Nonlinear terahertz metamaterials via field-enhanced carrier dynamics in GaAs

We demonstrate nonlinear metamaterial split ring resonators (SRRs) on GaAs at terahertz frequencies. For SRRs on doped GaAs films, incident terahertz radiation with peak fields of ~20 - 160 kV/cm drives intervalley scattering. This reduces the carrier mobility and enhances the SRR LC response due to a conductivity decrease in the doped thin film. Above ~160 kV/cm, electric field enhancement within the SRR gaps leads to efficient impact ionization, increasing the carrier density and the conductivity which, in turn, suppresses the SRR resonance. We demonstrate an increase of up to 10 orders of magnitude in the carrier density in the SRR gaps on semi-insulating GaAs substrate. Furthermore, we show that the effective permittivity can be swept from negative to positive values with increasing terahertz field strength in the impact ionization regime, enabling new possibilities for nonlinear metamaterials.Comment: 5 pages, 4 figure

PT-symmetry in honeycomb photonic lattices

We apply gain/loss to honeycomb photonic lattices and show that the dispersion relation is identical to tachyons - particles with imaginary mass that travel faster than the speed of light. This is accompanied by PT-symmetry breaking in this structure. We further show that the PT-symmetry can be restored by deforming the lattice

New synthetic routes to Triazolo-benzodiazepine analogues:expanding the scope of the bump-and-hole approach for selective Bromo and Extra-Terminal (BET) bromodomain inhibition

We describe new synthetic routes developed toward a range of substituted analogues of bromo and extra-terminal (BET) bromodomain inhibitors I-BET762/JQ1 based on the triazolo-benzodiazepine scaffold. These new routes allow for the derivatization of the methoxyphenyl and chlorophenyl rings, in addition to the diazepine ternary center and the side chain methylene moiety. Substitution at the level of the side chain methylene afforded compounds targeting specifically and potently engineered BET bromodomains designed as part of a bump and hole approach. We further demonstrate that marked selectivity for the second over the first bromodomain can be achieved with an indole derivative that exploits differential interaction with an aspartate/histidine conservative substitution on the BC loop of BET bromodomains

Photonic crystals for nano-light in moir\'e graphene superlattices

Graphene is an atomically thin plasmonic medium that supports highly confined plasmon polaritons, or nano-light, with very low loss. Electronic properties of graphene can be drastically altered when it is laid upon another graphene layer, resulting in a moir\'e superlattice. The relative twist angle between the two layers is a key tuning parameter of the interlayer coupling in thus obtained twisted bilayer graphene (TBG). We studied propagation of plasmon polaritons in TBG by infrared nano-imaging. We discovered that the atomic reconstruction occurring at small twist angles transforms the TBG into a natural plasmon photonic crystal for propagating nano-light. This discovery points to a pathway towards controlling nano-light by exploiting quantum properties of graphene and other atomically layered van der Waals materials eliminating need for arduous top-down nanofabrication

Dynamics of quantum materials at the nanoscale

Programming the properties of quantum materials on demand is a central goal of condensed matter physics with the potential to usher in a new technological era. Photoexcitation has proven to be an exceptionally capable means of resonant and non-resonant control over matter offering coveted routes to selectively control the electronic, lattice, interband or valley optical and excitonic properties of quantum materials. One major limitation of probing the rich class of phenomena enabled by photoexcitation is the diffraction limit. The properties of quantum materials are often sensitive to the microscopic details of the environment at phase transition boundaries: which naturally leads drastic inhomogeneity at the nanoscale. In other cases, the media may transiently support high-momentum “nano-light” or host topologically protected conductive channels that are localized to one-dimensional physical edges. All of these phenomena demand a probe with the spatial resolution that is commensurate with the emergent behavior. To address these demands the author contributed to the development of time-resolved scattering near-field optical microscopy (Tr-SNOM). Utilizing the principles developed as part of this thesis amplified laser technology was combined with a commercial near-field optical microscope to produce a state-of-the-art time-resolved nanoscope. The custom apparatus operates with twenty nanometer spatial resolution with unprecedented spectral coverage spanning visible to mid-infrared all with (30-300) femtosecond temporal resolution. The experimental apparatus was, first, applied to investigate the photo-induced insulator-to-metal transition in Vanadium Dioxide. We observe nanoscale inhomogeneity of the transient conductivity. Our data reveals that local nanoscopic variations of the strain exist in our particular VO2 thin film at equilibrium. Regions of compressive strain are, furthermore, found to correlate with regions where a high degree of transient conductivity is attained. Our systematic study of the local fluence dependence and dynamics reveal that the fluence threshold, Fc, for the monoclinic-insulator to rutile-metal transition is inhomogeneous in real-space. A second growth process is identified, even at excitations fluences well below Fc, which operates on a longer timescale with an inhomogeneous rise time, tau-1. Together Fc and tau-1 govern the inhomogeneous nano-texturing of the transient conductivity. Secondly, we uncover that crystals of van-der Waals (vdW) semiconductors behave as optical waveguides with broadly tunable properties at femto-second time scales. We detect giant optical phase shifts of waveguided photons under strong photo-excitation devoid of any unwanted added losses in the vdW crystal, WSe2. Our results firmly implicate bound excitons in the observed behavior. Our transient spatio-temporal maps reveal two concomitant effects: i) photo-generation of electron-hole plasma that drives the WSe2 crystal towards a Mott transition where excitons dissociate and ii) a coherent interaction between the waveguide material and pump light, known as the optical Stark effect, that alters the phase velocity of guided photons on the femtosecond timescale

Son of Son of Sam: Trashing Popular Media and Criminalizing Crime-Related Expression

When the Supreme Court struck down New York\u27s Son of Sam statute on First Amendment grounds, it nonetheless found that states have an undisputed compelling interest in ensuring that criminals do not profit from their crimes. The Court in effect invited states and lower courts to find less restrictive means to restrict crime-related expression, yet declined to address the question of how, or whether, expression-related income can be considered profit from crime. This Article examines that question, and discusses judicially-imposed restrictions on receipt of payment for expression deemed to be crime-related, including fines intended to forestall sales of stories by indigent criminals and sentencing decisions influenced by defendants\u27 television appearances. In particular, the Article considers the case of former radical activist Katherine Anne Power, who unsuccessfully challenged a probation condition forbidding her from directly or indirectly engaging in benefit generating activity relating to the publication of facts pertaining to her thoughts, feelings, opinions or emotions about her crime or her twenty-three years underground. The author sets the Power case in the context of First Amendment doctrine as it concerns content-based financial disincentives to speech, as well as numerous lower-court opinions in which judges openly express hostility to crime-related expression and the popular media that publish and report such expression. This Article demonstrates that judicial attitudes have improperly influenced the choice and application of legal standards in these cases, resulting in a subset of disfavored speech not otherwise recognized in First Amendment jurisprudence. The author concludes that ample alternatives exist for punishing crime and compensating victims without burdening speech, and that judges have significantly overreached by considering both the content of, and venues for, expressive activity