Patent Application
20180229227
The present application claims the benefit and priority to Korean Patent Application No. 10-2017-0020289, filed in the Korean Patent Office on Feb. 15, 2017. The entire disclosure of the application is incorporated herein by reference.
The present invention relates to a catalytic system including an iridium (Ir) photosensitizer and a TiO2/Re(I) complex (hereinafter referred to as “ReC”) catalyst, and more specifically to a catalytic system for the reduction of carbon dioxide to carbon monoxide including an iridium (Ir) photosensitizer and a TiO2/Re(I) complex catalyst.
Carbon dioxide reduction is a way to utilize carbon dioxide, a major contributor of global warming, as a carbon resource and provides a fundamental solution to the problem of greenhouse gas emissions. Carbon dioxide reduction is a process for converting carbon dioxide, a root cause of environmental problems, to valuable energy materials. Efficient catalytic systems for visible-light-induced CO2 reductions have been developed in association with the greenhouse effect due to the rapid increase of CO2 concentration in the atmosphere by combustion of fossil fuels.
Building up such photocatalytic systems for CO2 reductions requires optimum combination of a visible-light-absorbing antenna and a CO2-reduction catalyst that can achieve an efficient visible-light-driven flow of electrons from an electron donor to the catalyst followed by multi-electron reductions of CO2. Among various catalysts used in visible-light reductions of CO2, transition-metal complexes have been receiving much attention associated with their potentialities in achieving high catalytic efficiencies and high chemical selectivity.
In particular, Re(I) complexes with a general formula of Re(L)(CO)3Yn+ (L=2,2′-bipyridine or a related ligand, Y=auxiliary ligand, and n=0 or 1) are attractive because of the remarkable capability in performing the efficient and selective reduction of CO2 to CO, being applied to versatile systems involving homogeneous-solution photosensitization and heterogeneous dye sensitization of the CO2 reduction under visible-light irradiation.
Recently, the present inventors reported visible-light driven CO2 reduction with highly improved durability (high turnover number) using a hybrid system, which is constructed by the covalent anchoring of both a visible-light absorbing organic dye (PS) and a Re(I) complex catalyst (ReC) on TiO2 particles (ternary system in
After having investigated some possible candidates for PS, the present inventors found that cationic iridium(III) complexes [Ir(btp)2(bpy-X2)]+ (X=OMe, tBu, Me, H) effectively work as photosensitizer for the CO2 reduction using the TiO2/ReC binary hybrid catalyst. The IrIII complexes have the absorption maximum at ˜430 nm, very close to that of the organic dye used in the ternary catalyst, allowing reasonable comparisons of the photocatalytic behavior between a system of the present invention and Dye/TiO2/ReC. Herein, the photocatalytic CO2-reduction behavior of a system of the present invention comprising an IIII-complex-based antenna and a TiO2/ReC binary catalyst is discussed, and the photosensitization capabilities of the IIII complexes are compared with that of Ru(bpy)32+, a widely used photosensitizer, as well as with the photocatalytic behavior of the Dye/TiO2/ReC ternary system. The present invention has been accomplished based on the finding that the presence of the photosensitizer in homogeneous solution and the use of the heterogenous mixed catalyst enable the reduction of carbon dioxide to carbon monoxide with high efficiency.
It is an object of the present invention to provide a catalytic system for the production of carbon monoxide from carbon dioxide including an iridium (Ir) photosensitizer and a TiO2/Re(I) complex catalyst.
An aspect of the present invention provides a catalytic system including an iridium (Ir) photosensitizer and a TiO2/Re(I) complex catalyst.
According to the present invention, no additional process is required to anchor the molecule-based dye compound on TiO2 in the synthesis of the catalytic system. This enables the synthesis of the catalytic system in a relatively easy manner for groups of photosensitizer candidates. In addition, the catalytic system of the present invention can be utilized as a platform for more easily evaluating the abilities of photosensitizers. Furthermore, the catalytic system of the present invention can find application in various fields due to its ability to selectively produce carbon monoxide gas with high efficiency.
These and/or other aspects and advantages of the invention will become apparent and more readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:
Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by the ordinary skilled in the art expert. In general, the nomenclature used herein is well-known and commonly used in the art.
In an aspect, the present invention is directed to a catalytic system including an iridium (Ir) photosensitizer and a TiO2/Re(I) complex catalyst.
In the present invention, the valence of the iridium is trivalent.
In the present invention, the iridium photosensitizer may be selected from the group consisting of Ir-OMe+, Ir-tBu+, Ir-Me+, and Ir—H+.
The catalytic system of the present invention further includes a sacrificial reagent. The sacrificial reagent may be BIH but is not limited thereto.
The catalytic system of the present invention is a binary system.
The catalytic system of the present invention reduces carbon dioxide (CO2) to produce carbon monoxide (CO).
Groups of photosensitizers, photocatalysts, and sacrificial reagents (
The present invention will be explained in more detail with reference to the following examples. It will be evident to those skilled in the art that these examples are merely for illustrative purposes and are not to be construed as limiting the scope of the present invention. Therefore, the true scope of the present invention should be defined by the appended claims and their equivalents.
All the synthetic procedures were performed in a dry dinitrogen atmosphere. All the solvents used were distilled over sodium-benzophenone under nitrogen prior to use. Benzo[b]thiophene-2-boronic acid and 2-bromopyridine were purchased from Sigma-Aldrich and used without further purification. Glassware, syringes, magnetic stirring bars, and needles were dried in a convection oven for over 4 h. Reactions were monitored by thin-layer chromatography (TLC; Merck Co.). The spots developed onto TLC were identified under UV light at 254 or 365 nm. Column chromatography was performed on silica gel 60 G (particle size 5-40 μm; Merck Co.). The synthesized compounds were characterized by 1H-NMR, 13C-NMR, and HR-MS. 1H- and 13C-NMR spectra were recorded using a Varian Mercury 300 spectrometer operating at 300.1 and 75.4 MHz, respectively. The elemental analyses were performed using a Carlo Erba Instruments CHNSO EA 1108 analyzer by the Korean Basic Science Institute. HR-MS analysis was performed on an LC/MS/MSn (n=10) spectrometer (Thermo Fisher Scientific, LCQ Fleet Hyperbolic Ion Trap MS/MSn Spectrometer).
Ir(III) complexes (Ir-OMe+, Ir-tBu+, Ir-Me+, and Ir—H+), Re(4,4′-Y2-2,2′-bipyridine)(CO)3Cl (ReC (Y═CH2PO3H2), RePE (Y═CH2PO(OC2H5)2)), and organic sensitizer (dye=(E)-2-cyano-3-(5′-(5″-(p-(diphenylamino)phenyl)thiophen-2″-yl)thiophen-2′-yl)-acrylic acid) were prepared.
2-1: Synthesis of [Ir(btp)2(bpy-CN)2]+PF6 (Ir—CN+)
A mixture of Ir-dimer complex (0.088 g, 0.068 mmol) and 4,4′-dicyano-2,2′-bipyridine (bpy-CN: 0.029 g, 0.14 mmol) in ethylene glycol (5.9 mL) was heated at 150° C. for 45 h under nitrogen. The reaction mixture was poured into water (40 mL) and washed with diethyl ether (40 mL×2). To the aqueous layer was added ammonium hexafluorophosphate (0.610 g, 3.74 mmol). The organic mixture products were extracted with dichloromethane (40 mL×2) and the solvent was removed by rotary evaporation under vacuum. The solids were collected by filtration, washed with water and vacuum dried. The obtained crude product was purified by column chromatography on silica gel (solvent: methanol/dichloromethane, 1:6 v/v), followed by recrystallization from dichloromethane through n-hexane vapor diffusion to yield complex Ir—CN+ as dark-green crystals (0.056 g, 0.058 mmol, 85% yield).
1H NMR (300 MHz, DMSO-d6) δ 9.54 (s, 2H), 8.13 (d, J=7.2 Hz, 2H), 8.xx8.0x (m, 4H), 7.95 (m, 4H), 7.77 (d, J=5.7 Hz, 2H), 7.23 (t, J=7.5 Hz, 2H), 7.08 (t, J=6.9 Hz, 2H), 6.88 (t, J=8.0 Hz, 2H), 5.86 (d, J=8.1 Hz, 2H).
13C NMR (100.6 MHz, DMSO-d6) δ 163.17, 155.69, 151.87, 150.89, 145.64, 144.61, 142.10, 140.69, 136.47, 132.10, 128.63, 125.84, 124.49, 124.15, 123.57, 122.67, 122.21, 119.99, 115.65.
ESI-MS calcd. for C44H36F6IrN6PS2, 819.0977 [M-PF6+; found 819 [M-P F6+.
2-2: Confirmation of Synthesized Molecular Structures
Cationic IrIII-complexes denoted as Ir—X+PF6−(X=OMe, tBu, Me, H, and CN) were synthesized from dimeric Ir2(btp)4Cl2 and 4,4′-X2-2,2′-bipyridines (X2-bpy) in moderate yields following a literature method. The preparation of Ru(bpy)32+(PF6−)2 used as a comparative photosensitizer was performed according to the published method. The structures of Ir—X+PF6− were confirmed by the spectroscopic and elemental analyses.
In particular, Ir—H+PF6− and Ir-OMe+PF6− gave fine crystals relevant to X-ray crystallographic analysis, revealing a monoclinic crystal system of the P21/n space group with reliability factors of R1=0.0315 and 0.0286, respectively. The (2-pyridyl)benzo[b]thiophen-3-yl ligands are commonly bonded to the iridium(III) center with cis-C,C and trans-N,N dispositions (
3-1:Crystal Structure Determination
Fine crystals of Ir—H+ and Ir-OMe+ obtained from a dichloromethane/n-hexane solution were sealed in glass capillaries under argon, and mounted on a diffractometer. The preliminary examination and data collection were performed using a Bruker SMART CCD detector system single-crystal X-ray diffractometer equipped with a sealed-tube X-ray source (50 kV×30 mA) using graphite monochromated Mo Kα radiation (λ=0.71073 Å). The preliminary unit cell constants were determined using a set of 45 narrowframe (0.3° in ω ) scans. The double pass method of scanning was used to exclude noise. The collected frames were integrated using an orientation matrix determined from the narrow-frame scans. The SMART software package was used for data collection, and SAINT was used for frame integration. The final cell constants were determined through global refinement of the xyz centroids of the reflections harvested from the entire dataset. Structure solution and refinement were carried out using the SHELXTL-PLUS software package.
3-2: Cyclic Voltammetry (CV)
CV was performed for an acetonitrile or DMF solution containing each of the electroactive compounds (1 mM) and 0.1 M tetrabutylammonium perchlorate at room temperature under an Ar atmosphere using a BAS 100B electrochemical analyzer equipped with a platinum working electrode, a platinum wire counter electrode, and an Ag/AgNO3 (0.1 M) reference. All the potentials were calibrated to the ferrocene/ferrocenium (Fc/Fc+) redox couple.
3-3: Steady-State and Time-Resolved Spectroscopic Measurements
Absorption spectra were recorded on a Shimadzu (UV-3101PC) scanning spectrophotometer. Emission and excitation spectra were measured by using a Varian fluorescence spectrophotometer (Cary Eclipse). For time-resolved spectroscopy, an Ar-purged acetonitrile solution of Ir—X+ was irradiated with 309 nm pulses, which were generated by modulating the third harmonic (355 nm) of a Q-switched Nd:YAG laser (Continuum, Surelite II, pulse width of 4.5 ns) with an H2-Raman shifter. The emitted phosphorescence was recorded using an ICCD detector (Andor, iStar) equipped with a monochromator (DongWoo Optron, Monora 500i). The temporal profiles were measured using a monochromator equipped with a photomultiplier (Zolix Instruments Co., CR 131) and a digital oscilloscope (Tektronix, TDS-784D). Phosphorescence lifetimes were measured according to a single photon counting method using a streak scope (Hamamatsu Photonics, C10627-03) equipped with a polychromator (Acton Research, SP2300). Ultra-short laser pulses were generated from a Ti:sapphire oscillator (Coherent, Vitesse, FWHM 100 fs) pumped with a diode-pumped solid-state laser (Coherent, Verdi). High-power (1.5 mJ) pulses were generated using a Ti:sapphire regenerative amplifier (Coherent, Libra, 1 kHz). The pulses at 330 nm generated from an optical parametric amplifier (Coherent, TOPAS) were used as the excitation light. The temporal emission profiles were well-fitted to a single-exponential function. The time resolution is ˜20 ps after the deconvolution procedure. The fitting was judged by weighted residuals and the X2 values.
3-4: Photophysical Properties of Ir—X+
The UV-visible absorption and emission spectra of Ir—X+ were measured in acetonitrile. The absorption maxima and molar extinction coefficients are summarized in Table 1. All complexes commonly reveal intense absorptions at ˜250 and ˜350 nm assignable as the Π-Π* transitions of the X2-bpy and btp ligands, respectively, and a less intense absorption band at ˜430 nm attributable to a transition with a dominant contribution of IrIII-to-btp charge transfer (
The emission spectra of Ir—X+ were measured in degassed acetonitrile at room temperature, and the data are summarized in Table 1. The Ir(III) complexes reveal similar phosphorescence spectra with the maxima at ˜590 and ˜640 nm accompanied by a shoulder at ˜701 nm, while Ir—CN+ is virtually nonemissive even at 77 K. Table 1 lists the quantum yields (Φ) and lifetimes (T) of phosphorescence for the four emissive complexes, which uniquely depend on the substituent (X) of the bpy ligand. From the observed values of Φ and T, the rate constants of the radiative and nonradiative pathways (kr and knr) were calculated. While the kr values are similar with minor differences, knr increases in the order Ir-OMe+≈Ir-tBu+≤Ir-Me+<<Ir—H+, an interesting dependence on the bulkiness and/or electron-donating character of X. Since the emissive complexes reveal almost identical phosphorescence spectra and similar kr values independently of the X2-bpy ligand, the btp ligand should be dominantly involved in the emissive excited state accompanied by a small or negligible contribution of the X2-bpy ligand. The phosphorescence of Ir—X+ should commonly occur from a state with a dominant or major contribution of the btp-centered triplet (3LC) mixed with a metal-to-ligand charge-transfer (3MLCT) character, as reported for similar heteroleptic and homoleptic IrIII analogues with the btp ligand. On the other hand, the knr values significantly vary with X, suggesting that the X2-bpy ligands significantly contribute to the nonradiative decay process (or processes) from the emissive state. A possible assumption is that vibrational modes in the X2-bpy ligands would be more or less coupled with the crossing from the emissive state to other nonemissive state(s), e.g. a metal-centred triplet state (3MC). Alternatively, the electron-donating OMe, tBu, and Me substituents would more or less enhance the electron density on the Ir(III) centre in the excited state to result in an increase of the barrier for the crossing to the nonradiative state(s). In the case of Ir-CN+, the strong electron-withdrawing effect of the two CN substituents should cause a significant reduction of the electron density on the metal centre to result in a barrierless crossing to the putative 3MC state. Alternatively, the lowest-excited singlet state of Ir—CN+ different from that of the other complexes would undergo direct intersystem crossing to a nonemissive triplet state. At any rate, if the nonemissive state would be coupled with a chemical change of Ir—X+, the Ir(III) complexes are not attractive as PS. Fortunately, it was confirmed that all the complexes are totally stable under long-term irradiation in DMF (
TABLE 1 Photophysical properties of Ir—X+
[a]λabs (nm) (ε (103 M−1 cm−1))
[b]λem (nm)
[c]φ
[d]τ (μs)
[e]kr (104 s−1)
[f]knr (105 s−1)
[g]—
[g]—
[g]—
[g]—
[g]—
[a]Absorption maxima (molar extinction coefficient).
[b]Phosphorescence maxima.
[c]Phosphorescence quantum yield measured in deaerated acetonitrile.
[d]Phosphorescence lifetime measured in deaerated acetonitrile.
[e]Radiative rate constant.
[f]Nonradiative rate constant.
[g]No luminescence.
3-5: Electrochemical Properties of Ir—X+
The electrochemical properties of Ir—X+ were examined by cyclic voltammetry (CV), the data of which are summarized in Table 2. Typical CV scans of Ir—X+ are shown in
[a]E1/2ox [V]
[a]E1/2red [V]
[b]E0-0 [eV]
[e]HOMO [eV]
[e]LUMO [eV]
[c]Ered* (V)
[d]Eox* (V)
[a]Epa = anodic peak potential, Epc = cathodic peak potential, and E1/2 = (Epc + Epa)/2 vs SCE.
[b]E0-0 denotes triplet energy estimated from the phosphorescence data at 77 K.
[c]Excited-state reduction potential estimated using Ered* = E1/2red + E0-0.
[d]Excited-state oxidation potential estimated using Eox* = E1/2ox − E0-0.
[e]HOMO and LUMO levels were determined using the following equations: EHOMO (eV) = −e(E1/2ox + 4.42), ELUMO (eV) = −e(E1/2red + 4.42).
4-1: Preparation of TiO2/ReC Catalyst
Commercially available TiO2 particles with specific Brauner-Emmet-Teller (BET) surface areas of ≥250 m2/g were thoroughly washed with distilled water, ultrasonically treated in water, separated by centrifugation, and then dried in an oven under N2. The TiO2 particles (0.125 g) were stirred overnight in a 50 mL solution of ReC (fac-[Re(4,4′-Bis(dihydroxyphosphorylmethyl)-2,2′-bipyridine)(CO)3Cl]) (1 μmol) in MeCN/tert-butanol, and then subjected to centrifugation. The collected solids were washed with the solvent and then dried in an oven under N2. The successful anchoring of ReC on TiO2 was confirmed by the IR absorption bands characteristic of the CO ligands at 2025, 1920, and 1910 cm−1.
4-2: Photocatalyzed CO2 Reduction
Suspensions of TiO2/ReC particles (0.1 μmol ReC on 10 mg TiO2) in 3 ml N,N-dimethylformamide (DMF) containing 1 mM PS ( Ir—X+ or Ru(bpy)32+), 0.1 M BIH, and 2.5 vol % H2O were placed in a pyrex cell (˜1 cm pass length; 6.0 mL total volume), bubbled with CO2 for 30 min, sealed with a septum, and then irradiated under stirring with visible light at ≥400 nm emitted from a LED lamp (60 W, Cree Inc.). Homogeneous-solution photoreactions were performed for 3 mL DMF solutions of Ir—X+ (0.5 mM), RePE (0.5 mM), and BIH (0.1 M). The amounts of CO evolved in the overhead space of the cell were determined by gas chromatography (HP6890A GC equipped with a TCD detector) using a 5 Å molecular sieve column. The liquid phase of the irradiated samples was subjected to HPLC analysis using a Waters 515 pump, a Waters 486 UV detector operated at 210 nm, a Rspak KC-811 Column (Shodex) and 0.05 M H3PO4 aqueous solution eluent.
4-3: Confirmation of Photocatalytic CO2 Reduction
The hybrid catalyst (TiO2/ReC) was prepared by anchoring Re(4,4′-Y2-bpy)(CO)3Cl (Y═CH2PO3H2) on TiO2 particles. Suspensions of TiO2/ReC particles in CO2-saturated DMF containing PS ( Ir—X+ or Ru(bpy)32+, 1 mM), BIH (0.1 M), and 2.5 vol % H2O were irradiated at ≥400 nm using a LED lamp (60 W, Cree Inc.). When using Ir—X+ as a photosensitizer, the photoreactions gave CO as the exclusive CO2-reduction product accompanied by negligible amounts of H2 and formic acid, while in the case of Ru(bpy)32+ two CO2-reduction products (CO and HCOOH) were produced comparably with small amount of H2 production. It was confirmed that little CO was formed in the absence of either or both of PS and BIH.
4-4: Comparison with the Other Photosensitization Systems
For comparison, the other photosensitization systems ((a) and (b) of
Eqs 1-6 of
The second important process is collisional electron injection from PS−· into TiO2 followed by transport of the injected electron (TiO2(e−) to ReC (eq 2). The electron injection should depend on the differences between the conduction-band edge of TiO2 and the oxidation potential of PS−·. The latter is approximately given by the anodic peak (Epared) in the reduction wave of PS listed in
On the other hand, the conduction-band edge of TiO2 is known to be close to the experimentally determined flat-band potential (Efb), which is ˜−1.50 V vs SCE for a TiO2 nanoparticle film in the presence of 3% water in DMF. If the Efb value is applicable to the present TiO2 particles dispersed in DMF, the electron injection from PS−· into TiO2 should be endergonic by 0.12˜0.23 eV (
Under such conditions, the electron injection might only slowly proceed in equilibrium with electron reversal from TiO2(e−) to PS. It should be, however, noted that each PS−· generated by irradiation of PS in the presence of BIH can survive for several hours in the absence of TiO2, long-lived enough to undergo slow electron injection into TiO2 (
In an effort to estimate the collisional electron transfer kinetics from the PS−· to the TiO2, the samples were prepared with adding 1 mg TiO2 particles into Ar-saturated DMF solution involving 0.1 mM Ir-tBu+ and 10 mM BIH and 2.5 vol % H2O. The quenching behaviour of [Ir-tBu+]−· absorption peak by TiO2 is monitored under the dark condition, which is maintained after 5 min. irradiation to generate the reductively quenched [Ir-tBu+]−· species in the presence of BIH. The faster component (˜38 s) might be assigned to electron transfer from PS−· to TiO2 in diffusion layer, while the slower component (˜44 min.) can be assigned to the long-lived PS−· in the outward diffusion layer of TiO2 surfaces. With increasing the amount of TiO2 particles (ranging from 1 to 4 mg), the decay of absorption peak is substantially accelerated (˜10 s, the faster phase), indicating that the collisional electron transfer from PS−19 to TiO2 is highly sensitive to the surface area of added TiO2 particles (eq 2). Based on these observations, the inventors reason that the electron transfer rate on diffusion layer is in a few second at real photocatalysis using 10 mg TiO2 particles.
In reality, TiO2 nanoparticles have complex chemical and morphological features on their surfaces (14c) and a variety of energetically distributed trap sites, so that electrons injected from an excited-state dye may reveal complex kinetic behavior (S. H. Lee et al., Org. Lett., 12:460-23, 2010). It was reported that very fast trapping of electrons occurs with subpicosecond time constants on bandgap excitation of TiO2 particles, whereas other investigations indicated the existence of long-lived electrons. This means that the electrons injected into a TiO2 particle should show complex kinetic behavior, as has been demonstrated by multiple-component decays of transients formed by electron injection from a photoexcited dye into TiO2 as well as by direct photoexcitation of TiO2. Therefore, a crucial question emerges about what CR process(es) would be essential in determining the net efficiencies of H2 generation.
Under such circumstances, it can be presumed that the net efficiency of electron transport to ReC would be sensitively affected by various factors such as the small differences in Epared, steric properties of PS and distributions of the odd electron in PS−·. Provided that the photosensitization efficiencies in the early stage of the reaction are related to the amounts of injected electrons, it is of interest to note that Ir-OMe+ is significantly more efficient as photosensitizer than Ir-tBu+ and Ir-Me+ even though the Epared differences are only 40 mV. Presumably, the strong electron-donating effect of the OMe substituents would prevent significant population of the odd electron on the bpy ligand to push the electron toward the btp ligand. In the other PS−·, however, the negative charge would be more or less delocalized over the whole ligands. The particular electronic character of [Ir-OMe+]−· might be indicated by the broad spectrum different from the common sharp spectra for other (Ir-X+)−·. In photoreaction using Ru(bpy)32+ as PS, the relatively low selectivity and activity of CO production can be explained by the catalytic production of HCOOH (a competitive by-product) by [Ru(bpy)2(DMF)2]2+-type complexes, which would be generated via photochemical ligand substitution during photolysis. The formation of dimeric Ru complexes is evidenced by the absorption peaks reshaped with a substantial decrease of original absorption peak of [Ru(bpy)32+]−· under continuous light irradiation. From these data, it can be concluded that free Ir complexes are more suitable as a photosensitizer in photocatalytic CO2 reduction system than Ru complex.
The reduction of CO2 to CO requires net two-electron transfer to ReC from TiO2(e−), which should sequentially proceed. The simultaneous transfer of two electrons as an alternative process is unlikely to occur, because Efb of TiO2 is considerably less negative than the two-electron reduction potential of ReC. The one-electron reduced species of ReC (ReC−·=L(CO)3ReCl−·) generated by the initial one-electron transfer from TiO2(e−) to ReC gives the 17-electron species (L(CO)3Re·) as a key intermediate after the liberation of Cl− (eq 3) followed by coordination of a solvent molecule (eq 4). This species is known to interact with CO2, probably by the coordination of CO2 to the metal center (eq 5). Although the follow-up processes are not fully explored, the second electron transfer should occur with electrons deposited in TiO2 after the coordination of CO2 to complete the CO2 reduction under participation of protons (eq 6).
These chemical processes (eq 3 -6) can be considered to be slower than the electron-transfer processes (eq 1 and 2), a situation that leads to a mismatch between the electron flow and the chemical processes. As the consequence, PS−· might be increasingly accumulated in solution with elapsing of irradiation time after TiO2 has been filled up with electrons. In cases where PS−· undergo chemical changes during the CO2reduction, the efficiency of photosensitized CO formation would start to drop after PS has been significantly consumed. This might lead to the levelling-off behaviour of photosensitized CO formation observed in a later stage of the reaction. The lower the chemical stability of PS−·, the sooner the levelling-off behaviour would appear. Changes of absorption spectra following irradiation time for Ar-purged DMF solution containing Ir—X+ (X=OMe or tBu) and BIH in the absence of TiO2 are shown in
While details of the present invention have been described above, it will be evident to those skilled in the art that such detailed descriptions are merely preferred embodiments and do not limit the scope of the present invention. Therefore, the true scope of the present invention should be defined by the appended claims and their equivalents.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2017-0020289 | Feb 2017 | KR | national |
