All-Optical GeV Electron Bunch Generation in a Laser-Plasma Accelerator via Truncated-Channel Injection

We describe a simple scheme, truncated-channel injection, to inject electrons directly into the wakefield driven by a high-intensity laser pulse guided in an all-optical plasma channel. We use this approach to generate dark-current-free 1.2 GeV, 4.5% relative energy spread electron bunches with 120 TW laser pulses guided in a 110 mm-long hydrodynamic optical-field-ionized plasma channel. Our experiments and particle-in-cell simulations show that high-quality electron bunches were only obtained when the drive pulse was closely aligned with the channel axis, and was focused close to the density down ramp formed at the channel entrance. Start-to-end simulations of the channel formation, and electron injection and acceleration show that increasing the channel length to 410 mm would yield 3.65 GeV bunches, with a slice energy spread ∼5×10^{-4}.

Phase front retrieval and correction of Bessel beams

Bessel beams generated with non-ideal axicons are affected by aberrations. We introduce a method to retrieve the complex amplitude of a Bessel beam from intensity measurements alone, and then use this information to correct the wavefront and intensity profile using a deformable mirror.

Optical Guiding in Meter-Scale Plasma Waveguides

We demonstrate a new highly tunable technique for generating meter-scale low density plasma waveguides. Such guides can enable laser-driven electron acceleration to tens of GeV in a single stage. Plasma waveguides are imprinted in hydrogen gas by optical field ionization induced by two time-separated Bessel beam pulses: The first pulse, a J_{0} beam, generates the core of the waveguide, while the delayed second pulse, here a J_{8} or J_{16} beam, generates the waveguide cladding, enabling wide control of the guide's density, depth, and mode confinement. We demonstrate guiding of intense laser pulses over hundreds of Rayleigh lengths with on-axis plasma densities as low as N_{e0}∼5×10^{16}  cm^{-3}.

MeV electron acceleration at 1 kHz with <10 mJ laser pulses: erratum

In this erratum the funding section of Opt. Lett.42, 215 (2017)OPLEDP0146-959210.1364/OL.42.000215 has been updated.

Laser wakefield acceleration with mid-IR laser pulses

We report on, to the best of our knowledge, the first results of laser plasma wakefield acceleration driven by ultrashort mid-infrared (IR) laser pulses (λ=3.9  μm, 100 fs, 0.25 TW), which enable near- and above-critical density interactions with moderate-density gas jets. Relativistic electron acceleration up to ∼12  MeV occurs when the jet width exceeds the threshold scale length for relativistic self-focusing. We present scaling trends in the accelerated beam profiles, charge, and spectra, which are supported by particle-in-cell simulations and time-resolved images of the interaction. For similarly scaled conditions, we observe significant increases in the accelerated charge, compared to previous experiments with near-infrared (λ=800  nm) pulses.

MeV electron acceleration at 1 kHz with <10 mJ laser pulses

We demonstrate laser-driven acceleration of electrons to MeV-scale energies at 1 kHz repetition rate using <10  mJ pulses focused on near-critical density He and H₂ gas jets. Using the H₂ gas jet, electron acceleration to ∼0.5  MeV in ∼10  fC bunches was observed with laser pulse energy as low as 1.3 mJ. Increasing the pulse energy to 10 mJ, we measure ∼1  pC charge bunches with >1  MeV energy for both He and H₂ gas jets.

Generation of axially modulated plasma waveguides using a spatial light modulator

We demonstrate the generation of axially modulated plasma waveguides using spatially patterned high-energy laser pulses. A spatial light modulator (SLM) imposes transverse phase front modulations on a low-energy (10 mJ) laser pulse which is interferometrically combined with a high-energy (130-450 mJ) pulse, sculpting its intensity profile. This enables dynamic and programmable shaping of the laser profile limited only by the resolution of the SLM and the intensity ratio of the two pulses. The plasma density profile formed by focusing the patterned pulse with an axicon lens is likewise dynamic and programmable. Centimeter-scale, axially modulated plasmas of varying shape and periodicity are demonstrated.

Multi-MeV Electron Acceleration by Subterawatt Laser Pulses

We demonstrate laser-plasma acceleration of high charge electron beams to the ∼10  MeV scale using ultrashort laser pulses with as little energy as 10 mJ. This result is made possible by an extremely dense and thin hydrogen gas jet. Total charge up to ∼0.5  nC is measured for energies >1  MeV. Acceleration is correlated to the presence of a relativistically self-focused laser filament accompanied by an intense coherent broadband light flash, associated with wave breaking, which can radiate more than ∼3% of the laser energy in a ∼1  fs bandwidth consistent with half-cycle optical emission. Our results enable truly portable applications of laser-driven acceleration, such as low dose radiography, ultrafast probing of matter, and isotope production.

Mutation screening of the dopamine D1 receptor gene in Tourette's syndrome and alcohol dependent patients

We report a single stranded conformational polymorphism (SSCP) analysis of the coding region of the dopamine D1 receptor (DRD1) in Tourette's syndrome (n = 50) and control (n = 50) subjects. Tourette's syndrome populations with comorbidity for attention deficit-hyperactivity disorder (AD-HD) (n = 35) and obsessive compulsive disorder (OCD) (n = 30) were also screened. As a related study, we also screened patients diagnosed with alcohol dependence (n = 72). The present study discovered no DRD1 coding region mutations in any of the Tourette's syndrome or alcohol dependent patients. One silent mutation, a C for a T at Ile49, was discovered in one control subject. The non-polymorphic structure of the DRD1 gene among the Tourette's syndrome, Tourette's syndrome comorbid with AD-HD and OCD and the alcohol dependent populations screened by SSCP suggests that coding region mutations of the DRD1 gene are unlikely to contribute to the inheritance of these disorders.

Heparin fails to potentiate the effects of IL-1 beta-mediated bone resorption of fetal rat long bones in vitro

Heparin has been identified as a potent modulator of bone resorption. Heparin induces osteoporosis during long-term administration and has been shown in vitro to enhance the effects of other bone resorbing factors, including parathyroid hormone. In this study, we examined the effects of heparin on the bone-resorbing activity of the inflammatory cytokine IL-1 beta. Resorption was determined by measuring release of previously incorporated 45Ca from fetal rat long bones cultured in medium supplemented with either 0.1% bovine serum albumin or 10% heat-inactivated fetal calf serum. Heparin, in the absence of serum, decreased basal resorption at 4 and 10 units/ml, and slightly increased resorption at 30 units/ml. Heparin had no effect on IL-1 beta-stimulated resorption. In the presence of serum, heparin induced a two-fold increase in resorption alone, however, when cocultured with IL-1 beta, heparin failed to further enhance IL-1 beta-stimulated resorption.

Effects of plasminogen and interleukin-1 beta on bone resorption in vitro

Inflammatory bone resorption, a characteristic feature of periodontal disease and rheumatoid arthritis, appears to be mediated by interleukin-1 beta (IL-1 beta). IL-1 beta has been shown to stimulate a wide range of proteolytic enzymes, including collagenases and plasminogen activators, in particular chondrocytes, synovial cells, and isolated osteoblasts. In this study, we have examined the hypothesis that IL-1 beta may stimulate bone loss by inducing the activity of plasminogen activators (PAs) in bone cultures. The latter would convert plasminogen to plasmin, which in turn can activate precursor procollagenase to collagenase. Active collagenase would then break down the bone collagen matrix. In the present study, release of 45Ca from fetal rat long bones in culture was studied in the presence of plasminogen and IL-1 beta. Plasminogen and IL-1 beta separately enhance resorption of fetal rat long bones in vitro. When plasminogen and IL-1 beta are added together at suboptimal levels, mainly additive effects are observed. The presence of heat-inactivated serum does not alter these results. These data tend to indicate that IL-1 beta is stimulating bone resorption through both PA-dependent and PA-independent pathways.