His primary areas of investigation include Mineralogy, Streaming current, Electrokinetic phenomena, Salinity and Petrology. In his study, Mechanics, Permeability, Relative permeability and Chondrite is strongly linked to Porosity, which falls under the umbrella field of Mineralogy. His Streaming current research is multidisciplinary, relying on both Ionic strength and Electrical resistivity and conductivity.
His Electrokinetic phenomena research integrates issues from Saturation, Soil science and Brine. His biological study spans a wide range of topics, including Sedimentary rock, Outcrop and Magma chamber. His Porous medium study deals with Network model intersecting with Geotechnical engineering and Multiphase flow.
Matthew D. Jackson spends much of his time researching Mechanics, Porous medium, Petrology, Streaming current and Mineralogy. Matthew D. Jackson has researched Mechanics in several fields, including Saturation, Geotechnical engineering and Capillary pressure. His studies deal with areas such as Capillary action and Relative permeability as well as Capillary pressure.
Matthew D. Jackson focuses mostly in the field of Porous medium, narrowing it down to matters related to Flow and, in some cases, Control volume finite element method. The study incorporates disciplines such as Salinity, Electrical resistivity and conductivity and Petroleum engineering in addition to Streaming current. His work carried out in the field of Mineralogy brings together such families of science as Surface charge and Brine.
Mechanics, Polygon mesh, Salinity, Multiphase flow and Hydrogeology are his primary areas of study. His Mechanics research includes themes of Viscous fingering, Porous medium, Capillary pressure, Saturation and Numerical analysis. His work is dedicated to discovering how Capillary pressure, Instability are connected with Petrology and other disciplines.
His studies in Petrology integrate themes in fields like Grid cell and Permeability. His Salinity research is multidisciplinary, incorporating elements of Soil science, Aquifer and Diffusion. His Hydrogeology research integrates issues from Fluid dynamics, Grid, Petrophysics and Computational science.
The scientist’s investigation covers issues in Petrology, Hydrogeology, Grid, Instability and Mechanics. His Petrology study integrates concerns from other disciplines, such as Blackhawk Formation, Permeability and Crust. His Hydrogeology study combines topics from a wide range of disciplines, such as Level of detail, Geometry, Surface and Bounding overwatch.
Matthew D. Jackson has included themes like Volcano, Magma chamber, Magma, Geodynamics and Numerical analysis in his Instability study. Matthew D. Jackson interconnects Viscous fingering, Porous medium, Capillary pressure and Truncation error in the investigation of issues within Mechanics. The concepts of his Truncation error study are interwoven with issues in Polygon mesh and Flow.
This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.
Detailed physics, predictive capabilities and macroscopic consequences for pore-network models of multiphase flow.
Martin J. Blunt;Matthew D. Jackson;Mohammad Piri;Per H. Valvatne.
Advances in Water Resources (2002)
Zeta potential of artificial and natural calcite in aqueous solution.
Dawoud Al Mahrouqi;Dawoud Al Mahrouqi;Jan Vinogradov;Matthew D. Jackson.
Advances in Colloid and Interface Science (2017)
Zeta potential in oil-water-carbonate systems and its impact on oil recovery during controlled salinity water-flooding
Matthew D. Jackson;Dawoud Al-Mahrouqi;Dawoud Al-Mahrouqi;Jan Vinogradov;Jan Vinogradov.
Scientific Reports (2016)
Measurement of streaming potential coupling coefficient in sandstones saturated with natural and artificial brines at high salinity
J. Vinogradov;M. Z. Jaafar;M. Z. Jaafar;M. D. Jackson.
Journal of Geophysical Research (2010)
Evidence, mechanisms and improved understanding of controlled salinity waterflooding part 1: Sandstones ☆
M. D. Jackson;Jan Vinogradov;Jan Vinogradov;G Hamon;M Chamerois.
Zeta potential of intact natural limestone: Impact of potential-determining ions Ca, Mg and SO4
A. Alroudhan;A. Alroudhan;J. Vinogradov;J. Vinogradov;M.D. Jackson.
Colloids and Surfaces A: Physicochemical and Engineering Aspects (2016)
Melt Segregation in Deep Crustal Hot Zones: a Mechanism for Chemical Differentiation, Crustal Assimilation and the Formation of Evolved Magmas
J.L.S. Solano;M.D. Jackson;R S J Sparks;Jon D Blundy.
Journal of Petrology (2012)
Measurement of streaming potential coupling coefficient in sandstones saturated with high salinity NaCl brine
M. Z. Jaafar;M. Z. Jaafar;Jan Vinogradov;M. D. Jackson.
Geophysical Research Letters (2009)
Three-dimensional modeling of a shoreface-shelf parasequence reservoir analog: Part 1. Surface-based modeling to capture high-resolution facies architecture
Richard P. Sech;Matthew D. Jackson;Gary J. Hampson.
AAPG Bulletin (2009)
Three-dimensional reservoir characterization and flow simulation of heterolithic tidal sandstones
Matthew D. Jackson;Shuji Yoshida;Ann H. Muggeridge;Howard D. Johnson.
AAPG Bulletin (2005)
If you think any of the details on this page are incorrect, let us know.
We appreciate your kind effort to assist us to improve this page, it would be helpful providing us with as much detail as possible in the text box below: