Modified Keggin Anion-DFT Calculations" Catalysts 10, no. 2: 144. https://doi.org/10.3390/catal10020144

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop