> HG \pJava Excel API v2.6.10 Ba==h\:#8X@"1Arial1Arial1Arial1Arial  + ) , * `VUnknown, 2RankNameURL1DDevelopment of an AMR octree DSMC approach for shock dominated flowsnhttps://experts.illinois.edu/en/publications/developmentofanamroctreedsmcapproachforshockdominatedfl2On linear stability analyses of hypersonic laminar separated flows in a DSMC framework part I: Base flow computations in a double cone and a 'tick' modelnhttps://experts.illinois.edu/en/publications/onlinearstabilityanalysesofhypersoniclaminarseparatedflow3CHAOS: An octreebased PICDSMC code for modeling of electron kinetic properties in a plasma plume using MPICUDA parallelizationnhttps://experts.illinois.edu/en/publications/chaosanoctreebasedpicdsmccodeformodelingofelectronkine4sAdvanced parallelization strategies using hybrid MPICUDA octree DSMC method for modeling flow through porous medianhttps://experts.illinois.edu/en/publications/advancedparallelizationstrategiesusinghybridmpicudaoctree5lHigh fidelity and 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interactions for a double wedge configuration in different gasesnhttps://experts.illinois.edu/en/publications/shockshockinteractionsforadoublewedgeconfigurationindiff11/3D detailed far field plume modeling of SPT100^https://experts.illinois.edu/en/publications/3ddetailedfarfieldplumemodelingofspt100312gOn the unsteadiness of shocklaminar boundary layer interactions of hypersonic flows over a double conenhttps://experts.illinois.edu/en/publications/ontheunsteadinessofshocklaminarboundarylayerinteractions13mComparison of two protic ionic liquid behaviors in the presence of an electric field using molecular dynamicsnhttps://experts.illinois.edu/en/publications/comparisonoftwoproticionicliquidbehaviorsinthepresenceo14INovel use of AMR unstructured grids in DSMC compressible flow simulationsphttps://experts.illinois.edu/en/publications/noveluseofamrunstructuredgridsindsmccompressibleflowsim215\Electrospray molecular dynamics simulations using an octreebased Coulomb interaction methodnhttps://experts.illinois.edu/en/publications/electrospraymoleculardynamicssimulationsusinganoctreebased16XState specific modeling of energy transfer in nitrogen shocks using high fidelity modelsnhttps://experts.illinois.edu/en/publications/statespecificmodelingofenergytransferinnitrogenshocksusi17[Three dimensional simulation of ion thruster plumes with AMR and parallelization strategiesphttps://experts.illinois.edu/en/publications/threedimensionalsimulationofionthrusterplumeswithamrand218^DSMC implementation of MD/QCT generated energy distributions for SO<sub>2</sub> + O collisionsnhttps://experts.illinois.edu/en/publications/dsmcimplementationofmdqctgeneratedenergydistributionsfors19BBGK and MD simulations of H<sub>2</sub>O supersonic condensed jetsjhttps://experts.illinois.edu/en/publications/bgkandmdsimulationsofhsub2subosupersoniccondensedjets20Preface for the RGD proceedingsLhttps://experts.illinois.edu/en/publications/prefaceforthergdproceedi< ngs21USimulation of a typical reentry vehicle TPS local flow features and material responsenhttps://experts.illinois.edu/en/publications/simulationofatypicalreentryvehicletpslocalflowfeaturesa22TMultiscale kdistribution model for gas mixtures in hypersonic nonequilibrium flowsnhttps://experts.illinois.edu/en/publications/multiscalekdistributionmodelforgasmixturesinhypersonicn23RSimulation of the stagnation region microcrack growth during space shuttle reentrynhttps://experts.illinois.edu/en/publications/simulationofthestagnationregionmicrocrackgrowthduringspac24VDSMC simulations of the plasma bombardment on Io's sublimated and sputtered atmospherenhttps://experts.illinois.edu/en/publications/dsmcsimulationsoftheplasmabombardmentoniossublimatedand25lDevelopment of a molecular dynamicsbased coalescence model for DSMC simulations of ammonia condensate flowsnhttps://experts.illinois.edu/en/publications/developmentofamoleculardynamicsbasedcoalescencemodelford26\Study of homogeneous condensation of water in supersonic expansions using molecular dynamicsnhttps://experts.illinois.edu/en/publications/studyofhomogeneouscondensationofwaterinsupersonicexpansio27[Coupled molecular dynamics  3D poisson simulations of ionic liquid electrospray thrustersnhttps://experts.illinois.edu/en/publications/coupledmoleculardynamics3dpoissonsimulationsofionicliqui28IModeling of an ionic liquid electrospray using a molecular dynamics modelphttps://experts.illinois.edu/en/publications/modelingofanionicliquidelectrosprayusingamoleculardynami329K3D simulation of ion thruster plumes using octree adaptive mesh refinementphttps://experts.illinois.edu/en/publications/3dsimulationofionthrusterplumesusingoctreeadaptivemesh230Molecular dynamics electrospray simulations of coarsegrained ethylammonium nitrate (EAN) and 1ethyl3methylimidazolium tetrafluoroborate (EMIMBF<sub>4</sub>)nhttps://experts.illinois.edu/en/publications/moleculardynamicselectrospraysimulationsofcoarsegrainedeth31bInvestigation of the DSMC approach for ion/neutral species in modeling low pressure plasma reactornhttps://experts.illinois.edu/en/publications/investigationofthedsmcapproachforionneutralspeciesinmode32eDevelopment of a chemistry model for DSMC simulation of the atmosphere of Io using molecular dynamicsphttps://experts.illinois.edu/en/publications/developmentofachemistrymodelfordsmcsimulationoftheatmos233Development of a moleculardynamicsbased clusterheatcapacity model for study of homogeneous condensation in supersonic watervapor expansionsnhttps://experts.illinois.edu/en/publications/developmentofamoleculardynamicsbasedclusterheatcapacitym34`State specific vibrational relaxation and dissociation models for nitrogen in shock wave regionsphttps://experts.illinois.edu/en/publications/statespecificvibrationalrelaxationanddissociationmodelsfor335wSimulation of homogeneous condensation of ethanol in high pressure supersonic nozzle flows using BGK condensation modelnhttps://experts.illinois.edu/en/publications/simulationofhomogeneouscondensationofethanolinhighpressur36ZDevelopment of a particleparticle hybrid scheme to simulate multiscale transitional flowsnhttps://experts.illinois.edu/en/publications/developmentofaparticleparticlehybridschemetosimulatemult37XModeling of nitrogen monoxide formation and radiation in nonequilibrium hypersonic flowsnhttps://experts.illinois.edu/en/publications/modelingofnitrogenmonoxideformationandradiationinnonequil38Simulation of homogeneous condensation of small polyatomic systems in high pressure supersonic nozzle flows using BhatnagarGrossKrook modelnhttps://experts.illinois.edu/en/publications/simulationofhomogeneouscondensationofsmallpolyatomicsystem39cCoupled molecular dynamics  Onedimensional PIC simulations of ionic liquid electrospray thrustersnhttps://experts.illinois.edu/en/publications/coupledmoleculardynamicsonedimensio<nalpicsimulationsofion40\Development of the ellipsoidal statistical bhatnagarGrosskrook method for hypersonic flowsnhttps://experts.illinois.edu/en/publications/developmentoftheellipsoidalstatisticalbhatnagargrosskrook415Simulation of plasma interaction with Io's atmosphereahttps://experts.illinois.edu/en/publications/simulationofplasmainteractionwithiosatmosphere42MAnalysis of fractallike spore aggregates using direct simulation Monte Carlonhttps://experts.illinois.edu/en/publications/analysisoffractallikesporeaggregatesusingdirectsimulation43:In depth analysis of AVCOAT TPS response to a reentry flowghttps://experts.illinois.edu/en/publications/indepthanalysisofavcoattpsresponsetoareentryflow44;Ionic liquid electrospray modeling using molecular dynamicsjhttps://experts.illinois.edu/en/publications/ionicliquidelectrospraymodelingusingmoleculardynamics245LDevelopment of a chemistry model for DSMC simulation of the atmosphere of Ionhttps://experts.illinois.edu/en/publications/developmentofachemistrymodelfordsmcsimulationoftheatmos46nhttps://experts.illinois.edu/en/publications/threedimensionalsimulationofionthrusterplumeswithamrand47dDevelopment of DSMC chemistry models for nitrogen collisions using accurate theoretical calculationsphttps://experts.illinois.edu/en/publications/developmentofdsmcchemistrymodelsfornitrogencollisionsusin348JClosely coupled flowfieldradiation interactions during hypersonic reentrynhttps://experts.illinois.edu/en/publications/closelycoupledflowfieldradiationinteractionsduringhypersoni49YModeling of electronic excitation and radiation in noncontinuum hypersonic reentry flowsnhttps://experts.illinois.edu/en/publications/modelingofelectronicexcitationandradiationinnoncontinuum50VSimulations of ion thruster plumes in ground facilities using adaptive mesh refinementnhttps://experts.illinois.edu/en/publications/simulationsofionthrusterplumesingroundfacilitiesusingadaj".rt <lL
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