|
| Name: |
Professor A Gavriilidis |
| Organisation: |
UCL |
| Department: |
Chemical Engineering |
| Current EPSRC-Supported Research
Topics: |
|
Biomaterials
|
Bioprocess Engineering
|
|
Catalysis & Applied Catalysis
|
Design & Testing Technology
|
|
Manufacturing Machine & Plant
|
Materials Synthesis & Growth
|
|
Reactor Engineering
|
|
|
| Current EPSRC Support |
| EP/X024016/1 | DEVELOPMENT OF A MACHINE LEARNING-ASSISTED DIGITAL TWIN PLATFORM FOR REAL-TIME OPTIMISATION OF REACTION SYSTEMS UNDER UNCERTAINTY | (C) |
| EP/W019132/1 | NOVEL SUSTAINABLE MANUFACTURING TECHNOLOGIES FOR EFFICIENT UTILISATION OF AGRICULTURAL WASTE STREAMS IN A CIRCULAR ECONOMY | (C) |
| EP/V050796/1 | Fully Automated Platforms for Drug Nanocrystals Manufacturing via Continuous-Flow, Data-Driven Antisolvent Crystallization | (C) |
| EP/R026815/1 | The UK Catalysis Hub - 'Science': 1 - Optimising, predicting and designing new Catalysts | (C) |
|
| Previous EPSRC Support |
| EP/S03305X/1 | Frontier Engineering: Progression Grant in Nature-Inspired Engineering | (C) |
| EP/M018016/1 | MAGNETIC NANOPARTICLE ENGINEERING via MICROREACTION TECHNOLOGY | (P) |
| EP/M015157/1 | ADVANCED FLOW TECHNOLOGY FOR HEALTHCARE MATERIALS MANUFACTURING | (P) |
| EP/L027232/1 | Fluid processes in smart microengineered devices: Hydrodynamics and thermodynamics in microspace | (P) |
| EP/K035061/1 | Process Intensification Using an Advanced Flow Reactor | (P) |
| EP/K038656/1 | Centre for Nature Inspired Engineering (CNIE): Addressing Challenges in Sustainability and Scalable Manufacturing | (C) |
| EP/L003279/1 | Sustainable Manufacturing in Multiphase Continuous Reactors: Aerobic Oxidations | (P) |
| EP/K014714/1 | The UK Catalysis Hub | (C) |
| EP/K014854/1 | The UK Catalysis Hub | (C) |
| EP/J017833/1 | CATALYTIC TRANSFORMATION OF BIO-DERIVED PLATFORM MOLECULES | (P) |
| EP/I031480/1 | SONOCRYSTALLISATION IN CONTINUOUS FLOW MICROCHANNEL CONTACTORS | (P) |
| EP/G032122/1 | Luminescent nanoparticles as trackers for imaging of flows and sensing phenomena in microchannels | (C) |
| EP/G027447/1 | Challenging Ozonolysis | (P) |
| EP/G008442/1 | DEVELOPMENT OF HIGHLY ACTIVE AND SELECTIVE GOLD PALLADIUM ALLOY CATALYSTS AIDED BY MICROREACTION TECHNOLOGY | (P) |
| GR/S40589/01 | Microengineered Laboratory Catalytic Reactors | (P) |
| GR/S08596/01 | Engineering the Laboratory of the Synthetic Chemist | (C) |
| GR/R08834/01 | From Micrograms To Multikilos | (P) |
| GR/R08896/01 | From Micrograms To Multikilos | (C) |
| GR/R05628/01 | Laboratory For Characterisation of Porous Solid Catalysts | (C) |
| GR/N16525/01 | FROM MICROGRAMS TO MULTIKILOS | (C) |
| GR/M71794/01 | NON-EQUILIBRIUM CATALYTIC REACTOR CONFIGURATIONS FOR THE CLEAN SYNTHESIS OF FINE CHEMICALS | (P) |
| GR/M10311/01 | MICROFABRICATED CATALYTIC REACTORS IN FINE CHEMICALS PRODUCTION | (P) |
| GR/L57630/01 | ENHANCED HEAT TRANSFER TO ENDOTHERMIC REACTIONS BY CATALYTIC COMBUSTION IN SMALL CHANNELS | (C) |
| GR/K84622/01 | CATALYTIC COMBUSTION WITHOUT REACTANT PREMIXING | (P) |
| GR/K97936/01 | THERMOGRAVIMETRIC EXPERIMENTAL STATION FOR CATALYTIC STUDIES | (P) |
|
|
Key: (P)=Principal Investigator, (C)=Co-Investigator, (R)=Researcher Co-Investigator
|
| |
|
|
|
|