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Biogeochemical aspects of aquifer thermal energy storage
H.J. Brons
Microbiology
Research output
:
Thesis
›
external PhD, WU
Overview
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Dive into the research topics of 'Biogeochemical aspects of aquifer thermal energy storage'. Together they form a unique fingerprint.
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Engineering
Active Cell
20%
Air Saturation
20%
Aquifer Thermal Energy Storage
100%
Biomass Concentration
40%
Carbon Concentration
40%
Chemical Oxygen Demand
20%
Chemical Reduction
20%
Chemical Reduction Reaction
20%
Chemostat
60%
Chemostat Culture
20%
Coarse Sand
20%
Column Experiment
20%
Combined Action
40%
Continuous Culture
20%
Dissolved Organic Carbon
60%
Dissolved Oxygen Concentration
20%
Electron Acceptor
20%
Elevated Temperature
20%
Enzymatic Activity
40%
Heat Storage
40%
High Growth Rate
20%
Hollow-Fiber Membrane
20%
Inhibition
20%
Low Growth Rate
20%
Mols
40%
Nitrate Reductase
40%
Organic Material
40%
Reducing Bacteria
20%
Reductants
20%
Silicon Dioxide
20%
Substantial Increase
20%
Supersaturation
20%
Temperature Range
20%
Temperature Rise
20%
Test Facility
20%
Biochemistry, Genetics and Molecular Biology
Bacterial Growth
14%
Calcite
14%
Chemical Oxygen Demand
14%
Complex Formation
14%
Continuous Culture
14%
Dolomite
14%
Electron Paramagnetic Resonance Spectroscopy
14%
Electron Transport Chain
14%
Enzyme Activity
28%
Escherichia coli
100%
Hollow Fiber Membrane
14%
Nitrate Reductase
71%
Nitric Oxide
57%
Nitrite Reductase
71%
Nitrous Oxide
28%
Oxidoreductase
14%
Oxygen Concentration
14%
Plate Count
14%
Reductase
14%
Steady State
14%
Sulfate
14%
Sulfate Reducing Bacterium
14%
Chemical Engineering
Ammonia
40%
Calcite
20%
Carbon Dioxide
40%
Chemical Oxygen Demand
20%
Chemostat
80%
Dissolved Oxygen
20%
Effluent
40%
Hollow Fiber Membrane
20%
Nitrate Reductase
40%
Nitric Oxide
80%
Organic Carbon
100%
Earth and Planetary Sciences
Ammonia
16%
Calcite
8%
Carbon Compounds
8%
Carbon Dioxide
16%
Chemostat
33%
Complexation
8%
Dissolved Organic Carbon
25%
Dissolved Oxygen
8%
Dolomite
8%
Effluent
16%
Electron Paramagnetic Resonance
8%
Enzyme Activity
16%
Fulvic Acid
16%
Heat Storage
100%
Nitric Oxide
33%
Nitrite
100%
Nitrous Oxide
16%
Organic Carbon
16%
Organic Material
16%
Oxic Condition
8%
Plate Count
8%
Test Facility
8%
Immunology and Microbiology
Bacterial Growth
14%
Chemical Oxygen Demand
14%
Chemostat
57%
Complex Formation
14%
Continuous Culture
14%
Electron Paramagnetic Resonance Spectroscopy
14%
Enzyme Activity
28%
Escherichia coli
100%
Hollow Fiber Membrane
14%
Oxygen Concentration
14%
Plate Count
14%
Respiratory Chain
14%
Steady State
14%
Sulfate Reducing Bacterium
14%