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DC Field | Value | Language |
---|---|---|
dc.contributor.author | Feofanov, Alexey | |
dc.date.accessioned | 2022-05-02T08:28:16Z | - |
dc.date.available | 2022-05-02T08:28:16Z | - |
dc.date.issued | 2011 | |
dc.identifier.isbn | 9783866446441 | |
dc.identifier.uri | http://localhost:8080/xmlui/handle/123456789/146457 | - |
dc.language.iso | eng | |
dc.publisher | KIT Scientific Publishing | |
dc.relation.isbasedon | 10.5445/KSP/1000022237 | |
dc.relation.uri | https://www.ksp.kit.edu/9783866446441 | |
dc.rights.uri | CC BY-NC-ND (姓名標示-非商業性-禁止改作) | |
dc.source | DOAB | |
dc.subject.classification | Physics | |
dc.subject.other | fracturing fluid | |
dc.subject.other | rheology | |
dc.subject.other | chelating agent | |
dc.subject.other | viscosity | |
dc.subject.other | polymer | |
dc.subject.other | fluid-solid interaction | |
dc.subject.other | velocity profile | |
dc.subject.other | the average flow velocity | |
dc.subject.other | flow resistance | |
dc.subject.other | pore network model | |
dc.subject.other | shale gas | |
dc.subject.other | volume fracturing | |
dc.subject.other | finite volume method | |
dc.subject.other | production simulation | |
dc.subject.other | multi-scale flow | |
dc.subject.other | multi-scale fracture | |
dc.subject.other | shale gas reservoir | |
dc.subject.other | fractured well transient productivity | |
dc.subject.other | succession pseudo-steady state (SPSS) method | |
dc.subject.other | complex fracture network | |
dc.subject.other | multi-scale flow | |
dc.subject.other | analysis of influencing factors | |
dc.subject.other | tight sandstones | |
dc.subject.other | spontaneous imbibition | |
dc.subject.other | remaining oil distributions | |
dc.subject.other | imbibition front | |
dc.subject.other | imbibition recovery | |
dc.subject.other | NMR | |
dc.subject.other | slip length | |
dc.subject.other | large density ratio | |
dc.subject.other | contact angle | |
dc.subject.other | pseudo-potential model | |
dc.subject.other | lattice Boltzmann method | |
dc.subject.other | micro-fracture | |
dc.subject.other | dissolved gas | |
dc.subject.other | experimental evaluation | |
dc.subject.other | reservoir depletion | |
dc.subject.other | recovery factor | |
dc.subject.other | tight oil | |
dc.subject.other | Lucaogou Formation | |
dc.subject.other | tight oil | |
dc.subject.other | pore structure | |
dc.subject.other | prediction by NMR logs | |
dc.subject.other | tight oil reservoir | |
dc.subject.other | SRV-fractured horizontal well | |
dc.subject.other | multiporosity and multiscale | |
dc.subject.other | flow regimes | |
dc.subject.other | productivity contribution degree of multimedium | |
dc.subject.other | equilibrium permeability | |
dc.subject.other | non-equilibrium permeability | |
dc.subject.other | matrix–fracture interaction | |
dc.subject.other | effective stress | |
dc.subject.other | coal deformation | |
dc.subject.other | porous media | |
dc.subject.other | non-linear flow | |
dc.subject.other | conformable derivative | |
dc.subject.other | fractal | |
dc.subject.other | hydraulic fracturing | |
dc.subject.other | tight reservoirs | |
dc.subject.other | fracture diversion | |
dc.subject.other | extended finite element method | |
dc.subject.other | fracture network | |
dc.subject.other | gas adsorption capacity | |
dc.subject.other | shale reservoirs | |
dc.subject.other | influential factors | |
dc.subject.other | integrated methods | |
dc.subject.other | sulfonate gemini surfactant | |
dc.subject.other | thickener | |
dc.subject.other | temperature-resistance | |
dc.subject.other | clean fracturing fluid | |
dc.subject.other | low-salinity water flooding | |
dc.subject.other | clay mineral composition | |
dc.subject.other | enhanced oil recovery | |
dc.subject.other | wetting angle | |
dc.subject.other | pH of formation water | |
dc.subject.other | fractional diffusion | |
dc.subject.other | fractal geometry | |
dc.subject.other | analytical model | |
dc.subject.other | shale gas reservoir | |
dc.subject.other | carbonate reservoir | |
dc.subject.other | petrophysical characterization | |
dc.subject.other | pore types | |
dc.subject.other | pore structure | |
dc.subject.other | permeability | |
dc.subject.other | fractal dimension | |
dc.subject.other | reservoir classifications | |
dc.subject.other | deep circulation groundwater | |
dc.subject.other | groundwater flow | |
dc.subject.other | geothermal water | |
dc.subject.other | faults | |
dc.subject.other | isotopes | |
dc.subject.other | shale permeability | |
dc.subject.other | local effect | |
dc.subject.other | global effect | |
dc.subject.other | matrix-fracture interactions | |
dc.subject.other | nanopore | |
dc.subject.other | pore structure | |
dc.subject.other | shale | |
dc.subject.other | tight sandstone | |
dc.subject.other | mudstone | |
dc.subject.other | nitrogen adsorption | |
dc.subject.other | fractal | |
dc.subject.other | enhanced geothermal system | |
dc.subject.other | well-placement optimization | |
dc.subject.other | fracture continuum method | |
dc.subject.other | 0-1 programming | |
dc.subject.other | unconventional reservoirs | |
dc.subject.other | petrophysical characterization | |
dc.subject.other | fluid transport physics | |
dc.title | Experiments on flux qubits with pi-shifters | |
dc.type | 電子教科書 | |
dc.classification | 自然科學類 | |
Theme: | 教科書-自然科學類 |
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