D. Palla scite author profile

Radiotherapy with very high energy electrons has been investigated for a couple of decades as an effective approach to improve dose distribution compared to conventional photon-based radiotherapy, with the recent intriguing potential of high dose-rate irradiation. Its practical application to treatment has been hindered by the lack of hospital-scale accelerators. High-gradient laser-plasma accelerators (LPA) have been proposed as a possible platform, but no experiments so far have explored the feasibility of a clinical use of this concept. We show the results of an experimental study aimed at assessing dose deposition for deep seated tumours using advanced irradiation schemes with an existing LPA source. Measurements show control of localized dose deposition and modulation, suitable to target a volume at depths in the range from 5 to 10 cm with mm resolution. The dose delivered to the target was up to 1.6 Gy, delivered with few hundreds of shots, limited by secondary components of the LPA accelerator. Measurements suggest that therapeutic doses within localized volumes can already be obtained with existing LPA technology, calling for dedicated pre-clinical studies.

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

Gizzi

Baffigi

Brandi

et al. 2018

Nuclear Instruments and Methods in Physics Research Section A:

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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.

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A New Line for Laser-Driven Light Ions Acceleration and Related TNSA Studies

et al. 2017

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Abstract:In this paper, we present the status of the line for laser-driven light ions acceleration (L3IA) currently under implementation at the Intense Laser Irradiation Laboratory (ILIL), and we provide an overview of the pilot experimental activity on laser-driven ion acceleration carried out in support of the design of the line. A description of the main components is given, including the laser, the beam transport line, the interaction chamber, and the diagnostics. A review of the main results obtained so far during the pilot experimental activity is also reported, including details of the laser-plasma interaction and ion beam characterization. A brief description of the preliminary results of a dedicated numerical modeling is also provided.

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Role of laser contrast and foil thickness in target normal sheath acceleration

Gizzi

Altana

Brandi

et al. 2016

Nuclear Instruments and Methods in Physics Research Section A:

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Intense proton acceleration in ultrarelativistic interaction with nanochannels

Gizzi

Cristoforetti

Baffigi

et al. 2020

Phys. Rev. Research

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We show that both the flux and the cutoff energy of protons accelerated by ultraintense lasers can be simultaneously increased when using targets consisting of thin layers of bundled nanochannels. Particle-in-cell simulations suggest that the propagation of an electromagnetic field in the subwavelength channels occurs via excitation of surface plasmon polaritons that travel in the channels down to the end of the target, sustaining continuous and efficient electron acceleration and boosting acceleration of protons via enhancement of the target normal sheath acceleration mechanism.

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Laser-driven proton acceleration via excitation of surface plasmon polaritons into TiO₂ nanotube array targets

Cristoforetti¹,

Baffigi²,

Brandi³

et al. 2020

Plasma Phys. Control. Fusion

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In this paper we report the measurement of laser-driven proton acceleration obtained by irradiating nanotube array targets with ultrashort laser pulses at an intensity in excess of 1020 W cm−2. The energetic spectra of forward accelerated protons show a larger flux and a higher proton cutoff energy if compared to flat foils of comparable thickness. Particle-In-Cell 2D simulations reveal that packed nanotube targets favour a better laser-plasma coupling and produce an efficient generation of fast electrons moving through the target. Due to their sub-wavelength size, the propagation of e.m. field into the tubes is made possible by the excitation of Surface Plasmon Polaritons, travelling down to the end of the target and assuring a continuous electron acceleration. The higher amount and energy of these electrons result in turn in a stronger electric sheath field on the rear surface of the target and in a more efficient acceleration of the protons via the target normal sheath acceleration mechanism.

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Comparison of self-injection thresholds in He and N2 and role of self-focusing in LWFA

Palla¹,

Baffigi²,

Brandi

et al. 2016

Nuclear Instruments and Methods in Physics Research Section A:

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Investigation of ion acceleration mechanism through laser-matter interaction in femtosecond domain

Altana

Muoio

Lanzalone

et al. 2016

Nuclear Instruments and Methods in Physics Research Section A:

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D. Palla

Toward an effective use of laser-driven very high energy electrons for radiotherapy: Feasibility assessment of multi-field and intensity modulation irradiation schemes

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

A New Line for Laser-Driven Light Ions Acceleration and Related TNSA Studies

Role of laser contrast and foil thickness in target normal sheath acceleration

Intense proton acceleration in ultrarelativistic interaction with nanochannels

Laser-driven proton acceleration via excitation of surface plasmon polaritons into TiO₂ nanotube array targets

Comparison of self-injection thresholds in He and N2 and role of self-focusing in LWFA

Investigation of ion acceleration mechanism through laser-matter interaction in femtosecond domain

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D. Palla

Toward an effective use of laser-driven very high energy electrons for radiotherapy: Feasibility assessment of multi-field and intensity modulation irradiation schemes

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

A New Line for Laser-Driven Light Ions Acceleration and Related TNSA Studies

Role of laser contrast and foil thickness in target normal sheath acceleration

Intense proton acceleration in ultrarelativistic interaction with nanochannels

Laser-driven proton acceleration via excitation of surface plasmon polaritons into TiO2 nanotube array targets

Comparison of self-injection thresholds in He and N2 and role of self-focusing in LWFA

Investigation of ion acceleration mechanism through laser-matter interaction in femtosecond domain

Contact Info

Product

Resources

About

Laser-driven proton acceleration via excitation of surface plasmon polaritons into TiO₂ nanotube array targets