Development of Unconventional Reservoirs 2020 

<br/><br/><br/>English[eng] 
<br/><br/><label>ISBN: </label>9783040000000 
<br/><br/><label>Subjects--Topical Terms: </label><br/>bedding fractures||failure criterion||lamina||tight oil||tight sandstone||finite element simulation||numerical simulation||unconventional reservoir||permeability||group method of data handling||artificial neural network||well logs||sensitivity analysis||tight gas reservoir||multi-fractured horizontal well (MFHW)||unstable productivity model||productivity forecast||influencing factor analysis||horizontal well with multiple finite-conductivity fractures||elliptical-shaped drainage||productivity index||non-Darcy flow||pressure-dependent conductivity||reservoir properties||void space structure||porosity||complex rocks||NMR||MICP||CT||SEM||coal-bearing tight sandstone||organic-rich clasts||occurrence||classifications||formation mechanisms||Ordos Basin||hydraulic fracturing||fracturing fluids||fluids-rock interaction||environmental implication||history matching||semianalytic model||unconventional gas reservoirs||multistage fractured horizontal wells||fractal theory||pore structure||heterogeneity||NMR measurements||multifractal analysis||shale reservoir||elastic properties||brittleness||rock physics||brittle spot identification||shale gas||reservoir characteristics||gas content||eastern Sichuan Basin||the Da’anzhai member||pulse decay method||gas adsorption||dual media||unconventional core||natural fracture||influencing factor||oil production||carbonate rock||basement reservoir||Jizhong Sub-basin||dynamic pore network modeling||shale reservoirs||water imbibition||discrete element method||modified fluid-mechanical coupling algorithm||injection sequence||well spacing||stress shadow effect||seismic location||microseismic events||waveform stacking||induced seismicity||CBM||surfactant||solid-free drilling fluid||CBM reservoir wettability||machine learning||lithofacies||umiat||Alaska||proppant transportation||cross fractures||CFD simulation||dimensional analysis||equilibrium proppant height||coalbed methane||Lattice Boltzmann method||gas diffusion||adsorption–desorption||pore-scale||clay minerals||pore structures||tight gas reservoirs||Xujiaweizi Rift||Northern Songliao Basin||methane adsorption isotherm||coal properties||gradient boosting decision tree||estimation model||shale gas reservoir||geology||Gibbs excess adsorption||supercritical adsorption||gas viscosity||high voltage spark discharge||electrohydraulic effect||electrical conductivity||drilling||rock damage||pressure waves||water fracturing||turbulence effect||Eulerian multiphase modeling||proppant transport mechanism||equilibrium height prediction model||adaptive filtering||complex noise canceling||electromagnetic telemetry||multifractured horizontal wells||production analysis||irregular stimulated region||natural gas hydrate||seismic modeling||fractional derivatives||gas geochemical characteristics||noble gas||shale gas evolution||Large Igneous Province (LIP)||gas loss||geological structure||gas controlling pattern||neutral surface||tectonic movement||Bumu region||seismic interpretation||depositional environments characteristics||Wheeler diagram||seismic attributes||heterogeneous sequence||sample size||neutron scattering||mercury injection capillary pressure||adsorption||shale||junggar basin||hong-che fault zone||carboniferous||volcanic reservoir||main controlling factors of hydrocarbon accumulation||fracture||vug||micro CT||carbonate||wave velocity||amorphous SiO2||X-ray diffraction||X-ray fluorescence spectrometry||scanning electron microscope||quantitative analysis||void ratio||FEM||ABAQUS||matrix porosity||kerogen porosity||water saturation||gas hydrate||saturation||deep learning||recurrent neural network||molecular simulation||enhanced oil recovery||methane||shale petroleum||technological development||patent||network analysis||imbibition||osmosis||unconventional formations||EOR||water flooding