Combustion inhibition and enhancement of premixed methane–air flames by halon replacements JL Pagliaro, GT Linteris, PB Sunderland, PT Baker Combustion and Flame 162 (1), 41-49, 2015 | 122 | 2015 |
Premixed flame inhibition by C2HF3Cl2 and C2HF5 JL Pagliaro, GT Linteris, VI Babushok Combustion and Flame 163, 54-65, 2016 | 66 | 2016 |
Hydrocarbon flame inhibition by C6F12O (Novec 1230): Unstretched burning velocity measurements and predictions JL Pagliaro, GT Linteris Fire Safety Journal 87, 10-17, 2017 | 64 | 2017 |
Flammability and explosion characteristics of mildly flammable refrigerants SG Davis, JL Pagliaro, TF Debold, M Van Wingerden, K Van Wingerden Journal of Loss Prevention in the Process Industries 49, 662-674, 2017 | 56 | 2017 |
Effects of stretch and thermal radiation on difluoromethane/air burning velocity measurements in constant volume spherically expanding flames RR Burrell, JL Pagliaro, GT Linteris Proceedings of the Combustion Institute 37 (3), 4231-4238, 2019 | 41 | 2019 |
Premixed flame inhibition by CF3Br and C3H2F3Br (2-BTP) JL Pagliaro, N Bouvet, GT Linteris Combustion and Flame 169, 272-286, 2016 | 39 | 2016 |
Understanding overpressure in the FAA aerosol can test by C3H2F3Br (2-BTP) GT Linteris, VI Babushok, JL Pagliaro, DR Burgess Jr, JA Manion, ... Combustion and flame 167, 452-462, 2016 | 35 | 2016 |
Flame Inhibition by CF3CHCl2 (HCFC-123) VI Babushok, GT Linteris, OC Meier, JL Pagliaro Combustion Science and Technology 186 (6), 792-814, 2014 | 32 | 2014 |
Effects of stretch and radiation on the laminar burning velocity of R-32/air flames M Hegetschweiler, J Pagliaro, L Berger, R Hesse, J Beeckmann, H Pitsch, ... Science and Technology for the Built Environment 26 (5), 599-609, 2020 | 10 | 2020 |
Burning velocities of marginally flammable refrigerant-air mixtures JL Pagliaro, GT Linteris US Department of Commerce, National Institute of Standards and Technology, 2018 | 10 | 2018 |
Data reduction considerations for spherical R-32 (CH2F2)-air flame experiments MJ Hegetschweiler, JL Pagliaro, L Berger, R Hesse, J Beeckmann, ... Combustion and Flame 237, 111806, 2022 | 8 | 2022 |
Do not believe the hype: Using case studies and experimental evidence to show why the HSE is wrong about excluding deflagration‐to‐detonation transitions S Davis, J Pagliaro, D Botwinick, T DeBold, K van Wingerden, D Allason, ... Process Safety Progress 38 (2), e11998, 2019 | 8 | 2019 |
Burning velocity measurements and simulations for understanding the performance of fire suppressants in aircraft GT Linteris, JL Pagliaro National Institute of Standards and Technology, US Department of Commerce …, 2016 | 6 | 2016 |
Test Results Prepared for Honeywell: Igniter Material Effects in the Japanese High Pressure Gas Law Test G Linteris, G Linteris, J Pagliaro, P Sunderland US Department of Commerce, National Institute of Standards and Technology, 2016 | 5 | 2016 |
Overpressure in the FAA aerosol can test with halon replacements GT Linteris, JA Manion, W Tsang, DR Burgess Jr, V Babushok, VR Katta, ... The Seventh Triennial International Fire & Cabin Safety Research Conference, 2013 | 5 | 2013 |
Inhibition of laminar premixed flames by Halon 1301 alternatives JL Pagliaro University of Maryland, College Park, 2015 | 4 | 2015 |
Test results prepared for Honeywell: Flammability of refrigerants in the Japanese high pressure gas law test GT Linteris, JL Pagliaro, P Sunderland NISTIR 7178, 48, 2011 | 3 | 2011 |
Burning Velocity Measurements and Simulations for Understanding the Performance of Fire Suppressants in Aircraft-Letter Report Prepared for Meggitt GT Linteris, JL Pagliaro Gregory T. Linteris, John L. Pagliaro, 2016 | 2 | 2016 |
Measurements and Modeling of Spherical CH2F2-Air Flames MJ Hegetschweiler, MJ Hegetschweiler, JL Pagliaro, L Berger, R Hesse, ... US Department of Commerce, National Institute of Standards and Technology, 2020 | 1 | 2020 |
Comparison of simple and complex methods for determining refrigerant/air laminar burning velocities from the pressure rise in constant-volume experiments JL Pagliaro, SG Davis Science and Technology for the Built Environment 26 (5), 588-598, 2020 | 1 | 2020 |