NREL RPP
Cory D. Jensen's research interests involve fast pyrolysis of various biomass feedstocks like Arabidopsis, Imperata cylindrica, Pinus strobus, and Populus spp. He has participated in 6 research projects studying in situ iron catalyzed fast pyrolysis, char formation analysis, product variability from different feedstocks, heat transfer of pelleted biomass, biomass pretreatment via incipient wetting, and catalytic upgrading of pyrolysis vapors. He has co-authored several conference presentations and publications on characterization of biomass particles during pyrolysis and catalytic fast pyrolysis for fuel production. His related research interests include intraparticle transport during biomass processing and transgenic approaches to enhance biomass thermochemical pret
NREL RPP
- 1. Statement of Research Interests Cory D. Jensen 1 Research Program Participant Projects and Team Members 1. In situ Fe catalyzed Fast Pyrolysis of Arabidopsis spp. and Imperata cylindrica. Cory Jensen, Alex Stanton, Calvin Mukarakate, Bryon Donohoe 2. Char Formation-Image Analysis from a Laminar Entrained Flow Reactor David Robichaud, Mark Jarvis, Cory Jensen, Peter N. Ciesielski, Bryon Donohoe 3. Fast Pyrolysis Product Variability of Pinus strobus Cory Jensen, Bryon Donohoe, collaborating institution - North Carolina State 4. Heat Transfer Characteristics of Pelleted Pinus strobus Cory Jensen, Todd Vinzant, David Robichaud, Bryon Donohoe 5. Pretreatment of Populus spp. via Incipient Wetting Peter N. Ciesielski, Nathan Mosier, Cory Jensen, Bryon Donohoe 6. Fast catalytic upgrading of Pinus strobus with Albermarle UPV-2 and ZSM -5 Calvin Mukarakate, Cory Jensen, Bryon Donohoe Outcomes Cory D. Jensen, Peter N. Ciesielski, Kara Malhortra, David J. Robichaud, Bryon S. Donohoe, Mark R. Nimlos. Characterization of Biomass Particles and Geometry During Past Pyrolysis for Systems Models. February 21st, 2013. Conference on Earth and Energy Research. The BioFuels Frontier: Replacing Our Conventional Energy Sources. Robichaud, DJ, Mukarakate, C, Donohoe, BS, Ilsa, K, and Nimlos, MR. Catalytic Fast Pyrolysis for the production of hydrocarbon fuels. 245th ACS National Meeting New Orleans, LA. April 10th, 2013. (acknowledged) Related Research Jarvis, Mark W., et al. "Elucidation of biomass pyrolysis products using a laminar entrained flow reactor and char particle imaging." Energy & Fuels 25.1 (2010): 324-336. Viamajala, Sridhar, et al. "Heat and mass transport in processing of lignocellulosic biomass for fuels and chemicals." Sustainable biotechnology. Springer Netherlands, 2010. 1-18. Ciesielski, Peter N., et al. "Biomass Particle Models with Realistic Morphology and Resolved Microstructure for Simulations of Intraparticle Transport Phenomena." Energy & Fuels 29.1 (2014): 242-254. Research that Demonstrates Example of Potential Future Outcomes van der Lelie, Daniel, et al. "The metagenome of an anaerobic microbial community decomposing poplar wood chips." PloS one 7.5 (2012): e36740. Baldwin, Robert M., et al. "Current research on thermochemical conversion of biomass at the National Renewable Energy Laboratory." Applied Catalysis B: Environmental 115 (2012): 320-329. Mukarakate, Calvin, et al. "Real-time monitoring of the deactivation of HZSM-5 during upgrading of pine pyrolysis vapors." Green Chemistry 16.3 (2014): 1444-1461.
- 2. Statement of Research Interests Cory D. Jensen 2 Wei, Hui, et al. "Transgenic ferritin overproduction enhances thermochemical pretreatments in Arabidopsis." Biomass and Bioenergy 72 (2015): 55-64. McCann, Maureen, et al. "Tailoring Biomass for Biochemical, Chemical or Thermochemical Catalytic Conversion." The FASEB Journal 29.1 Supplement (2015): 485-3.