Light Ion Accelerating Line (L3IA): Test Experiment at ILIL-PW

The construction of a novel Laser driven Light Ions Acceleration Line(L3IA) is progressing rapidly towards the operation, following the recent upgrade of the ILIL-PW laser facility. The Line was designed following the pilot experimental activity carried out earlier at the same facility to define design parameters and to identify main components including target control and diagnostic equipment, also in combination with the numerical simulations for the optimization of laser and target parameters. A preliminary set of data was acquired following the successful commissioning of the laser system >100 TW upgrade. Data include output from a range of different ion detectors and optical diagnostics installed for qualification of the laser-target interaction. An overview of the results is given along with a description of the relevant upgraded laser facility and features.Comment: 6 pages, 7 figures, 18 references, presented at the EAAC 201

High-quality GeV-scale electron bunches with the Resonant Multi-Pulse Ionization Injection

Recently a new injection scheme for Laser Wake Field Acceleration, employing a single 100-TW-class laser system, has been proposed. In the Resonant Multi-Pulse Ionization injection (ReMPI) a resonant train of pulses drives a large amplitude plasma wave that traps electrons extracted from the plasma by further ionization of a high-Z dopant (Argon in the present paper). While the pulses of the driver train have intensity below the threshold for the dopant's ionization, the properly delayed and frequency doubled (or more) ionization pulse possesses an electric field large enough to extract electrons, though its normalized amplitude is well below unity. In this paper we will report on numerical simulations results aimed at the generation of GeV-scale bunches with normalized emittance and {\it rms} energy below $80\, nm \times rad$ and $0.5\, \%$, respectively. Analytical consideration of the FEL performance for a $1.3\, GeV$ bunch will be also reported.Comment: EAAC 2017 Conference, Elba, Ital

Avaliacoes da infeccao de explantes de feijoeiro por Agrobacterium tumefaciens por meio de microscopia.

Phaseolus vulgaris L. e considerada recalcitrante a transformacao por Agrobacterium tumefaciens. Contudo, alteracoes no meio de co-cultivo, utilizacao de linhagens hipervirulentas de Agrobacterium e de vetores binarios contendo genes vir demostraram que o feijoeiro e susceptivel a essa bacteria. O objetivo do presente trabalho foi estudar o efeito da sonificacao nos tecidos vegetais de feijoeiro, bem como a penetracao da Agrobacterium nas camadas subepidermicas do tecido vegetal, usando a metodologia SAAT ("Sonification-Assisted Agrobacterium-mediated Transformation"). A variedade de feijoeiro utilizada foi a Olathe Pinto, a linhagem de A. tumefaciens foi LBA4404:pTOK.Os embrioes de feijao foram pre-tratados po 14 dias em meio de multibrotacao e, entao submetidos a sonificacao (de 0 ou 60 segundos) na presenca de Agrobacterium. Apos a inoculacao foram co-cultivados por 24 horas em meio liquido seguido de 48 horas em meio solido, ambos, contendo 20 m. L -1 de acetoceringona. Os explantes inoculados foram fixadas em solucao de Karnovsk para avaliacoes em microscopia optica e eletronica de varredura. As analises da microspia demostraram a presenca de rupturas na epiderme, quebras da parede celular e invasao da Agrobacterium nos tecidos subepidermicos. Os reultados demostraram que o metodo SAAT e uma tecnica viavel para a inoculcao de Agrobacterium em explantes de P. vulgaris.bitstream/CPAC-2010/23710/1/bolpd-04.pd

Acceleration with Self-Injection for an All-Optical Radiation Source at LNF

We discuss a new compact gamma-ray source aiming at high spectral density, up to two orders of magnitude higher than currently available bremsstrahlung sources, and conceptually similar to Compton Sources based on conventional linear accelerators. This new source exploits electron bunches from laser-driven electron acceleration in the so-called self-injection scheme and uses a counter-propagating laser pulse to obtain X and gamma-ray emission via Thomson/Compton scattering. The proposed experimental configuration inherently provides a unique test-bed for studies of fundamental open issues of electrodynamics. In view of this, a preliminary discussion of recent results on self-injection with the FLAME laser is also given.Comment: 8 pages, 10 figures, 44 references - Channeling 2012 conferenc