Jifeng Peng

jifeng peng
Professor and Chair
Mechanical Engineering
ECB 301H
907-786-6193
jpeng@alaska.edu

Education

Ph.D. Bioengineering (specialty: fluid mechanics) California Institute of Technology, Pasadena, CA 2009
M.S.Mechanical Engineering, Stony Brook University, Stony Brook, NY 2004
B.S. Mechanical Engineering, University of Science & Technology of China, China, 2002

Teaching Responsibilities

ES A261 Introduction to Engineering Computation
ES A208 Engineering Statics and Dynamics
ES A346 Introduction to Thermodynamics
ME A435 Renewable Energy System Engineering
ME A438 Design of Mechanical Engineering Systems
ME A442/642 Advanced Fluid Mechanics
ME A451/651 Aerodynamics 

Professional & Department Service

Reviewer for journals including: Atmospheric Environment, Bioinspiration & Biomimetics, Chaos, Experiments in Fluids, International Journal of Heat and Fluid Flow, International Journal of Non-linear Mechanics, Journal of Experimental Biology, Journal of Fluid Mechanics, Journal of the Japanese Society for Experimental Mechanics, Journal of Physics: Condensed Matter, Marine Technology Society Journal, Physica D: Nonlinear Phenomena, Physics of Fluid, Theoretical and Computational Fluid Dynamics

Research Interests

Computational fluid dynamics (CFD), propulsion, wind and hydro energy, micro-grid, environmental transports, pipeline flows, multiphase flow in porous media, vortex dynamics, marine structures, fluid-structure interactions, oil spills. 

Funded Research Projects (a total of $2,221,181 research grants awarded as PI and Co-PI鈥檚 portion): 

  1. PI, 鈥楢rctic ice condition index鈥, Department of Homeland Security, $195,000, 2019-2020.
  2. PI, 鈥楢 combustion and dispersion model of particulate matter from in situ oil burning,鈥 ConocoPhillips, $27,591, 2018-2019.
  3. Co-PI, 鈥楢rctic oil spill model鈥, Department of Homeland Security, Co-PI portion, $100,000, (grant total: $200,000, PI: Texas A&M University), 2018-2019.
  4. Co-PI, 鈥榃ind farm in Igiugig Alaska: integration of wind farm into microgrid,鈥 Gordon and Betty Moore Foundation, Co-PI portion: $1,317,058 (grant total: $1,759,700, PI: Stanford University), 2016-2020.
  5. Co-PI, 鈥榁illage grid integration strategy,鈥 Alaska Energy Authority, Co-PI portion: $103,750 (grant total: $421,500, PI: ORPC), 2017-2018. 
  6. PI, 鈥榁ortex induced vibration in marine pipelines with application to AKLNG,鈥 ConocoPhillips, $71,299, 2016-2017.
  7. Co-PI, 鈥楢rctic coastal erosion forecasting,鈥 ConocoPhillips, Co-PI portion: $16,331 (grant total: $141,511), 2016 ~2017.
  8. Co-PI, 鈥榃ind farm in Igiugig Alaska: demonstration of vertical-axis wind turbines,鈥 Gordon and Betty Moore Foundation, Co-PI portion: $121,686 (grant total: $679,997, PI: Stanford University), 2013-2016.
  9. PI, 鈥楤RIGE: Optimal formation of consecutive vortex rings for propulsion systems,鈥 National Science Foundation CBET-1228121, $174,957, 2012-2015.
  10. PI, 鈥楩easibility study of vertical-axis wind turbine farm in rural communities in Alaska鈥檚 wild salmon systems,鈥 Gordon and Betty Moore Foundation, $47,991, 2012-2013.
  11. PI, 鈥極cean plankton distribution patterns in the Alaska region from a coupled population dynamics-physical mixing model,鈥 Alaska EPSCoR, $19,950, 2012.
  12. PI, 鈥楢 novel method to predict hazard zones of airborne volcanic ash from eruptions,鈥 Alaska Space Grant Program, $25,568, 2011-2012.

Publications

Selected Publications:

  1. Peng J. (2018) 鈥淓ffects of aerodynamic interactions of closely-placed vertical axis wind turbine pairs,鈥 Energies, 11:2842.
  2. Cenek M, Haro R, Sayers B, Peng J. (2018) 鈥淧ower load prediction for rural electrical microgrids using long short term memory and artificial neural networks,鈥 Applied Science, 8:749.
  3. Peng J, (2015) 鈥淪imulation of vortex ring formation and the effect of piston velocity program on the formation number,鈥 Journal of Vortex Science and Technology,2:120.
  4. Dabiri J, GreerJ, Koseff J, Moin P, Peng J, (2015) 鈥淎 New Approach To Wind Energy,鈥 AIP Proceeding: Physics of Sustainable Energy, 1652:51.
  5. Peng J, Webley P, (2015) 鈥淎ttracting Structures in Volcanic Ash Transport and the Correlation to Environmental Hazard Zones鈥, book chapter in 鈥淰olcanic Ash,鈥 Nova Science Publishers.
  6. Alben S, Miller LA, Peng J (2013) 鈥淓fficient kinematics for jet-propelled swimming,鈥 Journal of Fluid Mechanics, 733:100-133.
  7. Satti JR, Peng J (2013) 鈥淟eapfrogging of two thick-cored vortex rings,鈥 Fluid Dynamics Research, 45: 035503.
  8. Chen G, Peng J (2012) 鈥淎n Experimental Investigation of Mode Shift of Cantilever Flexible Plate Coupled with Fluid,鈥 Nonlinear Engineering, 1:59-66.
  9. Peng J, Chen G (2012) 鈥淔low-Oscillating Structure Interactions and the Applications to Propulsion and Energy Harvest,鈥 Applied Physics Research, 4: 1-14.
  10. Peng J, Alben S (2012) 鈥淓ffects of shape and stroke parameters on the performance of an axisymmetric swimmer,鈥 Bioinspiration & Biomimetics, 7: 016012.
  11. Peng J, Peterson R (2012) 鈥淎ttracting structures in volcanic ash transport,鈥 Atmospheric Environment, 48: 230-239.
  12. Sapsis T, Peng J, Haller H (2011) 鈥淚nstabilities on prey dynamics in jellyfish feeding,鈥 Bulletin of Mathematical Biology 73: 1841-1856.
  13. Peng J, Dabiri JO (2009) 鈥淭ransport of inertial particles by Lagrangian Coherent Structures: application to predator-prey interaction in jellyfish feeding,鈥 Journal of Fluid Mechanics 623: 75-84.
  14. Wilson M, Peng J, Dabiri JO, Eldredge JD (2009) 鈥淟agrangian coherent structures in low Reynolds number swimming,鈥 Journal of Physics: Condensed Matter 21: 204105.
  15. Peng J, Dabiri JO (2008) 鈥淭he 'upstream wake' of swimming and flying animals and its correlation with propulsive efficiency,鈥 Journal of Experimental Biology 211: 2669-2677.
  16. Peng J, Dabiri JO (2008) 鈥淎n overview of a Lagrangian method for analysis of animal wake dynamics,鈥 Journal of Experimental Biology 211: 280-287.
  17. Franco E, Pekarek DN, Peng J, Dabiri JO (2007) 鈥淕eometry of unsteady fluid transport during fluid-structure interactions,鈥 Journal of Fluid Mechanics 589: 125-145.
  18. Peng J, Dabiri JO (2007) 鈥淎 potential-flow, deformable-body model for fluid-structure interactions with compact vorticity: application to animal swimming measurements,鈥 Experiments in Fluids 43: 655-664.
  19. Peng J, Dabiri JO, Madden PG, Lauder GV (2007) 鈥淣on-invasive measurement of instantaneous forces during aquatic locomotion: A case study of the bluegill sunfish pectoral fin,鈥 Journal of Experimental Biology 210: 685-698.

Career History/Work Experience

Professor of Mechanical Engineering, University of Alaska (2020 - present)
Associate Professor of Mechanical Engineering, University of Alaska (2016 - 2020)
Assistant Professor of Mechanical Engineering, University of Alaska (2009 - 2016)