LEADER 00851nam0-2200289---450- 001 990009195400403321 005 20100608110935.0 035 $a000919540 035 $aFED01000919540 035 $a(Aleph)000919540FED01 035 $a000919540 100 $a20100608d1960----km-y0itay50------ba 101 0 $aeng 102 $aNE 105 $aa-------001yy 200 1 $aFundamental Aspects of Normal and Malignant Growth$fWiktor W. Nowinski 210 $aAmsterdam [etc.]$cElsevier Publishing Company$d1960 215 $aXV, 1025 p.$cill.$d25 cm 610 0 $aCancerologia 700 1$aNowinski,$bWiktor W.$063388 801 0$aIT$bUNINA$gRICA$2UNIMARC 901 $aBK 912 $a990009195400403321 952 $aAUpc 3D 10$b10406$fDBEC 959 $aDBEC 996 $aFundamental Aspects of Normal and Malignant Growth$9775378 997 $aUNINA LEADER 01820nam0 2200373 i 450 001 SUN0124612 005 20191023100115.600 010 $d0.00 017 70$2N$a978-3-319-73839-0 100 $a20191022d2018 |0engc50 ba 101 $aeng 102 $aCH 105 $a|||| ||||| 200 1 $a*Computational diffusion MRI$eMICCAI Workshop, Québec, Canada, September 2017$fEnrico Kaden ... [et al.] editors 205 $aCham : Springer, 2018 210 $axi$d245 p.$cill. ; 24 cm 215 $aPubblicazione in formato elettronico 410 1$1001SUN0068552$12001 $a*Mathematics and visualization$1210 $aBerlin$cSpringer$d2001-. 606 $a92Bxx$xMathematical biology in general [MSC 2020]$2MF$3SUNC021467 606 $a65Zxx$xApplications to the sciences [MSC 2020]$2MF$3SUNC021520 606 $a65Dxx$xNumerical approximation and computational geometry (primarily algorithms) [MSC 2020]$2MF$3SUNC022980 606 $a62P10$xApplications of statistics to biology and medical sciences; meta analysis [MSC 2020]$2MF$3SUNC024649 606 $a65Cxx$xProbabilistic methods, stochastic differential equations [MSC 2020]$2MF$3SUNC028329 606 $a00A66$xMathematics and visual arts [MSC 2020]$2MF$3SUNC031202 620 $aCH$dCham$3SUNL001889 702 1$aKaden$b, Enrico$3SUNV096049 712 12$aMICCAI Workshop ?Computational Diffusion MRI?$f2017$eQuébec, Canada$3SUNV096050 712 $aSpringer$3SUNV000178$4650 801 $aIT$bSOL$c20210503$gRICA 856 4 $uhttp://doi.org/10.1007/978-3-319-73839-0 912 $aSUN0124612 950 $aUFFICIO DI BIBLIOTECA DEL DIPARTIMENTO DI MATEMATICA E FISICA$d08CONS e-book 1076 $e08eMF1076 20191022 996 $aComputational diffusion MRI$91409948 997 $aUNICAMPANIA LEADER 04183nam 22005655 450 001 9910337873803321 005 20200704142637.0 010 $a3-030-22208-X 024 7 $a10.1007/978-3-030-22208-6 035 $a(CKB)4100000008707649 035 $a(MiAaPQ)EBC5830028 035 $a(DE-He213)978-3-030-22208-6 035 $a(PPN)238489752 035 $a(EXLCZ)994100000008707649 100 $a20190716d2019 u| 0 101 0 $aeng 135 $aurcnu|||||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aRelativistically Intense Laser?Microplasma Interactions /$fby Tobias Ostermayr 205 $a1st ed. 2019. 210 1$aCham :$cSpringer International Publishing :$cImprint: Springer,$d2019. 215 $a1 online resource (175 pages) 225 1 $aSpringer Theses, Recognizing Outstanding Ph.D. Research,$x2190-5053 311 $a3-030-22207-1 327 $aPat I: Introduction and basics -- Scienti?c context and motivation -- Laser-plasmas -- Part II: Experimental methods -- High-power lasers -- Transportable Paul trap for isolated micro-targets in vacuum -- Part III: Laser-microplasma interactions -- Laser-driven ion acceleration using isolated micro-sphere targets -- Laser-driven micro-source for bi-modal radiographic imaging -- Part IV: Summary and perspectives. Summary -- Challenges and Perspectives -- Part V: Appendix. 330 $aThis dissertation covers several important aspects of relativistically intense laser?microplasma interactions and some potential applications. A Paul-trap based target system was developed to provide fully isolated, well defined and well positioned micro-sphere-targets for experiments with focused peta-watt laser pulses. The laser interaction turned such targets into microplasmas, emitting proton beams with kinetic energies exceeding 10 MeV. The proton beam kinetic energy spectrum and spatial distribution were tuned by variation of the acceleration mechanism, reaching from broadly distributed spectra in relatively cold plasma expansions to spectra with relative energy spread as small as 20% in spherical multi-species Coulomb explosions and in directed acceleration processes. Numerical simulations and analytical calculations support these experimental findings and show how microplasmas may be used to engineer laser-driven proton sources. In a second effort, tungsten micro-needle-targets were used at a peta-watt laser to produce few-keV x-rays and 10-MeV-level proton beams simultaneously, both measured to have only few-µm effective source-size. This source was used to demonstrate single-shot simultaneous radiographic imaging with x-rays and protons of biological and technological samples. Finally, the dissertation discusses future perspectives and directions for laser?microplasma interactions including non-spherical target shapes, as well as thoughts on experimental techniques and advanced quantitative image evaluation for the laser driven radiography. 410 0$aSpringer Theses, Recognizing Outstanding Ph.D. Research,$x2190-5053 606 $aPlasma (Ionized gases) 606 $aLasers 606 $aPhotonics 606 $aParticle acceleration 606 $aPlasma Physics$3https://scigraph.springernature.com/ontologies/product-market-codes/P24040 606 $aOptics, Lasers, Photonics, Optical Devices$3https://scigraph.springernature.com/ontologies/product-market-codes/P31030 606 $aParticle Acceleration and Detection, Beam Physics$3https://scigraph.springernature.com/ontologies/product-market-codes/P23037 615 0$aPlasma (Ionized gases) 615 0$aLasers. 615 0$aPhotonics. 615 0$aParticle acceleration. 615 14$aPlasma Physics. 615 24$aOptics, Lasers, Photonics, Optical Devices. 615 24$aParticle Acceleration and Detection, Beam Physics. 676 $a621.366 676 $a621.366 700 $aOstermayr$b Tobias$4aut$4http://id.loc.gov/vocabulary/relators/aut$01062100 906 $aBOOK 912 $a9910337873803321 996 $aRelativistically Intense Laser?Microplasma Interactions$92522934 997 $aUNINA