Design of robust 2,2'-bipyridine ligand linkers for the stable immobilization of molecular catalysts on silicon(111) surfaces.

The attachment of the 2,2'-bipyridine (bpy) moieties to the surface of planar silicon(111) (photo)electrodes was investigated using ab initio simulations performed on a new cluster model for methyl-terminated silicon. Density functional theory (B3LYP) with implicit solvation techniques indicated that adventitious chlorine atoms, when present in the organic linker backbone, led to instability at very negative potentials of the surface-modified electrode. In prior experimental work, chlorine atoms were present as a trace surface impurity due to required surface processing chemistry, and thus could plausibly result in the observed surface instability of the linker. Free energy calculations for the Cl-atom release process with model silyl-linker constructs revealed a modest barrier (14.9 kcal mol-1) that decreased as the electrode potential became more negative. A small library of new bpy-derived structures has additionally been explored computationally to identify strategies that could minimize chlorine-induced linker instability. Structures with fluorine substituents are predicted to be more stable than their chlorine analogues, whereas fully non-halogenated structures are predicted to exhibit the highest stability. The behavior of a hydrogen-evolving molecular catalyst Cp*Rh(bpy) (Cp* = pentamethylcyclopentadienyl) immobilized on a silicon(111) cluster was explored theoretically to evaluate differences between the homogeneous and surface-attached behavior of this species in a tautomerization reaction observed under reductive conditions for catalytic H2 evolution. The calculated free energy difference between the tautomers is small, hence the results suggest that use of reductively stable linkers can enable robust attachment of catalysts while maintaining chemical behavior on the electrode similar to that exhibited in homogeneous solution.

[1]  Michael J. Rose,et al.  Tuning p-Si(111) Photovoltage via Molecule|Semiconductor Electronic Coupling. , 2021, Journal of the American Chemical Society.

[2]  M. Baik,et al.  Electro-inductive effect: Electrodes as functional groups with tunable electronic properties , 2020, Science.

[3]  H. Jeon,et al.  Transition metal-based catalysts for the electrochemical CO2 reduction: from atoms and molecules to nanostructured materials. , 2020, Chemical Society reviews.

[4]  E. Sargent,et al.  Molecular enhancement of heterogeneous CO2 reduction , 2020, Nature Materials.

[5]  Y. Surendranath,et al.  Graphite-Conjugation Enhances Porphyrin Electrocatalysis , 2019, ACS Catalysis.

[6]  J. Fettinger,et al.  Electrocatalytic Reduction of CO2 into Formate with Glassy Carbon Modified by [Fe4N(CO)11(PPh2Ph-linker)]− , 2018, Organometallics.

[7]  C. Kubiak,et al.  Covalent attachment of [Ni(alkynyl-cyclam)]2+ catalysts to glassy carbon electrodes. , 2018, Chemical communications.

[8]  Christopher D. Sanborn,et al.  Interfacial Electron Transfer of Ferrocene Immobilized onto Indium Tin Oxide through Covalent and Noncovalent Interactions. , 2018, ACS applied materials & interfaces.

[9]  James D. Blakemore,et al.  Role of Ligand Protonation in Dihydrogen Evolution from a Pentamethylcyclopentadienyl Rhodium Catalyst. , 2017, Inorganic chemistry.

[10]  Hailiang Wang,et al.  Highly selective and active CO2 reduction electrocatalysts based on cobalt phthalocyanine/carbon nanotube hybrid structures , 2017, Nature Communications.

[11]  Gerald J Meyer,et al.  Finding the Way to Solar Fuels with Dye-Sensitized Photoelectrosynthesis Cells. , 2016, Journal of the American Chemical Society.

[12]  W. Goddard,et al.  Selectivity for HCO2– over H2 in the Electrochemical Catalytic Reduction of CO2 by (POCOP)IrH2 , 2016 .

[13]  G. Moore,et al.  Metalloporphyrin-modified semiconductors for solar fuel production , 2016, Chemical science.

[14]  R. Gobetto,et al.  Recent advances in catalytic CO2 reduction by organometal complexes anchored on modified electrodes , 2016 .

[15]  N. Lewis,et al.  Control of the Band-Edge Positions of Crystalline Si(111) by Surface Functionalization with 3,4,5-Trifluorophenylacetylenyl Moieties , 2016 .

[16]  Seokjoon Oh,et al.  Graphite-Conjugated Rhenium Catalysts for Carbon Dioxide Reduction. , 2016, Journal of the American Chemical Society.

[17]  C. Kubiak,et al.  Orientation of Cyano-Substituted Bipyridine Re(I) fac-Tricarbonyl Electrocatalysts Bound to Conducting Au Surfaces , 2016 .

[18]  M. Freund,et al.  Covalent Attachment of Ferrocene to Silicon Microwire Arrays. , 2015, ACS applied materials & interfaces.

[19]  N. Lewis,et al.  Synthesis, Characterization, and Reactivity of Ethynyl- and Propynyl-Terminated Si(111) Surfaces , 2015 .

[20]  W. Goddard,et al.  Activation and Oxidation of Mesitylene C–H Bonds by (Phebox)Iridium(III) Complexes , 2015 .

[21]  Hao Fan,et al.  Synthesis of Zinc Tetraphenylporphyrin Rigid Rods with a Built-In Dipole. , 2015, The journal of physical chemistry. B.

[22]  S. Griveau,et al.  Versatile functionalization of carbon electrodes with a polypyridine ligand: metallation and electrocatalytic H(+) and CO2 reduction. , 2015, Chemical communications.

[23]  J. Durrant,et al.  Improving the Photocatalytic Reduction of CO2 to CO through Immobilisation of a Molecular Re Catalyst on TiO2 , 2015, Chemistry.

[24]  James D. Blakemore,et al.  Assembly, characterization, and electrochemical properties of immobilized metal bipyridyl complexes on silicon(111) surfaces. , 2014, Dalton transactions.

[25]  M. Engelhard,et al.  A hydrogen-evolving Ni(P2N2)2 electrocatalyst covalently attached to a glassy carbon electrode: preparation, characterization, and catalysis. comparisons with the homogeneous analogue. , 2014, Inorganic chemistry.

[26]  Karin J. Young,et al.  Photoelectrochemical oxidation of a turn-on fluorescent probe mediated by a surface MnII catalyst covalently attached to TiO2 nanoparticles , 2014 .

[27]  J. Buriak Illuminating Silicon Surface Hydrosilylation: An Unexpected Plurality of Mechanisms , 2014 .

[28]  P. Persson,et al.  Emerging polymorphism in nanostructured TiO2: Quantum chemical comparison of anatase, rutile, and brookite clusters , 2013 .

[29]  N. Lewis,et al.  Redox Properties of Mixed Methyl/Vinylferrocenyl Monolayers on Si(111) Surfaces , 2013 .

[30]  James D. Blakemore,et al.  Noncovalent immobilization of electrocatalysts on carbon electrodes for fuel production. , 2013, Journal of the American Chemical Society.

[31]  Jing Zhang,et al.  Jaguar: A high-performance quantum chemistry software program with strengths in life and materials sciences , 2013 .

[32]  Jean-Michel Savéant,et al.  Catalysis of the electrochemical reduction of carbon dioxide. , 2013, Chemical Society reviews.

[33]  I. Sharp,et al.  A Noble-Metal-Free Hydrogen Evolution Catalyst Grafted to Visible Light-Absorbing Semiconductors. , 2013, The journal of physical chemistry letters.

[34]  Gonghu Li,et al.  Covalent attachment of a molecular CO2-reduction photocatalyst to mesoporous silica , 2012 .

[35]  J. Vos,et al.  Electrocatalytic pathways towards sustainable fuel production from water and CO2 , 2012 .

[36]  J. Mayer,et al.  Distant protonated pyridine groups in water-soluble iron porphyrin electrocatalysts promote selective oxygen reduction to water. , 2012, Chemical communications.

[37]  R. Hamers,et al.  Covalent attachment of catalyst molecules to conductive diamond: CO2 reduction using "smart" electrodes. , 2012, Journal of the American Chemical Society.

[38]  Petter Persson,et al.  Photoinduced electron transfer processes in dye-semiconductor systems with different spacer groups. , 2012, The Journal of chemical physics.

[39]  Thomas F. Jaramillo,et al.  New insights into the electrochemical reduction of carbon dioxide on metallic copper surfaces , 2012 .

[40]  T. Meyer,et al.  Selective electrocatalytic reduction of CO2 to formate by water-stable iridium dihydride pincer complexes. , 2012, Journal of the American Chemical Society.

[41]  Robert C. Snoeberger,et al.  Covalent attachment of a rhenium bipyridyl CO2 reduction catalyst to Rutile TiO2. , 2011, Journal of the American Chemical Society.

[42]  James D. Blakemore,et al.  Half-sandwich iridium complexes for homogeneous water-oxidation catalysis. , 2010, Journal of the American Chemical Society.

[43]  R. McCreery,et al.  Advanced carbon electrode materials for molecular electrochemistry. , 2008, Chemical reviews.

[44]  D. Truhlar,et al.  The M06 suite of density functionals for main group thermochemistry, thermochemical kinetics, noncovalent interactions, excited states, and transition elements: two new functionals and systematic testing of four M06-class functionals and 12 other functionals , 2008 .

[45]  N. Lewis,et al.  Powering the planet: Chemical challenges in solar energy utilization , 2006, Proceedings of the National Academy of Sciences.

[46]  K. Raghavachari,et al.  The emergence of collective vibrations in cluster models: quantum chemical study of the methyl-terminated Si(111) surface. , 2006, The Journal of chemical physics.

[47]  N. Lewis,et al.  Chemical and electrical passivation of silicon (111) surfaces through functionalization with sterically hindered alkyl groups. , 2006, The journal of physical chemistry. B.

[48]  W. Goddard,et al.  Quantum Chemical Calculations of the Influence of Anchor-Cum-Spacer Groups on Femtosecond Electron Transfer Times in Dye-Sensitized Semiconductor Nanocrystals. , 2006, Journal of chemical theory and computation.

[49]  Philip G. Jessop,et al.  Recent advances in the homogeneous hydrogenation of carbon dioxide , 2004 .

[50]  R. Mendelsohn,et al.  Excited State Electron Transfer from Ru(II) Polypyridyl Complexes Anchored to Nanocrystalline TiO2 through Rigid-Rod Linkers , 2004 .

[51]  Elena Galoppini,et al.  Linkers for anchoring sensitizers to semiconductor nanoparticles , 2004 .

[52]  R. Cicero,et al.  Photoreactivity of Unsaturated Compounds with Hydrogen-Terminated Silicon(111) , 2000 .

[53]  A. Deronzier,et al.  Electroreduction of CO2 catalyzed by polymeric [Ru(bpy)(CO)2]n films in aqueous media: Parameters influencing the reaction selectivity , 1998 .

[54]  W. H. Weinberg,et al.  Alkylation of Si Surfaces Using a Two-Step Halogenation/Grignard Route , 1996 .

[55]  C. Chatgilialoglu Structural and Chemical Properties of Silyl Radicals , 1995 .

[56]  Payne,et al.  Periodic boundary conditions in ab initio calculations. , 1995, Physical review. B, Condensed matter.

[57]  Yun-Dong Wu,et al.  Substituent Effect on the Dissociation Energy of the Si-H Bond: A Density Functional Study , 1995 .

[58]  A. Becke Density-functional thermochemistry. III. The role of exact exchange , 1993 .

[59]  Corwin Hansch,et al.  A survey of Hammett substituent constants and resonance and field parameters , 1991 .

[60]  B. P. Sullivan,et al.  Electrocatalytic reduction of carbon dioxide by 2,2'-bipyridine complexes of rhodium and iridium , 1988 .

[61]  H. Abruña Coordination chemistry in two dimensions: chemically modified electrodes , 1988 .

[62]  Parr,et al.  Development of the Colle-Salvetti correlation-energy formula into a functional of the electron density. , 1988, Physical review. B, Condensed matter.

[63]  M. Wrighton,et al.  Surface Functionalization of Electrodes with Molecular Reagents , 1986, Science.

[64]  Timothy Clark,et al.  Efficient diffuse function‐augmented basis sets for anion calculations. III. The 3‐21+G basis set for first‐row elements, Li–F , 1983 .

[65]  Mark S. Gordon,et al.  Self‐consistent molecular orbital methods. XXIII. A polarization‐type basis set for second‐row elements , 1982 .

[66]  T. Meyer,et al.  An electrode-supported oxidation catalyst based on ruthenium(IV). pH "encapsulation" in a polymer film , 1981 .

[67]  R. Murray,et al.  CHEMICALLY MODIFIED ELECTRODES , 1977 .

[68]  T. Saji,et al.  Polarographic studies on bipyridine complexes , 1975 .

[69]  J. Pople,et al.  Self—Consistent Molecular Orbital Methods. XII. Further Extensions of Gaussian—Type Basis Sets for Use in Molecular Orbital Studies of Organic Molecules , 1972 .

[70]  Aaron J. Sathrum,et al.  Electrocatalytic and homogeneous approaches to conversion of CO2 to liquid fuels. , 2009, Chemical Society reviews.

[71]  S. Cosnier,et al.  Carbon/poly {pyrrole-[(C5Me5)RhIII(bpy)Cl]+} modified electrodes; a molecularly-based material for hydrogen evolution (bpy = 2,2′-bipyridine) , 1989 .

[72]  W. R. Wadt,et al.  Ab initio effective core potentials for molecular calculations. Potentials for K to Au including the outermost core orbitals , 1985 .

[73]  J. Pople,et al.  Self‐consistent molecular orbital methods. XX. A basis set for correlated wave functions , 1980 .