Electrocatalytic CO2 Reduction: Monitoring of Catalytically Active, Downgraded, and Upgraded Cobalt Complexes

The premise of most studies on the homogeneous electrocatalytic CO2 reduction reaction (CO2RR) is a good understanding of the reaction mechanisms. Yet, analyzing the reaction intermediates formed at the working electrode is challenging and not always attainable. Here, we present a new, general approach to studying the reaction intermediates applied for CO2RR catalyzed by a series of cobalt complexes. The cobalt complexes were based on the TPA-ligands (TPA = tris(2-pyridylmethyl)amine) modified by amino groups in the secondary coordination sphere. By combining the electrochemical experiments, electrochemistry-coupled electrospray ionization mass spectrometry, with density functional theory (DFT) calculations, we identify and spectroscopically characterize the key reaction intermediates in the CO2RR and the competing hydrogen-evolution reaction (HER). Additionally, the experiments revealed the rarely reported in situ changes in the secondary coordination sphere of the cobalt complexes by the CO2-initiated transformation of the amino substituents to carbamates. This launched an even faster alternative HER pathway. The interplay of three catalytic cycles, as derived from the experiments and supported by the DFT calculations, explains the trends that cobalt complexes exhibit during the CO2RR and HER. Additionally, this study demonstrates the need for a molecular perspective in the electrocatalytic activation of small molecules efficiently obtained by the EC-ESI-MS technique.


■ INTRODUCTION
−6 Numerous molecular catalysts, based on the transition metal complexes, have been proposed for CO 2 reduction, generally exhibiting good product selectivity. 7,8However, they often display mediocre electrocatalytic performance, possibly due to the poisoning or degradation of the catalyst or undesirable side reactions. 1,9,10he in-depth investigation of the electrolytic CO 2 reduction reaction mechanism is thus imperative for developing efficient and robust molecular catalysts.Although several remarkable mechanistic studies have been reported, 11−15 the fate of the catalysts during the electrocatalytic CO 2 reduction with a molecular-level insight remains under-investigated.This is primarily attributed to the limited availability of suitable analytical tools.
During the electrocatalytic CO 2 reduction, a homogeneous molecular catalyst can follow three routes: (i) the catalyst reduces at the cathode and initiates electrocatalytic CO 2 reduction; (ii) the catalyst is poisoned, which stops or slows down the catalysis; (iii) the catalyst is in situ modified, changing its catalytic activity or giving rise to undesired side reactions (Scheme 1).Conventional electroanalytical techni-ques such as cyclic voltammetry (CV) and controlled potential electrolysis (CPE) provide crucial information about product selectivity and catalyst efficiency; however, they lack molecularlevel insight and, therefore, cannot immediately distinguish and monitor the contributions of the three scenarios (i−iii).
−18 The in situ IR-SEC provides mechanistic details of the formation of CO 2 RR products such as CO or formic acid, electron transfer kinetics, and the electrochemical behavior of the molecular catalysts during electrocatalysis.However, with this technique, only the bulk properties of the reaction mixture are examined, limiting the detailed molecularlevel insight into the state of the molecular catalysts. 18oreover, the solution matrix effects can significantly alter the spectroscopic analyses of the reaction intermediates during in situ mechanistic studies. 19An online method that allows the intermediates to be separated from the reaction mixture is crucial for attaining a comprehensive molecular perspective on the fate of the catalysts during electrocatalysis.
To monitor the intermediates, we developed an online coupling of an electrochemical cell with electrospray-ionization mass-spectrometry monitoring (EC-ESI-MS). 20The EC-ESI-MS technique transfers the intermediates from the solution to the gas phase, allowing us to characterize their structures with spectroscopic and mass spectrometric techniques.−25 Nonetheless, the mechanistic study of electrochemical CO 2 RR using EC-MS techniques remains scarce. 20ere, we present the study of the reaction intermediates in the electrocatalytic CO 2 reduction reaction with Co(II) catalysts having TPA-based ligands (TPA = Tris(2pyridylmethyl)amine).The TPA ligands differ in the number of amino groups in the secondary coordination sphere (Scheme 2).Using EC-ESI-MS experiments, we could monitor the fate of the Co(II) complexes during CO 2 reduction in the presence of water.We captured and fully assigned structures of several cobalt intermediates, including the CO-poisoned complex and a cobalt-hydride intermediate from the competing hydrogen evolution reaction.In addition, we observed a rarely reported in situ modification of the amino substituents of the cobalt complexes into carbamates.This, in turn, modified the catalytic properties of the respective cobalt complexes.Combining all experiments with DFT calculations provided a cohesive picture of all of the reaction pathways during the studied electrocatalytic CO 2 reduction reactions.
This study demonstrates the need for a molecular perspective in studying the fate of a catalyst during electrocatalysis.

Electrocatalytic CO 2 Reduction Activity of Cobalt
Complexes.We first analyzed the performance of cobalt complexes in electrocatalytic CO 2 reduction by cyclic voltammetry and controlled potential electrolysis.All cobalt complexes studied in this paper comprised of Co(II) center, and we refer to them as TPACo, MAPACo, BAPACo, and TAPACo, thus without the counteranions and the oxidation state (Scheme 2).−30 The main objective of this work was to study the impact of the amino groups in the secondary coordination sphere of the TPACo complex on the electrocatalytic CO 2 reduction reaction at the molecular level using electrochemical techniques, the EC-ESI-MS technique, and DFT calculations.
All CV experiments were done in 0.1 M nBu 4 PF 6 DMF electrolyte solution with 0.5 mM cobalt complex at a scan rate of 100 mV s −1 .Unless stated otherwise, the potentials are given against the ferrocene (Fc + /Fc) couple.−33 The Co II/I reduction was homogeneous and diffusion-controlled for all the Co(II) complexes (Figures S9−S12

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V); MAPACo: E p = −2.07V; BAPACo: E p = −2.10V; TAPACo: E p = −2.18V.The negative peak-current shift is accompanied by the increase of the I cat /I p values in order TPACo: 4.2 < MAPACo: 4.3 < BAPACo: 5.6 < TAPACo: 6.7 (Figure 1 and Figure S7).Interestingly, we also observed a precatalytic wave with the BAPACo and TAPACo complexes  around −1.8 V, suggesting the preassociation with CO 2 .Finally, all complexes showed a large catalytic current wave beyond −2.5 V around the Co I/0 reduction process (CO 2 saturation and 3 M water).This process is dominated by the hydrogen evolution reaction (HER), as this feature was also observed under the argon atmosphere in the presence of water (see Figure S7).
The products of the CO 2 RR were analyzed after controlled potential electrolysis (CPE) experiments in the presence of 3 M water at −2.0 V for 1 h (Figure 1c and Table S4).The headspace analysis by gas chromatography showed that all Co(II) complexes yield carbon monoxide and H 2 (Table S4).No other CO 2 RR products were observed.The parent complex TPACo yielded nearly an equimolar mixture of CO and H 2 , albeit with a low Faradaic yield (FE CO = 11 ± 3%).Introducing the amino substituents into the catalyst's secondary coordination sphere resulted in a progressively higher yield of the hydrogen evolution reaction (Figure 1c and Table S4).Interestingly, the performance for CO production was similar among all Co(II) complexes, as is evidenced by approximately the same amount of CO produced by all Co(II) complexes.The increasing number of amino substituents in the secondary coordination sphere positively affected only the yield of the hydrogen evolution reaction.
EC-ESI-MS Experiments with Parent Complex TPACo, Capturing the CO 2 RR Intermediates.We further studied the CO 2 RR using electrochemistry-electrospray ionization mass spectrometry (EC-ESI-MS) experiments.Our EC-ESI-MS cell is a standard electrochemical cell equipped with a working electrode, embedding a silica capillary directly connected to the electrospray ionization source of a mass spectrometer (Figure S1). 20An overpressure in the cell induces a flow of the reaction solution through the working electrode toward ESI-MS.The setup allows us to detect the reaction intermediates by the mass spectrometer as a function of the electrode potential.The electrode potential is referenced to the ferrocene (Fc + /Fc) couple (Figure S20).
By ramping the electrode potential stepwise to negative potentials, we observed a progressive increase of the signals of  S25).We did not observe any significant effect of the water concentration on the relative intensities and identities of the detected intermediates (Figure S23).
Spectroscopy Characterization of the Detected Intermediates.The detailed structure of the captured intermediates was further studied by helium-tagging infrared photodissociation (IRPD) spectroscopy (Figure S37).The IRPD experiments provide IR spectra of mass-selected ions cooled to the ground vibrational state.Accordingly, we acquired well-resolved IR spectra of isolated gaseous ions that can be assigned based on the comparison with theoretical spectra as demonstrated for [(TPA)Co I (CO)] + in Figure 2c.The IR spectrum of [(TPA)Co I (CO)] + showed the CO stretching band at 1984 cm −1 .The observed CO vibrations are higher than the CO stretching wavenumbers of the reported Co I carbonyl species in solution. 32,34By comparing with DFT results, we could assign all observed bands in the fingerprint region to the particular IR signatures of the TPA ligand of the Co(II) complex TPACo in the triplet spin state (S = 1) (see the assignment in Figure 2c, for the singlet state, see Figure S38).
Noticeably, the [(TPACo) 2 (CO)(H)] + (m/z 727) species did not exhibit any CO stretching vibration in the range of 1700 to 2000 cm −1 (Figure S40).We deduced that m/z 727 species could be formed by the in-source collision-induced dissociation of the dimer [(TPA)Co(μ-CO) 2 Co(TPA)(H)] + , which might have induced reactive changes to the structure.
These dimeric complexes combining the hydrido ligand and the CO molecule(s) suggest a prospect of further reduction of CO.However, we did not detect any highly reduced products.Possibly, the dimers formed during the transfer to the gas phase, during which the concentration of the solute increases due to the evaporation of the solvent molecules from the droplets, 35 S28).The only significant difference could be a lower abundance of  S29, and for CID see Figure S30).The dimeric intermediates had an abundance lower than those in the experiments with TPACo and MAPACo.In addition, we detected low-abundance Co(II) complexes with m/z 422 that incorporated a CO 2 molecule.Accordingly, these ions eliminate CO 2 in the CID experiment (Figure S30d).Their m/z ratio suggests that one amino group could have been transformed to the carbamate functionality (NHCOO − ); we denote these ions as [( NHCOO BAPA)Co] + .
Finally, three amino groups in the secondary coordination sphere of the TAPACo complex had the most prominent effect.The expected Co(I) complexes were not detected at all.Instead, we detected Co(II) complexes with the carboxylation modification of the ligand, leading to complexes with a carbamate functionality in the secondary coordination sphere (Figure 4d and Figure S31): [( NHCOO TAPA)Co] + (m/z 437, NHCOO TAPA refers to the anionic ligand with one amino group transformed to the carbamate functionality).The complexes easily eliminated CO 2 during collision-induced dissociation (Figure S32a).S31 and S32).We have also detected the complex incorporating two molecules of CO 2 [( NHCOOCOO TAPA)Co] + (m/z 482, Figures S31 and S32b).These species formed only at higher negative potentials, as indicated by potential ramping EC-ESI-MS experiments (Figure S33).
CO Bond Dissociation Energies of the Detected Carbonyl Complexes.The bond-dissociation energies (BDEs) can be determined in the gas phase 36  Spectroscopy Characterization of the Detected Carbamate Intermediates.The structure of the tentatively assigned complexes with a modified secondary coordination sphere was confirmed based on the IR spectra obtained by helium tagging infrared photodissociation (IRPD) spectroscopy.Note that the carbamate modifications of the amino groups during electrocatalytic CO 2 reduction have been proposed in previous studies. 37,38However, online detection of carbamatemodified amino groups in secondary coordination has not been reported.Helium tagging IRPD spectrum of the [( NHCOO TAPA)Co] + complexes (m/z 437) revealed carbonyl stretching vibration at 1750 cm −1 and showed distinct N−H vibrations (Figure 5).This signature is fully captured if we compare the experimental spectrum with the DFT-calculated IR spectrum of the Co(II) complex with carbamate modification of one of the amino groups; the carbamate oxygen atom is coordinated to the Co(II) center (Figure 5).The other amino groups stabilize the carbamate moiety by hydrogen bonding, which is indicated by the broadening and the red shift of two NH stretching vibrations (3240 and 3322 cm −1 ).The complex has the quartet ground state (S = 3/2).The doublet spin state (S = 1/2) lies at 51.8 kJ mol −1 higher in energy (Figure S44).
Building the Reaction Pathways by DFT Calculations.To rationalize and connect all experimental results, we performed DFT calculations (PBE0-D3/def2-SVPP/CPCM-(DMF)) of possible reaction pathways (see the Supporting Information for full computational details).Multiple potential reaction paths were examined with a specific account for the possible conformational and spin-state changes during the elementary steps.The minimum-energy reaction paths were proposed based solely on thermodynamic considerations and

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used to rationalize the experimental observations.Calculations revealed that the minor changes in the conformations of the NH 2 -containing Co complexes might give rise to notable (up to 15 kJ mol −1 ) variations in the stability of the intermediates due to the changes in the intermolecular hydrogen bonding.This work limits the discussion to the lowest-energy configurations predicted within the implicit solvation approximation (CPCM).The quantitative analysis would require the use of explicit solvation models along with an appropriate sampling to account for the pronounced dynamics and configurational freedom of the considered catalytic system.During the mechanistic exploration, the protonation and reduction at both the Co and basic sites of the ligand and the possibility of the change of the spin-state (S = 0, 1, 2 for the Co I and Co III states, and S = 1/2 and 3/2 for the Co II state) were considered.In the end, the most thermodynamically favorable reaction sequence for each reaction mechanism was identified.
The CO 2 RR starts with the coordination of the CO 2 to the Co(I) complex (1), forming adduct 2 (Co III −CO 2 ̅ , Figure 6a).The subsequent electron transfer, followed by proton transfer to form the Co II −CO 2 H intermediate (4), is the most energydemanding step in this pathway.However, the potential required for reducing 2 lies below the onset potential of the observed CO 2 RR (−1.84 V, see above and Figure S7), implying the viability of this pathway for the observed electrocatalysis.The reaction then continues by protonating 4 followed by H 2 O elimination, forming [(L)Co II −CO] 2+ intermediate 5.This complex is expected to have a short lifetime because it has an exceptionally low reduction potential and small CO-binding energy.Therefore, it either rapidly loses the CO molecule to form 4-coordinate Co(II) complex 6 or gets reduced to the experimentally detected Co I −CO complex 11.The Co(II) complex 6 can be directly reduced to 1, which requires, as expected, a lower potential than the measured Co II /Co I reduction potential.The initial Co(I) complex 1 is also regenerated by the elimination of CO from 11.The binding energy of CO to the Co I −CO complex is 0.97 eV (94 kJ mol −1 ); therefore, the required CO elimination will be a bottleneck of the catalytic reaction.The DFT calculations for the systems with the amino-substituents in the secondary coordination sphere suggest that the ligand modification has a small effect on the energetics of the CO 2 RR pathway (Table S5), which agrees with the experimental results.
The Co(I) complex 1 can also catalyze the HER, although it is favored at higher overpotentials (>−2.2V) (see Figure 6 and Figure S7 for CV).The HER formally starts with the protonation of 1, forming Co III −H intermediate 2 H (Figure 6b and Figure S47).The protonation step is endoergic.However, the subsequent 1-electron reduction is exoergic and will be coupled with the protonation step at the electrode.The  Introducing the NH 2 groups to the ligand opens an alternative reaction pathway in the CO 2 RR.Namely, the reduced Co(I) complexes react in an almost thermoneutral reaction with CO 2 by inserting it into the N−H bond of the amino substituent (Figure 7).The formed Co(I) complex 1 C has a carbamic acid moiety in the secondary coordination sphere.A proton migration from the carbamic acid to the cobalt center is again an almost thermoneutral process and leads directly to cobalt(III)-hydride intermediates 8 C that are stabilized by the coordination of the carbamate anion.This cooperation of the reaction center with the carbamate in the secondary coordination sphere leads to the markedly increased proton affinity of the Co(I) complexes.In addition, only the 1e reduction of the cobalt(III)-hydride intermediates suffices to form an intermediate that can produce H 2 (see also Figure S49).Therefore, Co II −H reduction is not a bottleneck of the observed HER if carbamate is present in the secondary coordination sphere.The H 2 elimination by hydride abstraction from Co II −H complexes 9 C is strongly exoergic.The formed cobalt(II) complexes 5 C are stable complexes with a high reduction potential: 1.96 eV for the MAPACo and BAPACo systems and 2.08 eV for the TAPACo system (see Figure S49).Therefore, the next catalytic cycle is driven by protonation to form 6 C , which can be easily reduced to reform complex 1 C (reduction potentials: 1.62 eV for MAPACo, 1.58 eV for BAPACo, and 1.64 eV for the TAPACo system).Once the amino group is transformed into the carbamate moiety, the competitive CO 2 RR path is substantially hampered.DFT calculations predict that the binding of CO 2 to Co(I) in 1c or 7c complexes (see Figure S50) is thermodynamically disfavored by ca.0.2 eV.

■ DISCUSSION
Combining electrochemical experiments, EC-ESI-MS experiments, and DFT calculations allowed us to propose the detailed reaction pathways of Co(II) complexes during the CO 2 RR in a DMF-water mixture (Scheme 3).
The cyclic voltammetry results showed that the required potential to generate cobalt(I) complexes slightly increased with the modifications of the ligands in the order TPA < Scheme 3. Proposed Catalytic Cycles for CO 2 Reduction Reaction and Hydrogen Evolution Reactions Journal of the American Chemical Society MAPA < BAPA < TAPA (see Figure S7).This is the expected trend, because the order follows the increasing number of electron-donating amino groups.The catalytic current achieved in the presence of water and CO 2 increases in the same order (Figure S7).The I cat /I p values near the Co(II) to Co(I) formation potential (∼ −2 V) increased in the order TPACo < MAPACo < BAPACo < TAPACo (Figure 1).The current increase is mainly due to the competing hydrogen evolution based on the trend observed in the CPE experiments with the CO/H 2 ratios (Figure 1 and Table S4).Interestingly, all cobalt(II) complexes exhibited a similar catalytic activity for the CO 2 reduction reaction.
The efficient hydrogen evolution reaction is conditioned by the presence of CO 2 (Figure S7).The larger efficiency of the hydrogen evolution reaction in the presence of CO 2 can be partly attributed to the decreased pK a due to the formation of the carbonic acid upon CO 2 saturation of the water-containing reaction mixture. 39Although, as we go from the TPACo to TAPACo complex, the amount of formed H 2 increased nearly 7-fold.The sole pK a change does not explain this large effect of the secondary coordination sphere on the activity of the cobalt complex in the presence of CO 2 .Instead, we demonstrate that this effect was caused by modification of the secondary coordination sphere by reaction with CO 2 .
Based on the intermediates detected during EC-ESI-MS experiments for the CO 2 RR and HER, the overall mechanism is divided into three main reaction pathways.
CO 2 Reduction Reaction (CO 2 RR) Pathway.In the presence of water, the CO 2 RR starts with the formation of Co(I) species from Co(II) complex reduction at around −2 V.The [(L)Co I ] + complexes bind and reduce CO 2 , as indicated by the current gain in the presence of CO 2 (Figures S7 and  S8).The so-formed [(L)Co III (CO 2 )] + intermediates get further converted to [(L)Co II (CO 2 H)] + by accepting 1e − and 1H + .Further protonation of this intermediate leads to the formation of [(L)Co II (CO)] 2+ and H 2 O with almost no energy barrier (Figure 6a).The [(L)Co II (CO)] 2+ complex either releases CO and regenerates [(L)Co II ] 2+ or gets reduced to form 18 e − Co(I)-carbonyl species [(L)Co I (CO)] + .This species was detected and fully characterized using the EC-ESI-MS methods for the TPACo, MAPACo, and BAPACo complexes.The release of CO from the Co(I)-carbonyl species [(L)Co I (CO)] + is slow, as indicated by its high abundance in the EC-ESI-MS spectra (Figures 2 and 4).The stability of [(L)Co I (CO)] + in the solution is further supported by a large Co-CO bond-dissociation energy (∼140 ± 4 kJ mol −1 ) of [(L)Co I (CO)] + determined in the gas phase (Figure S35).Furthermore, a large DFT calculated CO binding energy in the Co I −CO complex of 0.97 eV (94 kJ mol −1 ) also corroborates that the formation of Co(I)-carbonyl species essentially corresponds to the poisoning of the CO 2 RR catalysis at the Co II/I reduction potential (approximately −2 V).−43 The CO binding energy decreases with the increasing number of amino substituents, suggesting that the poisoning should weaken in the TPACo > MAPACo > BAPACo > TAPACo series.However, the CO 2 to CO efficiency does not increase (due to competing ligand modification; see below).
At even larger negative potentials (below −2 V, near the Co I/0 reduction potential), the Co(I)-carbonyl species [(L)-Co I (CO)] + can itself become catalytically active and mediate a similar CO 2 RR reaction pathway as depicted in Figure 6a.We propose the presence of this pathway based on the EC-ESI-MS observation of the dimeric species binding two carbonyl groups [(TPA)Co(μ-CO) 2 Co(TPA)(H)] + (Figures 2b and Figure S26).Earlier comprehensive mechanistic study on a similar Co(II) complex by Fernandez et al., 32 showed [(L)Co I (CO)] + species indeed get further reduced at larger negative potential and initiate catalytic CO 2 to CO conversion, supporting our proposition.
Hydrogen  6b).The thermodynamic barrier for the formation of [(L)Co I ] + decreased slightly less with amino functionalization of the Co(II) complexes (Figure 6b).However, the decrease does not vary linearly with the number of amino groups in the secondary coordination sphere of cobalt complexes.Therefore, the thermodynamics of this HER pathway do not corroborate the increasing HER trends with amino-functionalized Co(II) complexes.Interestingly, the potential ramping experiment done with the TPACo complex revealed that the dimeric hydride-carbonyl species dominated the mass spectra at potentials negative to −2 V, substantiating that this HER pathway becomes dominant at highly negative potentials (Figures 2b and Figure S26).Nevertheless, detecting cobalt hydride intermediate by EC-ESI-MS is remarkable as the direct detection and full characterization of hydride intermediates during the electrocatalytic reactions is rarely reported. 11arbamate-Promoted Hydrogen Evolution Reaction (HER CO2 ) Pathway.The CPE experiments in CO 2 -saturated DMF-water mixture of Co(II) complexes showed an increasing H 2 yield in the order TPACo < MAPACo < BAPACo < TAPACo (Figure 1 and Table S4).−46 We corroborate this with in situ modification of the amino groups of the ligands to carbamate groups (NHCOO − ).Remarkably, we observed this modification during the EC-ESI-MS studies under CO 2 with amino-functionalized complexes BAPACo and TAPACo (Figure 4).The ligand modification was confirmed by helium tagging IRPD spectroscopy of the isolated intermediates (Figure 5).The carbamation opened an accelerated hydrogen evolution reaction pathway (Scheme 3, denoted as HER CO2 ).Which, unlike the normal HER, did not consist of a similar thermodynamic bottleneck and was faster at the Co II/I reduction potential (∼-2 V) as demonstrated by DFT calculations (Figure 7 and S49).Therefore, we suggest that this pathway becomes an exclusive HER pathway for amino-functionalized cobalt(II) complexes at the Co II/I reduction potential (approximately −2 V).The carbamate formation with the TAPACo complex was more abundant compared to those of MAPACo and BAPACo Journal of the American Chemical Society (Figure 4), which also paralleled the high HER observed with TAPACo during CPE experiments (Figure 1 and Table S4).This can be attributed to the faster carbamate formation (three amino substituents increase the statistical probability of the reaction) and thermodynamic stabilization of the carbamate moiety by hydrogen bonding interactions with the other amino groups in the TAPACo complex.
In summary, we demonstrated that the EC-ESI-MS studies can elucidate the fate of the catalyst during CO 2 RR catalysis.The reduced Co(I) complexes can catalyze the conversion of CO 2 to CO.In the process, the product Co(I)-carbonyl species poison the catalysis.In competition, the Co(I) complexes can get protonated and follow the HER pathway to evolve H 2 gas.The amino substituents in the secondary coordination sphere of Co(I) complexes get in situ modified to the carbamate function.The carbamate moiety at the cobalt coordination sphere opens an alternative yet faster pathway for the competing hydrogen evolution reaction (Scheme 3).

■ CONCLUSION
We presented here a comprehensive mechanistic study of CO 2 electroreduction catalyzed by a series of Co(II) complexes with modifications by the amino-substituents in the secondary coordination sphere of the TPA-based ligands (TPA = Tris(2pyridylmethyl)amine).All of the complexes electrocatalytically convert CO 2 to CO in the presence of water in DMF at the Co(I) formation potential.The main competing reaction is the hydrogen evolution reaction (HER).With the increasing number of amino groups in the secondary coordination sphere of the Co (II) complexes, the competing levels of H 2 production increased.
Electrochemistry-electrospray ionization mass spectrometry (EC-ESI-MS) provided molecular-level insight into the mechanism of the electrocatalytic reactions.We detected and characterized the intermediates for CO 2 to CO reduction pathways and the hydrogen evolution reaction.We observed in situ modifications of the cobalt complexes by transformation of the amino groups to the carbamate moieties.The structures of the modified complexes were also spectroscopically characterized.Combining DFT calculations with the experimental results from cyclic voltammetry, controlled potential electrolysis, and EC-ESI-MS experiments, we elucidated the fate of cobalt complexes during electrocatalytic CO 2 reduction in DMF-water solutions.During the CO 2 to CO reduction in DMF-water solution at the Co(I) formation potential, Co(I) complexes can either bind CO 2 and carry out 2 e − /2 H + reduction of CO 2 to CO or react with proton to produce H 2 .The CO production involves the rapid formation of the [(L)Co I (CO)] + species, as detected in EC-ESI-MS experiments.This poisons the catalysts and slows the CO 2 RR cycle.The amino groups in the secondary coordination sphere can easily be transformed into carbamate moieties (NHCOO−).The resulting complexes mediate faster hydrogen evolution reactions, explaining the increased production of H 2 with amino-modified Co(II) complexes.
Overall, this study has a broad consequence as EC-ESI-MS techniques can be effectively used in the mechanistic studies of molecular catalysts in the electrochemical activation of small molecules (CO 2 , O 2 , N 2 reduction, water oxidation, etc.).We are currently working to utilize the capabilities of EC-ESI-MS techniques to investigate the mechanisms of other homogeneous electrocatalytic small molecule activation reactions.

■ EXPERIMENTAL SECTION
The syntheses of TPA derivatives bearing a different number of amino groups in the secondary coordination sphere were carried out according to the methods previously reported by our group. 47The corresponding Co(II) complexes were synthesized by the reaction of CoCl 2 .6H 2 O with the ligands in either THF or methanol.The crystals suitable for single-crystal XRD measurements were produced according to the reported procedure. 48The details of the syntheses and characterization of the complexes can be found in the Supporting Information, together with the details of all experiments (see the Supporting Information).
The EC-ESI-MS experiments were carried out with an ion-trap mass spectrometer Thermo Scientific LCQ Deca XP or LTQ XL.The Palmsens potentiostat was used to control the electrode potential in a custom-made flow cell.The flow of the solution from the electrochemical cell to the mass spectrometer was achieved with N 2 or CO 2 overpressure (0.4 to 0.6 bar).The typical ESI-MS source conditions were as follows: capillary temperature 200 °C, spray voltage 4−5 kV, capillary voltage 0 V, and tube lens voltage 10−40 V (see the Supporting Information).
Cyclic voltammetry experiments were carried out in a threeelectrode cell (Metrohm) with a glassy carbon working electrode, platinum plate counter electrode, and nonaqueous Ag, AgCl/LiCl (ethanol) reference electrode (Metrohm).The CV and CPE measurements were performed under an argon or CO 2 atmosphere.The controlled potential electrolysis (CPE) experiments were performed in a custom-made H-cell (see the Supporting Information).
Helium tagging infrared photodissociation (IPRD) experiments were carried out using the ISORI instrument (see the Figure S36). 49,50Typical experiments involved generating reaction intermediates using an electrochemical cell connected to the ESI source of ISORI by analogy with standard EC-ESI-MS experiments.The ions of interest were mass-selected and trapped in a cryogenic trap at 3 K using a helium buffer gas.The trapped and thermalized ions formed complexes with helium atoms.These helium-tagged ions were used to record the IRPD spectra (absorption of a photon increases the internal energy of the helium-tagged ions, resulting in helium detachment).The spectra were recorded in alternating cycles by counting the helium complexes with tunable infrared laser on (N i ) and off (N 0 ) as a function of wavenumber ν I ; the IRPD spectrum is given as 1 − N i /N 0 (see the Supporting Information).

■ ASSOCIATED CONTENT
* sı Supporting Information Scheme 1.(a) Fate of the Molecular Catalyst during Electrocatalytic CO 2 Reduction and (b) Schematics of EC-ESI-MS Setup to Get the Molecular-Level Perspective of the Catalysis

Figure 1 .
Figure 1.(a) CV study with TPACo under argon (black trace, anhydrous conditions) and CO 2 saturation with 3 M water recorded at a 100 mV.s −1 scan rate in the 0.1 M nBu 4 PF 6 in DMF electrolyte solution with 0.5 mM TPACo.I p is the peak current under argon at the Co II/I reduction potential, and I cat is the peak current near the Co II/I reduction process under CO 2 saturation.(b) I cat /I p ratio from the CV experiments with Co(II) complexes: experimental conditions -CO 2 saturated 0.1 M nBu 4 PF 6 in DMF electrolyte with 3 M H 2 O. (c) Selectivity trends in the products generated after 1 h of controlled potential electrolysis (at −2.0 V vs Fc + /Fc; 3 mM Co(II) catalysts, CO 2 saturation, 0.1 M nBu 4 PF 6 in DMF with 3 M H 2 O).

Figure 2 .
Figure 2. Trapping the intermediates of electrochemical CO 2 reduction catalyzed by TPACo complex using the EC-ESI-MS method; (a) cyclic voltammetry experiments with TPACo (0.5 mM) at a 100 mV s −1 scan rate under argon (black) showing Co(I) formation at −2.04 V, the purple trace shows the catalytic current starting near Co(I) formation potential under CO 2 saturation in the presence of 3 M water in 0.1 M nBu 4 PF 6 DMF solution.(b) EC-ESI-MS experiments with TPACo in DMF-MeCN (1:2) under CO 2 with 3 M water at different potentials, 0.2 mM catalyst, 2 mM NaPF 6 as supporting electrolyte.(c) Experimental helium-tagging IRPD spectrum of [(TPA)Co I (CO)] + (m/z 377) (top) generated using EC-ESI-MS experiments from the solution of TPACo in DMF-MeCN (1:2) under CO 2 with 3 M water and the theoretical IR spectrum (bottom, B3LYP-D3/def2svp, the scaling factor was 0.97).(d) The schematic structure and optimized geometry of [(TPA)Co I (CO)] + species at the triplet ground state (S = 1).

Figure 6 .
Figure 6.Free energy profiles for electrocatalytic (a) CO 2 RR and b) HER mediated by Co(II) complexes.
Co II −H intermediate 3 H must undergo another 1-electron reduction, leading to the Co I −H intermediate 4 H .The recombination of the hydride in 4 H with H + is highly exergonic and proceeds with a free energy barrier of only 0.3 eV to produce H 2 and regenerate 1.The bottleneck of this reaction path is the reduction of the Co II −H intermediate 3 H .The required theoretical potential for this step with the [(TPA)-Co] 2+ catalyst is 2.14 eV, which is higher than the observed peak potential for the CO 2 RR.Introducing the amino substituents to the ligand of the catalyst leads to a modest decrease in the energy demand for the 3 H → 4 H reduction step.Accordingly, we observed a decreased selectivity of the CO 2 RR in favor of the HER experimentally.

Figure 7 .
Figure 7. Free energy profiles for electrocatalytic HER enabled by CO 2 -functionalization of the Co(II) complexes with the amino-substituents in the secondary coordination sphere.
Evolution Reaction (HER) Pathway.The HER pathway initiates with the protonation of the Co(I) species [(L)Co I ] + to form the Co hydride species [(L)-Co III (H)] 2+ , which on 2e − reduction generates neutral Co(I)hydride species [(L)Co I (H)].Protonation of [(L)Co I (H)] leads to facile H 2 release and regeneration of [(L)Co I ] + .In concordance with the neutrality of [(L)Co I (H)], we could detect the hydride species only in dimers [(L)Co(μ-CO) 2 Co-(L)(H)] + (for TPACo, MAPACo, and BAPACo) formed by binding with the charged Co(I)-carbonyl complexes.DFT calculations indicated that this pathway is sluggish at the Co II/I reduction potential (approximately −2 V), with the bottleneck being the formation of [(L)Co I ] + (Figure