High-Density Dynamics of Laser Wakefield Acceleration from Gas Plasmas to Nanotubes

Nicks, Bradley Scott; Barraza-Valdez, Ernesto; Hakimi, Sahel; Chesnut, Kyle; DeGrandchamp, Genevieve; Gage, K.; Housley, David; Huxtable, Gregory; Lawler, Gerard; Lin, Daniel; Manwani, Pratik; Nelson, Eric R.; Player, Gabriel; Seggebruch, M.; Sweeney, J.; Tanner, Joshua; Thompson, Kurt; Tajima, T.

doi:10.3390/photonics8060216

Cited by 7 publications

(17 citation statements)

References 46 publications

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“…However, when 𝑛𝑛 𝑒𝑒 is approaches the critical density, additional physics must come into play. Nicks et al showed electron energy scaling with respect to laser intensity (1 > 𝑎𝑎 0 ≥ 0.1) for 0.1𝑛𝑛 𝑐𝑐𝑐𝑐𝑖𝑖𝑐𝑐 and 0.3𝑛𝑛 𝑐𝑐𝑐𝑐𝑖𝑖𝑐𝑐 in their Figure 5a,b [7]. Nicks et al also showed that a somewhat discontinuous maximum energy gain of electrons as a function of 𝑎𝑎 0 (around 1) is observed.…”

Section: Near-critical Density Bwamentioning

confidence: 93%

“…As mentioned above, it is conventional wisdom that the maximum electron acceleration energy achieved using laser wakefield schemes is proportional to �𝜔𝜔 0 𝜔𝜔 𝑝𝑝 ⁄ � 2 (due to the relativistic dynamics in underdense plasma). For this reason, we sought to see the limitations of the BWA with respect to density, similar to what was done by Nicks et al [7]. We ran eight BWA simulations like those shown in Figure 2, with a pump and seed intensity given by 𝑎𝑎 0 , 𝑎𝑎 1 = 0.1 and Gaussian pulse width of 100 fs, just below the nonrelativistic regime.…”

Section: Underdense Lwfa and Bwamentioning

confidence: 99%

“…Valenta et al determined that electron densities of roughly 0.1n c were necessary for high repetition rate, low energy, and short pulse lasers [6]. More recently, Nicks et al further explored how one can achieve bulk acceleration of electrons by exploring the maximum energy achieved for different near-critical densities, laser intensities, and laser pulse widths [4,7]. We note that in the nearcritical densities the gas plasma is replaced by other materials such as nanomaterials [8].…”

Section: Introductionmentioning

confidence: 99%

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Laser Beat-Wave Acceleration near Critical Density

et al. 2022

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We consider high-density laser wakefield acceleration (LWFA) in the nonrelativistic regime of the laser. In place of an ultrashort laser pulse, we can excite wakefields via the Laser Beat Wave (BW) that accesses this near-critical density regime. Here, we use 1D Particle-in-Cell (PIC) simulations to study BW acceleration using two co-propagating lasers in a near-critical density material. We show that BW acceleration near the critical density allows for acceleration of electrons to greater than keV energies at far smaller intensities, such as 1014 W/cm2, through the low phase velocity dynamics of wakefields that are excited in this scheme. Near-critical density laser BW acceleration has many potential applications including high-dose radiation therapy.

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Section: Near-critical Density Bwamentioning

confidence: 93%

Section: Underdense Lwfa and Bwamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Laser Beat-Wave Acceleration near Critical Density

et al. 2022

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“…For more details see Ref. [68]. The current state-of-the-art of the RF techniques is limited to gradients on the order of 100 MV/m.…”

Section: Solid-state Plasma By Electron Field Emissionmentioning

confidence: 99%

“…For example, recent theoretical and numerical studies have shown the feasibility of obtaining tens of TV/m fields in nanomaterials by excitation of non-linear plasmonic modes driven by a high density sub-micron particle bunch [62,63]. To obtain multi-TV/m fields other techniques rely on the ablation of solids [67] or the induced electron field emission from nanomaterials [68].…”

Section: Solid-state Plasma By Electron Field Emissionmentioning

confidence: 99%

Long-term future particle accelerators

Resta-López¹

2022

Preprint

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Particle accelerators have enabled forefront research in high energy physics and other research areas for more than half a century. Accelerators have directly contributed to 26 Nobel Prizes in Physics since 1939 as well as another 20 Nobel Prizes in Chemistry, Medicine and Physics with X-rays. Although high energy physics has been the main driving force for the development of the particle accelerators, accelerator facilities have continually been expanding applications in many areas of research and technology. For instance, active areas of accelerator applications include radiotherapy to treat cancer, production of short-lived medical isotopes, synchrotron light sources, free-electron lasers, beam lithography for microcircuits, thin-film technology and radiation processing of food. Currently, the largest and most powerful accelerator is the Large Hadron Collider (LHC) at CERN, which accelerates protons to multi-TeV energies in a 27 km high-vacuum ring. To go beyond the maximum capabilities of the LHC, the next generation of circular and linear particle colliders under consideration, based on radiofrequency acceleration, will require multi-billion investment, kilometric infrastructure and a massive power consumption. These factors pose serious challenges in an increasingly resource-limited world. Therefore, it is important to look for alternative and sustainable acceleration techniques. This review article pays special attention to novel accelerator techniques to overcome present acceleration limitations towards more compact and cost-effective long term future accelerators. KeywordsHigh energy collider • Plasma wakefield • Dielectric accelerator • Solid-state plasma • Plasmonic accelerator * The author acknowledges support by the Generalitat Valenciana under Grant agreement No. CIDEGENT/2019/058.

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