LEADER 02529nam0 22006133i 450 001 VAN0211335 005 20230609120938.689 017 70$2N$a9783319963044 100 $a20210903d2018 |0itac50 ba 101 $aeng 102 $aCH 105 $a|||| ||||| 200 1 $aKinetics of Evaporation$fDenis N. Gerasimov, Eugeny I. Yurin 210 $aCham$cSpringer$d2018 215 $axvii, 321 p.$cill.$d24 cm 410 1$1001VAN0132874$12001 $aSpringer Series in Surface Sciences$1210 $aBerlin [etc.]$cSpringer$v68 500 1$3VAN0211336$aKinetics of Evaporation$91866848 606 $a76-XX$xFluid mechanics [MSC 2020]$3VANC019858$2MF 606 $a80-XX$xClassical thermodynamics, heat transfer [MSC 2020]$3VANC022357$2MF 606 $a82-XX$xStatistical mechanics, structure of matter [MSC 2020]$3VANC021931$2MF 610 $aBBGKY chain$9KW:K 610 $aBoltzmann kinetic equation$9KW:K 610 $aCUDA optimization technique$9KW:K 610 $aCavitation$9KW:K 610 $aCondensation coefficient$9KW:K 610 $aEvaporated atoms$9KW:K 610 $aEvaporation coefficient$9KW:K 610 $aEvaporation surface$9KW:K 610 $aFilm boiling$9KW:K 610 $aHydrodynamics equations$9KW:K 610 $aLiouville theorem$9KW:K 610 $aMaster equation$9KW:K 610 $aMaxwell distribution function$9KW:K 610 $aNucleate boiling$9KW:K 610 $aParallel computing on GPU$9KW:K 610 $aParticle in cell$9KW:K 610 $aTemperature jump$9KW:K 610 $aTransient boiling$9KW:K 610 $aTrouton rule$9KW:K 610 $aVlasov approach$9KW:K 620 $aCH$dCham$3VANL001889 700 1$aGerasimov$bDenis N.$3VANV182012$0835346 701 1$aYurin$bEugeny I.$3VANV182013$0835347 712 $aSpringer $3VANV108073$4650 790 1$aGerasimov, D.N.$zGerasimov, Denis N.$3VANV232328 790 1$aGerasimov, D. N.$zGerasimov, Denis N.$3VANV232329 801 $aIT$bSOL$c20240726$gRICA 856 4 $uhttp://doi.org/10.1007/978-3-319-96304-4$zE-book ? Accesso al full-text attraverso riconoscimento IP di Ateneo, proxy e/o Shibboleth 899 $aBIBLIOTECA DEL DIPARTIMENTO DI MATEMATICA E FISICA$1IT-CE0120$2VAN08 912 $fN 912 $aVAN0211335 950 $aBIBLIOTECA DEL DIPARTIMENTO DI MATEMATICA E FISICA$d08CONS e-book 3571 $e08eMF3571 20210903 996 $aKinetics of Evaporation$91866848 997 $aUNICAMPANIA