Boosting laser-ion acceleration with multi-picosecond pulses

Yogo, Akifumi; Mima, K.; Iwata, N.; Tosaki, S.; Morace, A.; Arikawa, Yasunobu; Fujioka, Shinsuke; Johzaki, Tomoyuki; Sentoku, Y.; Nishimura, Hiroaki; Sagisaka, A.; Matsuo, Kazuki; Kamitsukasa, N.; Kojima, Sadaoki; Nagatomo, Hideo; Nakai, M.; Shiraga, H.; Murakami, M.; Tokita, Shigeki; Kawanaka, Junji; Miyanaga, Noriaki; Yamanoi, Kohei; Norimatsu, T.; Sakagami, Hiroyuki; Bulanov, S. V.; Kondo, Kotaro; Azechi, H.

doi:10.1038/srep42451

Cited by 87 publications

(63 citation statements)

References 58 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Firstly, when the laser pulse duration is extended to more than 1 ps, such as τ=3 ps, we see from the dashed green line in figure 7(d) that the stable CSA in our scheme can even produce high-flux high-energy proton beams with the peaked energy > 100 MeV and the particle number > 10 12 , which have many applications in high-energy-density science, medicine as well as neutron production. This higher ion energy is achieved due to the significantly increase of laser accelerated/heated electron temperature with longer laser pulse duration, which has been found and identified in [55,56]. In other words, even though at the same laser intensity a 0 , with longer pulse duration, the ion acoustic velocity increases so that shock velocity becomes larger and eventually a higher ion energy is obtained, which has also been discussed in theory [27].…”

Section: Robustness Of the Proposed Schemementioning

confidence: 65%

High-flux high-energy ion beam production from stable collisionless shock acceleration by intense petawatt-picosecond laser pulses

Qiao

Shen

et al. 2019

New J. Phys.

View full text Add to dashboard Cite

A scheme to achieve stable collisionless shock acceleration (CSA) of ions from a near-critical plasma by intense petawatt-picosecond laser pulses is proposed, where the plasma is confined in a high-Z solid tube. The application of the tube, on the one hand, restrains the plasma from transverse thermal expansion, helping to sustain sufficient density steepening required for shock formation and maintenance; on the other hand, due to the induced sheath field along its wall, pinches hot electrons for recirculation near laser axis, aiding to reach efficient plasma heating that is crucial to have a strong shock velocity for ion reflection. Consequently, stable ion CSA can be maintained for picosecond time scales, resulting in production of high-flux high-energy ion beams. Two-dimensional PIC simulations show that proton beams with narrow energy spread between 50 and 80 MeV and high flux with particle number about 10 12 are produced by a laser pulse at intensity 8.8×10 19 W cm −2 and duration 1 ps. By extending the pulse duration to 3 ps, over 100 MeV high-flux proton beams are obtained.

show abstract

Section: Robustness Of the Proposed Schemementioning

confidence: 65%

High-flux high-energy ion beam production from stable collisionless shock acceleration by intense petawatt-picosecond laser pulses

Qiao

Shen

et al. 2019

New J. Phys.

View full text Add to dashboard Cite

show abstract

“…Proton spectra from the highest intensity shots at each pulse duration are shown in figure 3. Taking into account that RCF ion spectrometry is less sensitive than other techniques, such as Thomson Parabola spectroscopy used in [28] and [29], these measurements likely underestimate the cutoff proton energy. Batch-to-batch variations in the sensitivity of the film give rise to a 20%-30% absolute error in determining proton number [43].…”

Section: Resultsmentioning

confidence: 99%

“…Simulations suggest that the multipicosecond interaction will heat plasma electrons beyond the ponderomotive potential of the laser [24][25][26][27]. Indeed, recent experimental results have confirmed that these high energy, multipicosecond laser systems accelerate ions to maximum energies beyond those predicted by traditionally cited scaling laws [28][29][30].…”

Section: Introductionmentioning

confidence: 85%

Proton beam emittance growth in multipicosecond laser-solid interactions

et al. 2019

View full text Add to dashboard Cite

High intensity laser-solid interactions can accelerate high energy, low emittance proton beams via the target normal sheath acceleration (TNSA) mechanism. Such beams are useful for a number of applications, including time-resolved proton radiography for basic plasma and high energy density physics studies. In experiments using the OMEGA EP laser system, we perform the first measurements of TNSA proton beams generated by up to 100 ps, kilojoule-class laser pulses with relativistic intensities. By systematically varying the laser pulse duration, we measure degradation of the accelerated proton beam quality as the pulse length increases. Two dimensional particle-in-cell simulations and simple scaling arguments suggest that ion motion during the rise time of the longer pulses leads to extended preformed plasma expansion from the rear target surface and strong filamentary field structures which can deflect ions away from uniform trajectories and therefore lead to large emittance growth.

show abstract

“…In addition, 1D simulations have been performed by considering the planar plasma expansion in quasi one dimension. 16 In the simulations, recirculating hot electrons have been observed on time scales longer than the incident laser pulse duration. The dynamics of the recirculating hot electrons are more likely responsible for the modulations seen on the time-integrated raw traces of C 1þ ions.…”

Section: Introductionmentioning

confidence: 99%