Publications

  1. Y. Xie, S. D. Minteer, S. Banta and S. C. Barton, “Markov State Study of Electrostatic Channeling within the Tricarboxylic Acid Cycle Supercomplex”, ACS Nanosci. Au, 2, 414–421 (2022). doi:10/gqkvtq
  2. M. C. O. Monteiro, A. Mirabal, L. Jacobse, K. Doblhoff-Dier, S. Calabrese Barton and M. T. M. Koper, “Time-Resolved Local pH Measurements during CO 2 Reduction Using Scanning Electrochemical Microscopy: Buffering and Tip Effects”, JACS Au, 1, 1915–1924 (2021). doi:10/gm6t96
  3. A. Mirabal and S. Calabrese Barton, “Numerical Correction of In Situ AFM-SECM Measurements”, Anal. Chem., 93, 12495–12503 (2021). doi:10/gmrwqq
  4. Y. Xie and S. Calabrese Barton, “Infrequent metadynamics study of rare-event electrostatic channeling”, Phys. Chem. Chem. Phys., 23, 13381 (2021). doi:10/gkgmtf
  5. M. S. Dhawan, G. D. Yadav and S. Calabrese Barton, “Zinc-electrocatalyzed hydrogenation of furfural in near-neutral electrolytes”, Sustainable Energy Fuels, 5, 2972 (2021). doi:10/gj3gp7
  6. K. S. Chavan and S. C. Barton, “Confinement and Diffusion of Small Molecules in a Molecular-Scale Tunnel”, J. Electrochem. Soc., 167, 023505 (2020). doi:10.1149/1945-7111/ab6dd2
  7. Y. Liu, D. P. Hickey, S. D. Minteer, A. Dickson and S. Calabrese Barton, “Markov-State Transition Path Analysis of Electrostatic Channeling”, J. Phys. Chem. C, 123, 15284–15292 (2019). doi:10.1021/acs.jpcc.9b02844
  8. M. Yates, S. Strycharz-Glaven, J. Golden, J. Roy, S. Tsoi, J. Erickson, M. El-Naggar, S. Calabrese Barton and L. Tender, “Characterizing Electron Transport through Living Biofilms”, J. Vis. Exp., (2018). doi:10.3791/54671
  9. K. S. Chavan and S. Calabrese Barton, “Simulation of Intermediate Channeling by Nanoscale Confinement”, J. Phys. Chem. C, 122, 14474–14480 (2018). doi:10.1021/acs.jpcc.8b01922
  10. Y. Liu, I. Matanovic, D. P. Hickey, S. D. Minteer, P. Atanassov and S. Calabrese Barton, “Cascade Kinetics of an Artificial Metabolon by Molecular Dynamics and Kinetic Monte Carlo”, ACS Catal., 8, 7719–7726 (2018). doi:10.1021/acscatal.8b01041
  11. R. Pavlicek, S. Calabrese Barton, N. Leonard, H. Romero, S. McKinney, G. McCool, A. Serov, D. Abbott, P. Atanassov and S. Mukerjee, “Resolving Challenges of Mass Transport in Non Pt-Group Metal Catalysts for Oxygen Reduction in Proton Exchange Membrane Fuel Cells”, J. Electrochem. Soc., 165, F589–F596 (2018). doi:10.1149/2.0141809jes
  12. Y. Wu, K. N. Subramanian, S. Calabrese Barton and A. Lee, “Electrochemical studies of Pd-doped Cu and Pd-doped Cu-Al intermetallics for understanding corrosion behavior in wire-bonding packages”, Microelectron. Reliab., 78, 355–361 (2017). doi:10.1016/j.microrel.2017.09.024
  13. S. Rojas-Carbonell, S. Babanova, A. Serov, K. Artyushkova, M. J. Workman, C. Santoro, A. Mirabal, S. Calabrese Barton and P. Atanassov, “Integration of Platinum Group Metal-Free Catalysts and Bilirubin Oxidase into a Hybrid Material for Oxygen Reduction: Interplay of Chemistry and Morphology”, ChemSusChem, 10, 1534–1542 (2017). link
  14. C. Gumeci, D. Do and S. Calabrese Barton, “Electrospun Carbon Nanofibers as Supports for Bioelectrodes”, Electrocatalysis, 8, 321–328 (2017). link
  15. E. Earl and S. Calabrese Barton, “Simulation of intermediate transport in nanoscale scaffolds for multistep catalytic reactions”, Phys. Chem. Chem. Phys., 19, 15463–15470 (2017). link
  16. Y. Liu, D. P. Hickey, J.-Y. Guo, E. Earl, S. Abdellaoui, R. D. Milton, M. S. Sigman, S. D. Minteer and S. Calabrese Barton, “Substrate Channeling in an Artificial Metabolon: A Molecular Dynamics Blueprint for an Experimental Peptide Bridge”, ACS Catal., 7, 2486–2493 (2017). link
  17. H. M. Bambhania, D. Chakraborty, H. Wen and S. Calabrese Barton, “Impact of Oxygen on Glucose Oxidation Kinetics in a Redox Polymer Mediated Glucose Oxidase Electrode”, J. Electrochem. Soc., 164, H232–H240 (2017). link
  18. J. Anibal, H. G. Romero, N. D. Leonard, C. Gumeci, B. Halevi and S. Calabrese Barton, “Effect of silica morphology on the structure of hard-templated, non-precious metal catalysts for oxygen reduction”, Appl. Catal. B Environ., 198, 32–37 (2016). link
  19. Q. Jia, N. Ramaswamy, U. Tylus, K. Strickland, J. Li, A. Serov, K. Artyushkova, P. Atanassov, J. Anibal, C. Gumeci, S. Calabrese Barton, M.-T. Sougrati, F. Jaouen, B. Halevi and S. Mukerjee, “Spectroscopic insights into the nature of active sites in iron–nitrogen–carbon electrocatalysts for oxygen reduction in acid”, Nano Energy, 29, 65–82 (2016). link
  20. M. D. Yates, S. M. Strycharz-Glaven, J. P. Golden, J. Roy, S. Tsoi, J. S. Erickson, M. Y. El-Naggar, S. Calabrese Barton and L. M. Tender, “Measuring conductivity of living Geobacter sulfurreducens biofilms”, Nat. Nanotechnol., 11, 910–913 (2016). link
  21. I. Wheeldon, S. D. Minteer, S. Banta, S. Calabrese Barton, P. Atanassov and M. Sigman, “Substrate channelling as an approach to cascade reactions”, Nat. Chem., 8, 299–309 (2016). link
  22. M. D. Yates, J. Golden, J. Roy, S. M. Strycharz-Glaven, S. Tsoi, J. Erickson, M. Y. El-Naggar, S. Calabrese Barton and L. Tender, “Thermally Activated Long Range Electron Transport in Living Biofilms”, Phys. Chem. Chem. Phys., 17, 32564–32570 (2015). link
  23. C. Gumeci, N. Leonard, Y. Liu, S. McKinney, B. Halevi and S. Calabrese Barton, “Effect of pyrolysis pressure on activity of Fe–N–C catalysts for oxygen reduction”, J. Mater. Chem. A3, 21494–21500 (2015). link
  24. S. Calabrese Barton, “1D Models for Enzymatic Biological Fuel Cells”, Interface Mag., 24, 61–65 (2015). link
  25. N. D. Leonard, K. Artyushkova, B. Halevi, A. Serov, P. Atanassov and S. Calabrese Barton, “Modeling of Low-Temperature Fuel Cell Electrodes Using Non-Precious Metal Catalysts”, J. Electrochem. Soc.162, F1253–F1261 (2015). link
  26. N. D. Leonard and S. Calabrese Barton, “Analysis of Adsorption Effects on a Metal-Nitrogen-Carbon Catalyst Using a Rotating Ring-Disk Study”, J. Electrochem. Soc.161, H3100–H3105 (2014). link
  27. D. Chakraborty, E. McClellan, R. Hasselbeck and S. Calabrese Barton, “Characterization of Enzyme-Redox Hydrogel Thin-Film Electrodes for Improved Utilization”, J. Electrochem. Soc.161, H3076–H3082 (2014). link
  28. H. Li, R. Li, R. M. Worden and S. Calabrese Barton, “Facilitation of High-Rate NADH Electrocatalysis Using Electrochemically Activated Carbon Materials.”, ACS Appl. Mater. Interfaces, (2014). link
  29. S. Ganesan, N. Leonard and S.C. Barton, “Impact of transition metal on nitrogen retention and activity of iron-nitrogen-carbon oxygen reduction catalysts.” Physical Chemistry Chemical Physics : PCCP16(10), 4576–4585 (2014). link
  30. N. Leonard, V. Nallathambi and S. Calabrese Barton, “Carbon Supports for Non-Precious Metal Oxygen Reducing Catalysts”, J. Electrochem. Soc.160, F788-F792 (2013). link
  31. N. D. Leonard, S. Ganesan, V. Nallathambi, and S. Calabrese Barton, “Alkalinity of Non-Precious Metal Catalysts for Oxygen Reduction,” ECS Transactions50(2), 1869–1873 (2013). link
  32. H. Li, K. E. Worley and S. Calabrese Barton, “Quantitative Analysis of Bioactive NAD+ Regenerated by NADH Electro-oxidation”, ACS Catal., 2, 2572–2576 (2012). link
  33. H. Li, H. Wen and S. Calabrese Barton, “NADH Oxidation Catalyzed by Electropolymerized Azines on Carbon Nanotube Modified Electrodes,” Electroanalysis24(2), 398-406 (2012). link
  34. H. Wen, H.M. Bambhania, S. Calabrese Barton, “Carbon nanotube-modified biocatalytic microelectrodes with multiscale porosity”, Journal of Applied Electrochemistry 42(3) 145-151 (2012). link
  35. H. Wen, V. Nallathambi, D. Chakraborty and S. Calabrese Barton, “Carbon Fiber Microelectrodes Modified With Carbon Nanotubes as a New Support for Immobilization of Glucose Oxidase”, Microchimica Acta175(3-4), 283-289 (2011). link
  36. V. Nallathambi, N. Leonard, R. Kothandaraman and S. Calabrese Barton, “Nitrogen Precursor Effects in Iron-Nitrogen-Carbon Oxygen Reduction Catalysts,” Electrochemical and Solid State Letters14(6), B55-B58 (2011). link
  37. P. Kar, H. Wen, H. Li, S. D. Minteer and S. Calabrese Barton, “Simulation of Multistep Enzyme-Catalyzed Methanol Oxidation in Biofuel Cells,” Journal of the Electrochemical Society158(5), B580-B586 (2011).   link
  38. D. Chakraborty and S. Calabrese Barton, “Influence of Mediator Redox Potential on Fuel Sensitivity of Mediated Laccase Oxygen Reduction Electrodes,” Journal of the Electrochemical Society158(4), B440-B447 (2011). link
  39. R. Kothandaraman, V. Nallathambi, K. Artyushkova and S. Calabrese Barton, “Non-precious oxygen reduction catalysts prepared by high-pressure pyrolysis for low-temperature fuel cells,” Applied Catalysis B: Environmental92(2), 209-216 (2009). link
  40. S. Calabrese Barton, “Enzyme Catalysis in Biological Fuel Cells,” in Handbook of Fuel Cells – Fundamentals, Technology and Applications (eds. Vielstich, W., Gasteiger, H. A. & Yokokawa, H.) 112-130 (John Wiley and Sons, Ltd., London, 2009). link1link2
  41. J. W. Gallaway and S. A. Calabrese Barton, “Effect of redox polymer synthesis on the performance of a mediated laccase oxygen cathode,” Journal of Electroanalytical Chemistry626(1-2), 149-155 (2009). link
  42. N. S. Hudak, J. W. Gallaway and S. Calabrese Barton, “Formation of Mediated Biocatalytic Cathodes by Electrodeposition of a Redox Polymer and Laccase,” Journal of Electroanalytical Chemistry629, 57-62 (2009). link
  43. N. S. Hudak, J. W. Gallaway and S. Calabrese Barton, “Mediated Biocatalytic Cathodes Operating on Gas-Phase Air and Oxygen in Fuel Cells,” Journal of the Electrochemical Society156(1), B9-B15 (2009). link
  44. K. A. Vincent, S. Calabrese Barton, G. W. Canters and H. A. Heering, “Electrocatalysis for fuel cells at enzyme-modified electrodes,” in Fuel Cell Catalysis: a Surface Science Approach (ed. Koper, M. T. M.) 593-636 (Wiley, Hoboken, New Jersey, 2009). link
  45. H. Wen, K. Ramanujam and S. Calabrese Barton, “Multiscale Carbon Materials as Supports for Bioelectrodes,” ECS Transactions13(21), 67-76 (2008). link
  46. C. Hettige, S. Minteer and S. Calabrese Barton, “Simulation of Multi-Step Enzyme Electrodes,” ECS Transactions, 13(21), 99-109 (2008). link
  47. I. R. Wheeldon, J. Gallaway, S. Calabrese Barton and S. Banta, “Bioelectrocatalytic hydrogels from electron-conducting metallo-polypeptides co-assembled with bifunctional enzymatic building blocks,” PNAS105(40), 15275-15280 (2008). link
  48. R. Kothandaraman, W. Deng, M. Sorkin, A. Kaufman, H. F. Gibbard and S. Calabrese Barton, “Methanol Anode Modified by Semipermeable Membrane for Mixed-Feed Direct Methanol Fuel Cells,” Journal of the Electrochemical Society155(9), B865-B868 (2008). link
  49. J. Gallaway and S. Calabrese Barton, “Kinetics of redox polymer-mediated enzyme electrodes,” Journal of the American Chemical Society130(26), 8527-8536 (2008). link
  50. J. E. Trancik, S. Calabrese Barton and J. Hone, “Transparent and Catalytic Carbon Nanotube Films,” Nano Letters8(4), 982-987 (2008). link
  51. V. Svoboda, M. Cooney, B. Y. Liaw, S. Minteer, E. Piles, D. Lehnert, S. Calabrese Barton, R. Rincon and P. Atanassov, “Standardized Characterization of Electrocatalytic Electrodes,” Electroanalysis20(10), 1099-1109 (2008). link
  52. J. Gallaway, I. Wheeldon, R. Rincon, P. Atanassov, S. Banta and S. Calabrese Barton, “Oxygen-Reducing Enzyme Cathodes Produced from SLAC, a Small Laccase from Streptomyces coelicolor,” Biosensors and Bioelectronics, 23(8), 1229-1235 (2008). link
  53. I. R. Wheeldon, S. Calabrese Barton and S. Banta, “Bioactive Proteinaceous Hydrogels from Designed Bifunctional Building Blocks,” Biomacromolecules8(10), 2990-2994 (2007). link
  54. P. Atanassov, C. Apblett, S. Banta, S. Brozik, S. Calabrese Barton, M. Cooney, B. Y. Liaw, S. Mukerjee and S. D. Minteer, “Enzymatic biofuel cells”, Interface-Electrochemical Soc., 16, 28–31 (2007). link
  55. S. Calabrese Barton, Y. Sun, B. Chandra, S. White and J. Hone, “Mediated Enzyme Electrodes with Combined Micro- and Nanoscale Supports,” Electrochemical and Solid-State Letters10(5), B96-B100 (2007). link
  56. Y. Sun and S. Calabrese Barton, “Methanol Tolerance of a Mediated, Biocatalytic Oxygen Cathode,” Journal of Electroanalytical Chemistry590(1), 57-65 (2006). link
  57. N. S. Hudak and S. Calabrese Barton, “Mediated Biocatalytic Cathode for Direct Methanol Membrane-Electrode Assemblies,” Journal of the Electrochemical Society152(5), A876-A881 (2005). link
  58. S. Calabrese Barton, “Oxygen Transport in Composite Mediated Biocathodes,” Electrochimica Acta50, 2145-2153 (2005). link
  59. S. Calabrese Barton, J. Gallaway and P. Atanassov, “Enzymatic Biofuel Cells for Implantable and Microscale Devices,” Chemical Reviews, 104(10), 4867-4886 (2004). link
  60. S. Calabrese Barton, M. Pickard, R. Vazquez-Duhalt and A. Heller, “Electroreduction of O2 to Water at 0.6 V (NHE) at pH 7 on the ‘Wired’ Pleurotus ostreatus Laccase Cathode”, Biosensors & Bioelectronics17, 1071-1074 (2002). link
  61. Z. Gao, G. Binyamin, H.-H. Kim, S. Calabrese Barton, Y. Zhang and A. Heller, “Electrodeposition of Transition Metal Complex-based Redox Polymers by Coordinative Cross-linking”, Angewandte Chemie41, 810-813 (2001). link
  62. S. Calabrese Barton, H.-H. Kim, G. Binyamin, Y. Zhang and A. Heller, “Electroreduction of O2 to Water on the ‘Wired’ Laccase Cathode”, Journal of Physical Chemistry B105, 11917-11921 (2001). link
  63. T. Chen, S. Calabrese Barton, G. Binyamin, Z. Gao, Y. Zhang, H.-H. Kim, and A. Heller, “A Miniature Biofuel Cell”, Journal of the American Chemical Society123, 8630-8631 (2001). link
  64. S. Calabrese Barton, H.-H. Kim, G. Binyamin, Y. Zhang and A. Heller, “The ‘Wired’ Laccase Cathode: High Current Density Electroreduction of O2 to Water at +0.7 V (NHE) at pH 5”, Journal of the American Chemical Society123, 5802-5803 (2001). link
  65. S. Calabrese Barton and A. C. West, “Electrodissolution of Zinc at the Limiting Current”, Journal of the Electrochemical Society147 (5) (2001). link
  66. S. Calabrese Barton and A. C. West, “Electrohydrodynamic Impedance in the Presence of Nonuniform Transport Properties”, Journal of the Electrochemical Society147 (4) (2001). link
  67. S. Calabrese Barton, T. Patterson, E. Wang, T. F. Fuller, and A. C. West, “Mixed-Reactant, Strip-Cell Direct Methanol Fuel Cells”, Journal of Power Sources96 (2), 329-336 (2001). link
  68. S. Calabrese Barton, B. L. Murach, T. F. Fuller, and A. C. West, “A Methanol Sensor for Portable Direct Methanol Fuel Cells,” Journal of the Electrochemical Society145, 3783 (1998). link
  69. S. A. Barton and P. F. Dunn, “A Theoretical and Experimental Investigation of Electrostatically Charged, Falling Droplet Pairs,” Journal of Applied Phyics67, 3201 (1990). link

 

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