Abstract: Methods of natural gas production and carbon sequestration are provided. The method includes delivering a feedstock downhole to a coal reservoir, generating biogas within the coal reservoir, and harvesting the biogas. Another method for tracing the migration of biogas in a coal reservoir includes delivering a feedstock downhole to a coal reservoir, generating biogas that is isotopically differentiable from a background gas within the coal reservoir through microbial action, harvesting the biogas, analyzing the biogas from the coal reservoir at the injection well and at one or more offset wells within the same coal reservoir, detecting the biogas at the offset wells using isotopic differentiation, and mapping the migration of the biogas from the injection well to the offset wells using the biogas as an isotopic tracer.

Abstract: Embodiments of the present disclosure relate to methods of natural gas production and carbon sequestration. In one embodiment, a method of generating biogas is disclosed, comprising delivering a feedstock downhole to a coal reservoir, generating biogas within the coal reservoir, and harvesting the biogas. In another embodiment, a method for tracing the migration of biogas in a coal reservoir is disclosed.

Abstract: Use of chemical pretreatment agents on the subsequent enzymatic conversion of coal is described. As an example, fungal manganese peroxidase (MnP) produced by the agaric white-rot fungus Bjerkandera adusta, where the enzyme MnP has little effect on the untreated coal controls, was investigated. The nature of pretreatment agents and their applied concentrations were found to have significant impact on subsequent enzymatic conversion of coal. Four agents were investigated: HNO3, catalyzed H2O2, KMnO4, and NaOH. Hydrogen peroxide was found to generate the greatest quantity of total organic carbon from the coal samples employed. Combined chemical and enzymatic treatment of coal is appropriate for enhanced depolymerisation of coal and coal-derived constituents and results in chemically heterogeneous and complex liquefaction products like humic and fulvic acids, which will have important ramifications in the generation of liquid and gaseous fuels from coals as nonpetroleum-derived fuel alternatives.

Abstract: The use of coal fields as subsurface bioreactors for producing sustainable methane gas from terrestrial sources of biomass is described. Microbial presence is determined for a target coal formation, and tracers are injected to determine permeability, porosity, volume, and minimum and a maximum material injection rates. At least one injection well and at least one circulation well effective for generating an injection rate between the minimum and maximum injection rates are provided for injecting a solution of biodegradable materials into the coal seam. A chosen quantity of biodegradable materials is allowed to be digested, fermented and converted by microbial action within the coal seam. Methane gas is extracted through producing and injecting wells, although pumping will enhance gas recovery.

Abstract: Use of chemical pretreatment agents on the subsequent enzymatic conversion of coal is described. As an example, fungal manganese peroxidase (MnP) produced by the agaric white-rot fungus Bjerkandera adusta, where the enzyme MnP has little effect on the untreated coal controls, was investigated. The nature of pretreatment agents and their applied concentrations were found to have significant impact on subsequent enzymatic conversion of coal. Four agents were investigated: HNO3, catalyzed H2O2, KMnO4, and NaOH. Hydrogen peroxide was found to generate the greatest quantity of total organic carbon from the coal samples employed. Combined chemical and enzymatic treatment of coal is appropriate for enhanced depolymerisation of coal and coal-derived constituents and results in chemically heterogeneous and complex liquefaction products like humic and fulvic acids, which will have important ramifications in the generation of liquid and gaseous fuels from coals as nonpetroleum-derived fuel alternatives.

Abstract: The use of coal fields as subsurface bioreactors for producing sustainable methane gas from terrestrial sources of biomass is described. Microbial presence is determined for a target coal formation, and tracers are injected to determine permeability, porosity, volume, and minimum and a maximum material injection rates. At least one injection well and at least one circulation well effective for generating an injection rate between the minimum and maximum injection rates are provided for injecting a solution of biodegradable materials into the coal seam. A chosen quantity of biodegradable materials is allowed to be digested, fermented and converted by microbial action within the coal seam. Methane gas is extracted through producing and injecting wells, although pumping will enhance gas recovery.

Abstract: A method for converting coal to biogenic methane is provided. The method comprises providing a solid coal matrix, converting the solid coal matrix into soluble, coal-derived constituents, introducing indigenous microorganisms and nutrients into the soluble, coal-derived constituents, and biologically converting the soluble, coal-derived constituents into methane.