89 research outputs found
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Performance of ePix10K, a high dynamic range, gain auto-ranging pixel detector for FELs
ePix10K is a hybrid pixel detector developed at SLAC for demanding
free-electron laser (FEL) applications, providing an ultrahigh dynamic range
(245 eV to 88 MeV) through gain auto-ranging. It has three gain modes (high,
medium and low) and two auto-ranging modes (high-to-low and medium-to-low). The
first ePix10K cameras are built around modules consisting of a sensor flip-chip
bonded to 4 ASICs, resulting in 352x384 pixels of 100 m x 100 m each.
We present results from extensive testing of three ePix10K cameras with FEL
beams at LCLS, resulting in a measured noise floor of 245 eV rms, or 67 e
equivalent noise charge (ENC), and a range of 11000 photons at 8 keV. We
demonstrate the linearity of the response in various gain combinations: fixed
high, fixed medium, fixed low, auto-ranging high to low, and auto-ranging
medium-to-low, while maintaining a low noise (well within the counting
statistics), a very low cross-talk, perfect saturation response at fluxes up to
900 times the maximum range, and acquisition rates of up to 480 Hz. Finally, we
present examples of high dynamic range x-ray imaging spanning more than 4
orders of magnitude dynamic range (from a single photon to 11000
photons/pixel/pulse at 8 keV). Achieving this high performance with only one
auto-ranging switch leads to relatively simple calibration and reconstruction
procedures. The low noise levels allow usage with long integration times at
non-FEL sources. ePix10K cameras leverage the advantages of hybrid pixel
detectors with high production yield and good availability, minimize
development complexity through sharing the hardware, software and DAQ
development with all other versions of ePix cameras, while providing an upgrade
path to 5 kHz, 25 kHz and 100 kHz in three steps over the next few years,
matching the LCLS-II requirements.Comment: 9 pages, 5 figure
Technical considerations about laparoscopic treatment of giant hiatal hernia
Clinica I Chirurgie, Clinica II Chirurgie, Clinica ATI, Spital Clinic Universitar de Urgenţe “Sf.Spiridon”, Iaşi, România, Al XII-lea Congres al Asociației Chirurgilor „Nicolae Anestiadi” din Republica Moldova cu participare internațională 23-25 septembrie 2015Introducere: Hernia hiatală gigantă este definită acea hernie care conține mai mult de o treime din stomac în sacul herniar.
Reprezintă în general cam 5-10% din totalul herniilor hiatale, iar distanța dintre pilierii diafragmului este adesea peste 5 cm.
Tehnica chirurgicală laparoscopică este metoda terapeutică cea mai bună, însă necesită anumite artificii tehnice.
Scopul studiului este de a implementa anumite gesturi chirurgicale în tratamentul laparoscopic al acestei entități.
Material și metode: Este un studiu retrospectiv pe 5 ani între ianuarie 2010 și decembrie 2014, realizat în Clinica I Chirurgie,
Spital Clinic Universitar de Urgențe “Sf.Spiridon”, Iași. În acest studiu au fost incluși un numar de 32 de pacienți, dintre care 8
hernii hiatale gigantice. Criteriile de includere au fost: pacienți cu peste 1/3 din stomac în sacul de hernie, orificiul herniar peste
5 cm și pacienți care nu au mai fost operați pentru patologie esogastroduodenală.
Rezultate: Au existat complicații minore intraoperatorii ce au fost rezolvate (deschiderea pleurei în 4 cazuri cu sutura acesteia
și o plagă hepatică la care s-a realizat hemostaza). Postoperator nu au fost complicații locale, controlul cu substanță de contrast
făcîndu-se între ziua a 4-a și a 7-a postoperator. A existat un singur caz de pneumonie lobară ce s-a remis sub tratament
medical. Particularitățile tehnice au fost cele legate de disecția sacului, închiderea orificiului și efectuarea procedeului antireflux.
Concluzii: Un diagnostic precis și bine documentat alături de folosirea unei tehnici adecvate duce la rezultate foarte bune pe
termen lung în herniile hiatale gigante.Introduction: Giant hiatal hernia is defined the hernia that contains more than a third of stomach in hernia sac. Generally
represents about 5-10% of hiatal hernias and diaphragmatic distance between pillars is often more than 5 cm. Laparoscopic
surgical technique provides the best approach, but it requires some technical fireworks.
The aim of research is to implement some particular skills in laparoscopic surgical treatment of this entity.
Material and methods: It is a 5-year retrospective study between January 2010 and December 2014, conducted in First
Surgical Clinic University Emergency Hospital “St.Spiridon”, Iasi. The study includes a total of 32 patients of which 8 were giant
hiatal hernias. Inclusion criteria were patients with more than 1/3 of stomach in hernia sac, pillar distance more than 5 cm and
patients who have not been operated for an esogastroduodenal pathology.
Results: There were minor intraoperative complications that were resolved (opening pleura in 4 cases with its suture and
wound liver who achieved hemostasis). There were no major postoperative complication and local control with contrast being
made between 4th and 7th postoperative day. There was one case of lobar pneumonia which was resolved under medical
treatment. Technical peculiarities were related to sac dissection, closing the defect and making anti-reflux procedure.
Conclusions: An accurate and documented diagnosis with the use of appropriate techniques lead to very good results in the
long term of giant hiatal hernias
Atomistic characterization of the active-site solvation dynamics of a model photocatalyst
The interactions between the reactive excited state of molecular photocatalysts and surrounding solvent dictate reaction mechanisms and pathways, but are not readily accessible to conventional optical spectroscopic techniques. Here we report an investigation of the structural and solvation dynamics following excitation of a model photocatalytic molecular system [Ir-2(dimen)(4)](2+), where dimen is para-diisocyanomenthane. The time-dependent structural changes in this model photocatalyst, as well as the changes in the solvation shell structure, have been measured with ultrafast diffuse X-ray scattering and simulated with Born-Oppenheimer Molecular Dynamics. Both methods provide direct access to the solute-solvent pair distribution function, enabling the solvation dynamics around the catalytically active iridium sites to be robustly characterized. Our results provide evidence for the coordination of the iridium atoms by the acetonitrile solvent and demonstrate the viability of using diffuse X-ray scattering at free-electron laser sources for studying the dynamics of photocatalysis.1
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