2018 - Fellow of the Combustion Institute for excellent experiments in combustion across fundamental and applied areas, including autoignition, instabilities and turbulent flows
Simone Hochgreb is involved in relevant fields of research such as Laser and Amplitude in the field of Optics. Borrowing concepts from Incandescence, Simone Hochgreb weaves in ideas under Laser. Her research ties Optics and Amplitude together. Her study ties her expertise on Diesel fuel together with the subject of Organic chemistry. Her study connects Organic chemistry and Diesel fuel. Her Stratified flows research extends to the thematically linked field of Mechanics. Simone Hochgreb incorporates Stratified flows and Stratified flow in her research. Her study brings together the fields of Mechanics and Stratified flow. Combustion and Soot are two areas of study in which Simone Hochgreb engages in interdisciplinary work.
Her study looks at the relationship between Flow (mathematics) and topics such as Mechanics, which overlap with Turbulence and Laminar flow. Her Organic chemistry study overlaps with Environmental chemistry and Catalysis. As part of her studies on Environmental chemistry, Simone Hochgreb often connects relevant subjects like Analytical Chemistry (journal). Simone Hochgreb undertakes interdisciplinary study in the fields of Catalysis and Organic chemistry through her works. Her Thermodynamics study frequently links to other fields, such as Laminar flow and Turbulence. She combines topics linked to Physical chemistry with her work on Combustion. Physical chemistry and Combustion are commonly linked in her work. Combustor is frequently linked to Premixed flame in her study. Premixed flame is closely attributed to Combustor in her study.
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Rapid Compression Machines: Heat Transfer and Suppression of Corner Vortex
Daeyup Lee;Simone Hochgreb.
Combustion and Flame (1998)
An Overview of Hydrocarbon Emissions Mechanisms in Spark-Ignition Engines
Wai K. Cheng;Douglas Hamrin;John B. Heywood;Simone Hochgreb.
International Fuels & Lubricants Meeting & Exposition (1993)
Diesel Engine Combustion of Biomass Pyrolysis Oils
Alan Shihadeh;Simone Hochgreb.
Energy & Fuels (2000)
Plasma Reforming of Methane
Bromberg L;Cohn Dr;Rabinovich A;O'Brien C.
Energy & Fuels (1998)
Advances in rapid compression machine studies of low- and intermediate-temperature autoignition phenomena
S. Scott Goldsborough;Simone Hochgreb;Guillaume Vanhove;Margaret S. Wooldridge.
Progress in Energy and Combustion Science (2017)
The structure of turbulent stratified and premixed methane/air flames II: Swirling flows
Mark S. Sweeney;Simone Hochgreb;Matthew J. Dunn;Robert S. Barlow.
Combustion and Flame (2012)
Measurements of laminar flame speeds of liquid fuels: Jet-A1, diesel, palm methyl esters and blends using particle imaging velocimetry (PIV)
Cheng Tung Chong;Cheng Tung Chong;Simone Hochgreb.
Proceedings of the Combustion Institute (2011)
Effects of preferential transport in turbulent bluff-body-stabilized lean premixed CH4/air flames
Robert S. Barlow;Matthew John Dunn;Mark S. Sweeney;Simone Hochgreb.
Combustion and Flame (2012)
MECHANISMS OF PARTICULATE MATTER FORMATION IN SPARK-IGNITION ENGINES. 1: EFFECT OF ENGINE OPERATING CONDITIONS
David Kayes;Simone Hochgreb.
Environmental Science & Technology (1999)
Application of Raman/Rayleigh/LIF diagnostics in turbulent stratified flames
R.S. Barlow;G.-H. Wang;P. Anselmo-Filho;M.S. Sweeney.
Proceedings of the Combustion Institute (2009)
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