Brian Landi Headshot

Brian Landi

Professor

Department of Chemical Engineering
Kate Gleason College of Engineering

585-475-4726
Office Location

Brian Landi

Professor

Department of Chemical Engineering
Kate Gleason College of Engineering

Education

BS, MS, Ph.D., Rochester Institute of Technology

585-475-4726

Areas of Expertise

Select Scholarship

Journal Paper
Leggiero, Anthony P, et al. "High Conductivity Copper–Carbon Nanotube Hybrids via Site-Specific Chemical Vapor Deposition." ACS Applied Nano Materials. (2019): 118-126. Print.
Wilhelm, Thomas S, et al. "Fabrication of Ordered Si Micropillar Arrays via Carbon Nanotube-Assisted Chemical Etching." ACS Applied NanoMaterials. (2019): 9b01838. Print.
Soule, Karen J, et al. "Sustaining Enhanced Electrical Conductivity in KAuBr4‑Doped Carbon Nanotube Wires at High Current Densities." ACS Applied NanoMaterials. (2019): 9b01859. Web.
Staub, Jason W, et al. "Balancing Irreversible Capacity in Geranium Nanoparticle: HE5050 Lithium Ion Batteries for Improved Energy Densities Exceeding 250 Wh/kg." Electrochimica Acta. (2019): 135455. Web.
Bucossi, Andrew R., et al. "Effects of Solution Properties on Iodine Monobromide Doping for Enhanced Carbon Nanotube Electrical Conductivity." ACS Applied Nano Materials 1. 5 (2018): 2088-2094. Print.
Crompton, Kyle R., et al. "Lithium-ion Cycling Performance of Multi-Walled Carbon Nanotube Electrodes and Current Collectors Coated with Nanometer Scale Al2O3 by Atomic Layer Deposition." Electrochimica Acta 292. (2018): 628-638. Print.
Leggiero, Anthony P., et al. "High Conductivity Copper–Carbon Nanotube Hybrids via Site-Specific Chemical Vapor Deposition." ACS Applied Nano Materials 2. 1 (2018): 118–126. Print.
Amori, A., et al. "Defects Enable Dark Exciton Photoluminescence in Single-Walled Carbon Nanotubes." J. Phys. Chem. C 122. (2018): 3599-3607. Print.
Crompton, Kyle R., et al. "Lithium Rich Cathode/Graphite Anode Combination for Lithium Ion Cells with High Tolerance to Near Zero Volt Storage." Journal of Power Sources 343. (2017): 109-118. Print.
Rossi, Jamie E., et al. "Removal of Sodium Dodecyl Sulfate Surfactant From Aqueous Dispersions of Single-Wall Carbon Nanotubes." Journal of Colloid and Interface Science 495. (2017): 140-148. Print.
Robinson, J.T., et al. "Graphene Strained by Defects." ACS Nano 11. 5 (2017): 4745-4752. Print.
Cox, Nate D., et al. "Modification of Silver/Single-Wall Carbon Nanotube Electrical Contact Interfaces via Ion Irradiation." ACS Appl. Mater. Interfaces 9. 8 (2017): 7406-7411. Print.
Cress, Cory D., et al. "Carbon Nanotube Wires with Continuous Current Rating Exceeding 20 Amperes." Journal of Applied Physics 122. (2017): 1-8. Print.
Lee, Y.B., et al. "Synthesis and Property of Polyimines Containing 2,2,4,4-Tetramethyl-1,3-Cyclobutadiimine Moiety." Macromol. Res 25. 6 (2017): 578-583. Print.
Crompton, Kyle R., et al. "Enhanced Overdischarge Stability of LiCoO2 by Solution Deposited AlPO4 Coating." J. Electrochemical Society 164. 13 (2017): A3214-A3219. Print.
K.R., Crompton, and Landi, B.J. "Opportunities for Near Zero Volt Storage of Lithium Ion Batteries." Energy & Environmental Science 9. (2016): 2219-2239. Print.
J.E., Rossi,, et al. "Enhanced Electrical Transport in Carbon Nanotube Thin Films through Defect Modulation." The Journal of Physical Chemistry C 120. 28 (2016): 15488-15495. Print.
I., Puchades,, et al. "Carbon Nanotube Thin-Film Antennas." ACS Applied Materials & Interfaces 8. 32 (2016): 20986-20992. Print.
N.D., Cox,, et al. "Free-Standing Silver/Carbon Nanotube Metal Matrix Composite Thin Films." Journal of Materials Science 51. 24 (2016): 10935-10942. Print.
Rossi, J.E., et al. "Intrinsic Diameter Dependent Degradation of Single-wall Carbon Nanotubes from Ion Irradiation." Carbon 81. (2015): 488-496. Print.
Zeidell, A.M., et al. "Cyclopentadienyliron Dicarbonyl Dimer Carbon Nanotube Synthesis." Journal of Vacuum Science & Technology B 33. (2015): 11204. Print.
Rossi, Jamie E., et al. "Intrinsic Diameter Dependent Degradation of Single-Wall Carbon Nanotubes from Ion Irradiation." Carbon 81. (2015): 488-496. Print.
Zeidell, Andrew M., et al. "Cyclopentadienyliron Dicarbonyl Dimer Carbon Nanotube Synthesis." Journal of Vacuum Science & Technology B 33. 1 (2015): 011204-01-011204-5. Print.
Bucossi, Andrew R., et al. "Enhanced Electrical Conductivity in Extruded Single-Wall Carbon Nanotube Wires from Modified Coagulation Parameters and Mechanical Processing." ACS Applied Materials & Interfaces 7. (2015): 27299-27305. Print.
Merrill, Andrew, et al. "Threshold Displacement Energies in Graphene and Single-Walled Carbon Nanotubes." Physical Review B 92. 7 (2015): 75404. Print.
Puchades, Ivan, et al. "Mechanism of Chemical Doping in Electronic-Type-Separated Single Wall Carbon Nanotubes Towards High Electrical Conductivity." Journal of Materials Chemistry C. 39 (2015): 10256-10266. Print.
Cox, N.D., et al. "Spatially Selective Au Nanoparticle Deposition and Raman Analysis of Ion-irradiated Single-wall Carbon Nanotubes." The Journal of Physical Chemistry C 118. (2014): 14031-14038. Print.
Forney, M.W., et al. "Advanced Ge Nanoparticle Composite Anodes Using Single Wall Carbon Nanotube Conductive Additives." Journal of Materials Chemistry A 2 35. (2014): 14528-14535. Print.
Ganter, M.J., et al. "Cathode Refunctionalization As A Lithium Ion Battery Recycling Alternative." Journal of Power Sources 256. (2014): 274-280. Print.
Schauerman, C.M., et al. "Ultrasonic Welding of Bulk Carbon Nanotube Conductors." Advanced Engineering Materials 17. (2014): 76–83. Print.
Wang, X., et al. "Economic And Environmental Characterization Of An Evolving Li-ion Battery Waste Stream." Journal of Environmental Management 135. (2014): 126-134. Print.
Forney, Michael, et al. "Prelithiation of Silicon-Carbon Nanotube Anodes for Lithium Ion Batteries by Stabilized Lithium Metal Powder (SLMP)." Nano Letters 13. 9 (2013): 4158-4163. Print.
Forney, Michael, et al. "High Capacity Si-carbon Nanotube Anodes for Lithium Ion Batteries." Journal of Intelligence Community Research and Development. (2013): February 8. Web.
Forney, Michael, et al. "High Performance Silicon Free-standing Anodes Fabricated by Low-pressure and Plasma-enhanced Chemical Vapor Deposition onto Carbon Nanotube Electrodes." Journal of Power Sources 228. (2013): 270-280. Print.
Rogers, Reginald, et al. "Impact of Microwave Synthesis Conditions on the Rechargeable Capacity of LiCoPO4 for Lithium Ion Batteries." Journal of Applied Electrochemistry 43. (2013): 271-278. Print.
Anctil, Annick, et al. "Cumulative Energy Demand for Small Molecule and Polymer Photovoltaics." Progress in Photovoltaics: Research and Applications. (2012): DOI: 10.1002/pip.2226. Print.
Jarosz, Paul R., et al. "High Performance Lightweight Coaxial Cable from Carbon Nanotube Conductors." ACS Applied Materials and Interfaces 4. (2012): 1103-1109. Print.
Schauerman, Chris M., et al. "Recycling Single-Wall Carbon Nanotube Anodes from Lithium Ion Batteries." J. Mater. Chem. 22. (2012): 12008-12015. Print.
Cress, Cory D., et al. "Radiation Effects in Carbon Nanoelectronics." Electronics 1. (2012): 23-31. Web.
Rossi, Jamie E., et al. "Ion Irradiation of Electronic-Type-Separated Single Wall Carbon Nanotubes: A Model for Radiation Effects in Nanostructured Carbon." J. Appl. Phys 112. (2012): 34314. Print.
Lu, F., et al. "Surface Oxidation of Single-Walled Carbon Nanotube Paper with Oxygen Atoms." Journal of Adhesion Science and Technology. (2012): DOI:10.1080/ 01694243.2012.705093. Web.
Jarosz, Paul R., et al. "Coaxial Cables with Single-Wall Carbon Nanotube Outer Conductors Exhibiting Attenuation/Length within Specification." IEEE Micro Nano Lett. 7. (2012): 959-961. Web.
DiLeo, Roberta, et al. "Balanced Approach to Safety of High Capacity Silicon Germanium Carbon Nanotube Free-Standing Lithium Ion Battery Anodes." Nano Energy. (2012): DOI:10.1016/j.nanoen.2012.09.007. Print.
Anctil, A. and C.W. Babbitt, R.P. Raffaelle, B.J. Landi. "Material and Energy Intensity of Fullerene Production." Environmental Science & Technology 45. (2011): 2353-2359. Print.
Ganter, M.J. and R.A. DiLeo, C.M. Schauerman, R.E. Rogers, R.P. Raffaelle, B.J. Landi. "Differential Scanning Calorimetry Analysis of an Enhanced LiNi0.8Co0.2O2 Cathode with Single Wall Carbon Nanotube Conductive Additives." Electrochim. Acta 56. (2011): 7272-7277. Print.
Rogers, R. E., et al. "Solution-phase Adsorption of 1-pyrenebutyric Acid Using Single-wall Carbon Nanotubes." Chemical Engineering Journal 173. (2011): 486-493. Print.
Cress, C. D., et al. "Total Ionizing Dose-hardened Carbon Nanotube Thin-film transistors with Silicon Oxynitride Gate Dielectrics." MRS Communications 1. (2011): 27-31. Print.
Jarosz, P., et al. "Carbon Nanotube Wires and Cables: Near-Term Applications and Future Perspectives." Nanoscale 3. (2011): 4542-4553. Print.
DiLeo, R. A., et al. "Hybrid Germanium Nanoparticle-Single Wall Carbon Nanotube Free-Standing Anodes for Lithium Ion Batteries." The Journal of Physical Chemistry 115. (2011): 22609-22614. Print.
Published Conference Proceedings
Rossi, Jamie, et al. "Radiation Response of Single Wall Carbon Nanotube Thin-Films as a Function of Electronic-Type and Diameter." Proceedings of the 2013 Annual Government Microcircuit Applications and Critical Technology Conference, Las Vegas, Nevada, March 2013. Ed. In Microelectronics for Net-Enabled and Cyber-Transformational Technologies. Las Vegas, NV: n.p., Web.
Cress, C.D., et al. "Radiation -Hardening of Carbon Nanoelectronics." Proceedings of the Government Microcircuit Applications and Critical Technologies Conference. Ed. GOMAC Tech. Orlando, FL: n.p., 2011. Print.
Published Article
Cress, C.D., C.M. Schauerman, B.J. Landi, S.R. Messenger, R.P. Raffaelle, and R.J. Walters. “Radiationeffects in single walled carbon nanotubepapers.” Journal of Applied Physics, 107.1(2010): 1-5. Web. " É *
Landi, B.J., C.D. Cress, and R.P. Raffaelle. “High energy density lithium ion batteries with carbon nanotube anodes.” Journal of Materials Research, 25.8 (2010): 1636. Print. É *
DiLeo, R.A., M.J. Ganter, R.P. Raffaelle, B.J. Landi.“Germanium-Single Wall Carbon NanotubeAnodes for Lithium Ion Batteries.” Journal of Materials Research, 25.8 (2010): 1441-1446. Print. " É *
Dileo, R.A., A.Castiglia, M.J. Ganter, R.E. Rogers, C.D. Cress, R.P. Raffaelle, and B.J. Landi. “Enhanced Capacity and Rate Capability of Carbon Nanotube Based Anodes with Titanium Contacts for Lithium Ion Batteries.” ACS Nano, 4.10 (2010): 6121-6131. Web. " É *
Alvarenga, J., P.R. Jarosz, C.M. Schauerman, B.T. Moses, B.J. Landi, C.D. Cress, and R.P. Raffaelle.“High conductivity carbon nanotube wiresfrom radial densification and ionic doping.”Applied Physics Letters, 97.18 (2010): 182106-1-3. Print. " É *

Currently Teaching

CHME-650
3 Credits
The course focuses on applications of electrochemical phenomena with examples of practical materials and processes. Fundamental considerations will include charge transfer at electrode/electrolyte interphases, surface modification by electrodeposition and etching, and corrosion. Electroanalytical techniques will be described including potentiometry, voltammetry, and electrochemical impedance analysis. Applications of electrochemical engineering will be summarized in detail for batteries, capacitors, and fuel cells; including conventional materials and fabrication techniques. A special emphasis on the use of nanomaterials in electrochemical engineering will be investigated.
CHME-550
3 Credits
The course focuses on applications of electrochemical phenomena with examples of practical materials and processes. Fundamental considerations will include charge transfer at electrode/electrolyte interphases, surface modification by electrodeposition and etching, and corrosion. Electroanalytical techniques will be described including potentiometry, voltammetry, and electrochemical impedance analysis. Applications of electrochemical engineering will be summarized in detail for batteries, capacitors, and fuel cells; including conventional materials and fabrication techniques. A special emphasis on the use of nanomaterials in electrochemical engineering will be investigated.
CHME-499
0 Credits
One semester of paid work experience in chemical engineering.