Research Fellow, Heriot-Watt University
Dr Hannah Menke's research focusses on using reservoir condition multi-scale experiments, numerical modelling, and machine learning to upscale pore-scale processes for CO2 storage, hydrogen, and geothermal reservoirs. Hannah received a PhD from Imperial College in Earth Science and Engineering from Imperial College London in 2016, a master's from the Colorado School of Mines in 2012, and a BS from Columbia University in 2008. Since 2018 she has been a Research Fellow (equivalent to Assistant Professor Research) at the Institute for GeoEnergy Engineering Heriot-Watt University in Edinburgh, UK where she leads the development of new experimental and AI upscaling techniques and is co-founder of The GeoChemFoam Project with Dr. Maes, the world's most advanced Open Source CFD solver package for the energy transition.
Email: h.menke@hw.ac.ukwww.researchgate.net/profile/Hannah_Menkehttp://github.com/GeoChemFoam
May 30
The permeability of a pore structure is typically described by stochastic representations of its geometrical attributes (e.g. pore-size distribution, porosity, coordination number). Database-driven numerical solvers for large model domains can only accurately predict large-scale flow and reactive behaviour when they incorporate upscaled descriptions of that structure and its evolution. This is particularly challenging for rocks with multimodal porosity structures such as carbonates, where several different type of structures (e.g. micro-porosity, cavities, fractures) are interacting. It is the connectivity both within and between these fundamentally different structures that ultimately controls the porosity-permeability relationship at the larger length scales. Recent advances in machine learning techniques combined with both numerical modelling and informed structural analysis have allowed us to probe the relationship between structure, reaction, and permeability much more deeply. We have used this integrated approach to tackle the challenge of upscaling flow and reaction in rocks with complex pore structures with a combination of advanced pore-scale modelling and machine learning.
