LEADER 05010nam 2201261z- 450 001 9910580208403321 005 20231214133414.0 035 $a(CKB)5690000000012004 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/87412 035 $a(EXLCZ)995690000000012004 100 $a20202207d2022 |y 0 101 0 $aeng 135 $aurmn|---annan 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aState of the Art Geo-Energy Technology in China 210 $aBasel$cMDPI - Multidisciplinary Digital Publishing Institute$d2022 215 $a1 electronic resource (264 p.) 311 $a3-0365-4379-1 311 $a3-0365-4380-5 330 $aDear colleagues, Geological energy has a long history in China. As early as 500 BC, China began to use coal as fuel. In the middle of the 19th century, China began to develop oil resources. After the foundation of new China, with the discovery of the Daqing oilfield, China's oil industry entered an era of great development. During the 21st century, with the development of drilling technology, the development of unconventional energy such as shale gas and shale oil has entered a new era. In recent years, the development of flammable ice has set off a wave of clean energy. With the carbon reduction plan proposed by the Chinese government, clean geo-energy has been granted unparalleled development space in the future. China's geo-energy development technology used to lag behind that of major developed countries for a long time, but after years of development, it has become the world's leading edge in some fields. Therefore, we specially set up this collection to collect China's advanced geo-energy exploitation technology and development trends, whilst providing some new directions for thinking about geo-energy development in China and even the world. This collection seeks to contribute to such topics through enhanced scientific and multidisciplinary knowledge. 606 $aResearch & information: general$2bicssc 610 $aairflow reversal 610 $agas outburst 610 $amine ventilation system 610 $aorthogonal experiment 610 $anumerical simulation 610 $adeep chamber 610 $aasymmetric failure 610 $amechanical analysis 610 $acontrol measures 610 $aYinggehai 610 $aoverpressure 610 $ahydraulic fracture 610 $amudstone 610 $afluid pressure 610 $ared sandstone 610 $apre-existing cracks 610 $acreep behavior 610 $atemperature 610 $along-term permeability 610 $apartial saturation 610 $apatchy saturation 610 $asquirt flow 610 $aP-wave velocity dispersion and attenuation 610 $aanelasticity 610 $aultrasonic measurements 610 $aheavy oil reservoirs 610 $acyclic steam stimulation 610 $aconformance control 610 $aextreme gradient boost (XGBoost) trees 610 $aprediction model 610 $aDongsha Waters in the northern South China Sea margin 610 $avelocity inversion 610 $amud volcano 610 $amagma intrusion 610 $aMesozoic hydrocarbon 610 $atubing 610 $amodal analysis 610 $afluid-structure interaction 610 $ainlet pressure 610 $apipeline 610 $awater hammer 610 $agas-liquid two-phase flow 610 $apressure 610 $avelocity 610 $alattice Boltzmann method 610 $adiscrete element method 610 $asand production 610 $aforce chain network analysis 610 $aseismic sedimentology 610 $asedimentary facies evolution 610 $apeat accumulation regularity 610 $afrequency?division amplitude fusion 610 $athin sand bodies 610 $astable crack propagation 610 $acrack strain 610 $astress?strain curve 610 $amodel 610 $awing crack 610 $aoutburst coal 610 $aprimary coal 610 $astructural parameters 610 $ainfrared spectrum 610 $aXRD 610 $aoil shale 610 $ain situ conversion project 610 $abiomarker 610 $apyrolysis process 610 $aorganic geochemistry 615 7$aResearch & information: general 700 $aYang$b Sheng-Qi$4edt$01059040 702 $aWang$b Min$4edt 702 $aWang$b Qi$4edt 702 $aZhang$b Wen$4edt 702 $aDu$b Kun$4edt 702 $aZhu$b Chun$4edt 702 $aYang$b Sheng-Qi$4oth 702 $aWang$b Min$4oth 702 $aWang$b Qi$4oth 702 $aZhang$b Wen$4oth 702 $aDu$b Kun$4oth 702 $aZhu$b Chun$4oth 906 $aBOOK 912 $a9910580208403321 996 $aState of the Art Geo-Energy Technology in China$93030217 997 $aUNINA