LEADER 04986nam 2201189z- 450 001 9910367738903321 005 20210211 010 $a3-03921-857-3 035 $a(CKB)4100000010106328 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/56219 035 $a(oapen)doab56219 035 $a(EXLCZ)994100000010106328 100 $a20202102d2019 |y 0 101 0 $aeng 135 $aurmn|---annan 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 00$aPhysical Metallurgy of High Manganese Steels 210 $cMDPI - Multidisciplinary Digital Publishing Institute$d2019 215 $a1 online resource (212 p.) 311 08$a3-03921-856-5 330 $aThe Special Issue 'Physical Metallurgy of High Manganese Steels' addresses the highly fascinating class of manganese-alloyed steels with manganese contents well above 3 mass%. The book gathers manuscripts from internationally recognized researchers with stimulating new ideas and original results. It consists of fifteen original research papers. Seven contributions focus on steels with manganese contents above 12 mass%. These contributions cover fundamental aspects of process-microstrcuture-properties relationships with processes ranging from cold and warm rolling over deep rolling to heat treatment. Novel findings regarding the fatigue and fracture behavior, deformation mechanisms, and computer-aided design are presented. Additionally, the Special Issue also reflects the current trend of reduced Mn content (3-12 mass%) in advanced high strength steels (AHSS). Eight contributions were dedicated to these alloys, which are often referred to as 3rd generation AHSS, medium manganese steels or quenching and partitioning (Q&P/Q+P) steels. The interplay between advanced processing, mainly novel annealing variants, and microstructure evolution has been addressed using computational and experimental approaches. A deeper understanding of strain-rate sensitivity, hydrogen embrittlement, phase transformations, and the consequences for the materials' properties has been developed. Hence, the topics included are manifold, fundamental-science oriented and, at the same time, relevant to industrial application. 606 $aHistory of engineering and technology$2bicssc 610 $aalloy design 610 $aannealing 610 $aaustenite reversion 610 $aaustenite stability 610 $aaustenite-reversed-transformation 610 $aaustenitic high nitrogen steel (HNS) 610 $acold deformation 610 $acold rolling 610 $acontinuous annealing 610 $acorrosion resistance 610 $acrash box 610 $aD& 610 $adamage 610 $adeep rolling 610 $adeformation behavior 610 $adeformation twinning 610 $adislocation density 610 $adouble soaking 610 $adynamic strain aging 610 $afatigue 610 $afatigue behavior 610 $aforging 610 $afracture 610 $agrain refinement 610 $ahigh manganese steel 610 $ahigh strength steel 610 $ahigh-entropy alloys 610 $ahigh-manganese steel 610 $ahigh-manganese steels 610 $ahigh-Mn steels 610 $ahot-stamping 610 $ahydrogen embrittlement 610 $ain-situ DIC tensile tests 610 $aintercritical annealing 610 $alightweight 610 $alocalized deformation 610 $aLu?ders band 610 $amechanical properties 610 $amedium manganese steel 610 $amedium-manganese 610 $amedium-manganese steel 610 $amedium-Mn steel 610 $amicrostructure 610 $aMMn steel X20CrNiMnVN18-5-10 610 $amultiscale simulation 610 $an/a 610 $anear surface properties 610 $aneutron diffraction 610 $aP steel 610 $aphase field simulation 610 $aphase transformation 610 $aplastic deformation 610 $aprecipitations 610 $aprocessing 610 $aquenching and partitioning 610 $arecrystallization annealing 610 $aresidual stresses 610 $aretained austenite 610 $aserrated flow 610 $astrain-hardening behavior 610 $astrain-rate sensitivity 610 $astrengthening 610 $atexture 610 $aTRIP 610 $atwinning induced plasticity 610 $aTWIP 610 $aTWIP steel 610 $aultrafine grains 610 $aultrafine-grained microstructure 610 $aV alloying 610 $awarm rolling 615 7$aHistory of engineering and technology 700 $aBleck$b Wolfgang$4auth$01306026 702 $aHaase$b Christian$4auth 906 $aBOOK 912 $a9910367738903321 996 $aPhysical Metallurgy of High Manganese Steels$93028145 997 $aUNINA