2026 David P. Schmidt: Engineering and Technology Researcher – H-Index, Publications & Awards

D-Index & Metrics

Discipline name	D-Index	World Ranking	Current World Ranking	National Ranking	Current National Ranking	Publications	Citations
Engineering and Technology	39	7659	7390	2107	1955	153	6585

Discipline name

D-Index

World Ranking

Current World Ranking

National Ranking

Current National Ranking

Publications

Citations

Engineering and Technology

7659

7390

2107

1955

153

6585

Engineering and Technology

D-Index

Citations

6585

World Ranking

7659

National Ranking

2107

Overview

David P. Schmidt is a researcher affiliated with the University of Massachusetts Amherst in the United States. Their primary field of study is Engineering, with a focus on Computational Mechanics, Aerospace Engineering, Fluid Flow and Transfer Processes, Statistical and Nonlinear Physics, and Ocean Engineering.

Their research covers a range of topics including:

Combustion and flame dynamics
Advanced Combustion Engine Technologies
Model Reduction and Neural Networks
Wind Energy Research and Development
Fluid Dynamics and Heat Transfer
Fluid Dynamics and Vibration Analysis
Fluid Dynamics and Turbulent Flows

Recent publications by David P. Schmidt showcase contributions in various areas related to wind energy and fluid dynamics. Notable papers include:

"Floating platform effects on power generation in spar and semisubmersible wind turbines," 2021, Wind Energy
"Collaborative investigation of the internal flow and near-nozzle flow of an eight-hole gasoline injector (Engine Combustion Network Spray G)," 2020, International Journal of Engine Research
"CFD Simulations of Feeder Tube Pressure Oscillations and Prediction of Clogging in Cold Spray Nozzles," 2020, Journal of Thermal Spray Technology
"Large eddy simulations of offshore wind turbine wakes for two floating platform types," 2020, Journal of Physics Conference Series
"Machine learning accelerated turbulence modeling of transient flashing jets," 2021, Physics of Fluids

Frequent coauthors include Majid Haghshenas, Niccolò Dal Santo, Peetak Mitra, and Hannah M. Johlas, with collaboration counts ranging from four to nine publications.

Their work has been published repeatedly in venues such as:

arXiv (Cornell University)
Physics of Fluids
Wind Energy
International Journal of Engine Research
Energies

David P. Schmidt has also contributed to book publications, with at least one book published by Columbia University Press titled "The Long Year," released in 2022.

Best Publications

A new droplet collision algorithm

David P. Schmidt;C. J. Rutland

1074
Citations
Modeling high-speed viscous liquid sheet atomization

P.K Senecal;D.P Schmidt;I Nouar;C.J Rutland

612
Citations
Pressure-Swirl Atomization in the Near Field

David P. Schmidt;Idriss Nouar;P. K. Senecal;C. J. Rutland

314
Citations
The internal flow of diesel fuel injector nozzles: A review:

D. P. Schmidt;M. L. Corradini

264
Citations
A FULLY COMPRESSIBLE, TWO-DIMENSIONAL MODEL OF SMALL, HIGH-SPEED, CAVITATING NOZZLES

David P. Schmidt;Christopher J. Rutland;Michael L. Corradini

239
Citations
A Numerical Study of Cavitating Flow Through Various Nozzle Shapes

David P. Schmidt;Christopher J. Rutland;M. L. Corradini

196
Citations
Multi-dimensional simulation of thermal non-equilibrium channel flow

D.P. Schmidt;S. Gopalakrishnan;Hrvoje Jasak

174
Citations
Aerosol generation by reactive boiling ejection of molten cellulose

Andrew R. Teixeira;Kyle G. Mooney;Jacob S. Kruger;C. Luke Williams

166
Citations
A moving mesh interface tracking method for 3D incompressible two-phase flows

Shaoping Quan;David P. Schmidt

138
Citations
Cavitation in Two-Dimensional Asymmetric Nozzles

David P. Schmidt;C. J. Rutland;M. L. Corradini;P. Roosen

130
Citations
Multidimensional Modeling of Condensing Two-Phase Ejector Flow

Michael Colarossi;Nathaniel Trask;David P. Schmidt;Mark J. Bergander

116
Citations
An Eulerian CFD model and X-ray radiography for coupled nozzle flow and spray in internal combustion engines

Q. Xue;M. Battistoni;C.F. Powell;D.E. Longman

109
Citations
Accuracy and conservation properties of a three-dimensional unstructured staggered mesh scheme for fluid dynamics

Xing Zhang;David Schmidt;Blair Perot

107
Citations
ANALYTICAL PREDICTION OF THE EXIT FLOW OF CAVITATING ORIFICES

David P. Schmidt;Michael L. Corradini

99
Citations
Adaptive tetrahedral meshing in free-surface flow

Meizhong Dai;David P. Schmidt

98
Citations
Internal and near nozzle measurements of Engine Combustion Network “Spray G” gasoline direct injectors

Daniel J. Duke;Daniel J. Duke;Alan L. Kastengren;Katarzyna E. Matusik;Andrew B. Swantek

97
Citations
Internal and Near-Nozzle Flow in a Multi-Hole Gasoline Injector Under Flashing and Non-Flashing Conditions

Maryam Moulai;Ronald Grover;Scott Parrish;David Schmidt

97
Citations
String flash-boiling in gasoline direct injection simulations with transient needle motion

E.T. Baldwin;R.O. Grover;S.E. Parrish;D.J. Duke

95
Citations
X-ray Imaging of Cavitation in Diesel Injectors

Daniel Duke;Andrew Swantek;Zak Tilocco;Alan Kastengren

94
Citations
Modeling merging and breakup in the moving mesh interface tracking method for multiphase flow simulations

Shaoping Quan;Jing Lou;David P. Schmidt

91
Citations