G
Gabriel Blaj
Researcher at SLAC National Accelerator Laboratory
Publications - 61
Citations - 980
Gabriel Blaj is an academic researcher from SLAC National Accelerator Laboratory. The author has contributed to research in topics: Detector & Pixel. The author has an hindex of 14, co-authored 60 publications receiving 844 citations. Previous affiliations of Gabriel Blaj include Stanford University & CERN.
Papers
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Journal ArticleDOI
The Medipix3RX: a high resolution, zero dead-time pixel detector readout chip allowing spectroscopic imaging
Rafael Ballabriga,J. Alozy,Gabriel Blaj,Michael Campbell,Michael Fiederle,Erik Fröjdh,Erik H.M. Heijne,X. Llopart,M. Pichotka,S. Procz,Lukas Tlustos,W. Wong +11 more
TL;DR: The Medipix3RX chip as mentioned in this paper uses an architecture in which adjacent pixels communicate in the analog and digital domains on an event-by-event basis to reconstruct the deposited charge in a neighbourhood prior to the assignation of the hit to a single pixel.
Journal ArticleDOI
X-ray detectors at the Linac Coherent Light Source
Gabriel Blaj,P. Caragiulo,Gabriella Carini,Sebastian Carron,Angelo Dragone,D. Freytag,Gunther Haller,Philip Hart,Jasmine Hasi,Ryan Herbst,Sven Herrmann,C.J. Kenney,Bojan Markovic,K. Nishimura,S. Osier,J. Pines,B. Reese,J. Segal,Astrid Tomada,M. Weaver +19 more
TL;DR: An overview of area detectors developed for use at the Linac Coherent Light Source (LCLS) with particular emphasis on their impact on science is offered.
Journal ArticleDOI
Characterization of the Medipix3 pixel readout chip
Rafael Ballabriga,Gabriel Blaj,M. Campbell,Michael Fiederle,Dominic Greiffenberg,Erik H.M. Heijne,X. Llopart,R. Plackett,R. Plackett,S. Procz,Lukas Tlustos,Daniel Turecek,W. Wong +12 more
TL;DR: The Medipix3 chip as discussed by the authors is a hybrid pixel detector readout chip working in Single Photon Counting Mode (SPM) with a front-end architecture aimed at eliminating the spectral distortion produced by charge diffusion in highly segmented semiconductor detectors.
ReportDOI
New Science Opportunities Enabled by LCLS-II X-ray Lasers
P. Abbamonte,F. Abild Pedersen,Paul D. Adams,Musa Ahmed,Felicie Albert,R. Alonso Mori,Philip A. Anfinrud,A. Aqui la,M. Armstrong,John V. Arthur,J. Bargar,Anton Barty,Uwe Bergmann,Nora Berrah,Gabriel Blaj,Hendrik Bluhm,C. Bolme,Christoph Bostedt,Sébastien Boutet,Gordon E. Brown,Phillip Bucksbaum,M. Cargnello,Gabriella Carini,Andrea Cavalleri,Vadim Cherezov,W. Chiu,Y. Chuang,Daniele Cocco,R. Coffee,Gilbert Collins,A. Cordones Hahn,James P. Cryan,Georgi L. Dakovski,M. Dantus,Hasan DeMirci,P. Denes,Thomas P. Devereaux,Y. Ding,Sebastian Doniach,Reinhard Dörner,Mike Dunne,H. A. Dürr,T. Egami,D. Eisenberg,Paul Emma,C. Fadley,Roger Falcone,Y. Feng,Pontus Fischer,Frederico Fiuza,Luke Fletcher,L. Fou car,Matthias Frank,James S. Fraser,Heinz Frei,David Fritz,Petra Fromme,Alan Fry,Matthias Fuchs,Paul H. Fuoss,Kelly J. Gaffney,E. J. Gamboa,Oliver Gessner,Shambhu Ghimire,Arianna Gleason,S.H. Glenzer,Tais Gorkhover,Alexander X. Gray,Markus Guehr,J. Guo,Janos Hajdu,S. Hansen,P. Hart,M. Hashimoto,J. B. Hastings,Daniel J. Haxton,P.A. Heimann,Tony F. Heinz,A. Hexemer,John Hill,F. Himpsel,P. Ho,Brenda G. Hogue,Z. Huang,Mark S. Hunter,Greg L. Hura,Nils Huse,Zahid Hussain,Markus Ilchen,C. Jacobsen,C.J. Kenney,Jan Kern,Stephen D. Kevan,J. Kim,H. Kim,Patrick S. Kirchmann,Richard A. Kirian,Steven A. Kivelson,C. Kliewer,J. Ko ralek,G. Kovácsová,A. Lanzara,Jerry LaRue,H. Lee,J. Lee,W. Lee,Y. Lee,I. Lindau,Aaron M. Lindenberg,Z. Liu,D. Lu,U. Lundstrom,A. MacDowell,W. Mao,Jonathan P. Marangos,Gabriel Marcus,Todd J. Martínez,William McCurdy,Geraldine McDermott,C. McGuffey,H. Michelsen,Michael P. Minitti,S. Miyabe,Stefan Moeller,Robert G. Moore,S. Mukamel,Karol Nass,Adi Natan,Kimberly L. Nelson,S. Nemšák,Daniel M. Neumark,Richard Neutze,Anders Nilsson,Dennis Nordlund,Jens K. Nørskov,S. Nozawa,Hirohito Ogasawara,Hendrik Ohldag,Allen M. Orville,D. Osborn,Timur Osipov,Abbas Ourmazd,D. Parkinson,C. Pelle grini,George N. Phillips,T. Rasing,Tor Raubenheimer,Thomas N. Rescigno,A. Reid,David A. Reis,Aymeric Robert,J. S. Robinson,Daniel Rolles,Jan M. Rost,Sashwati Roy,Artem Rudenko,Thomas P. Russell,Robert B. Sandberg,Arvinder Sandhu,Nicholas K. Sauter,Ilme Schlichting,R. Schlögl,William F. Schlotter,Marius Schmidt,Jen Schneider,Robert W. Schoenlein,M. Schoeffler,A. Scholl,Z. Shen,Oleg Shpyrko,T. Silva,Shantanu Sinha,Daniel Slaughter,Jonathan Sobota,D. Sokaras,K. Sokolowski Tinten,S. Southworth,S. Arizona,Claudiu A. Stan,Joachim Stöhr,Robert M. Stroud,Villy Sundström,C. Taatjes,A. Thomas,Mariano Trigo,Y. Tsui,Joshua J. Turner,A. W. van Buuren,S. M. Vinko,Soichi Wakatsuki,Justin Wark,Peter M. Weber,Thorsten Weber,M. Wei,Thomas M. Weiss,Philippe Wernet,William E. White,Philip R. Willmott,K. Wilson,Wilfried Wurth,Vittal K. Yachandra,Junko Yano,D. Yarotski,L. Young,Y. Zhu,Diling Zhu,Petrus H. Zwart +206 more
Journal ArticleDOI
Negative Pressures and Spallation in Water Drops Subjected to Nanosecond Shock Waves.
Claudiu A. Stan,Philip R. Willmott,Howard A. Stone,Jason E. Koglin,Mengning Liang,Andrew Aquila,Joseph Robinson,Karl Gumerlock,Gabriel Blaj,Raymond G. Sierra,Sébastien Boutet,Serge Guillet,Robin Curtis,Sharon Vetter,Henrik Loos,James Turner,F.-J. Decker +16 more
TL;DR: This work generates tension pulses with nanosecond rise times in water by reflecting cylindrical shock waves, produced by X-ray laser pulses, at the internal surface of drops of water, using a nucleation-and-growth model that explains how rapid decompression could outrun heterogeneous cavitation in water, and enable the study of stretched water close to homogeneous Cavitation pressures.