Abstract: A diode-laser-based active transducer integrated on a heat-assisted magnetic recording head includes a diode laser structure, as a laser source, and a waveguide-transducer integrated with the laser structure as an intracavity element. Being a part of the laser cavity, the waveguide-transducer very efficiently delivers and couples the high-intensity intracavity laser light to a plasmonic antenna/transducer that concentrates the delivered near-field light to an optical spot of subwavelength nano-size volume to locally heat the surface of the magnetic recording medium.

Abstract: A new semiconductor-laser-integrated Atomic Force Microscopy (AFM) optical probe integrates a semiconductor laser and a silicon cantilever AFM probe into a robust easy-to-use chip to enable AFM measurements, optical imaging, and spectroscopy at the nanoscale.

Abstract: A semiconductor device comprising a waveguide having a core, said core having inserted therein one or more layers of nanoemitters.

Abstract: The present invention provides one or more injection-lockable whistle-geometry semiconductor ring lasers, which may be cascaded, that are integrated on a common silicon-on-insulator (SOI) substrate with a single-frequency semiconductor master laser, wherein the light output from the semiconductor master laser is used to injection-lock the first of the semiconductor ring lasers. The ring lasers can be operated in strongly injection-locked mode, while at least one of them is subjected to direct injection current modulation.

Abstract: A new monolithic Atomic Force Microscopy (AFM) active optical probe monolithically integrates a base of the probe, a cantilever, a semiconductor laser source, an AFM tip, and a photodetector into a robust, easy-to-use single semiconductor chip to enable AFM measurements, optical imaging, and optical spectroscopy at the nanoscale.

Abstract: The present invention provides one or more injection-lockable whistle-geometry semiconductor ring lasers, which may be cascaded, that are integrated on a common silicon-on-insulator (SOI) substrate with a single-frequency semiconductor master laser, wherein the light output from the semiconductor master laser is used to injection-lock the first of the semiconductor ring lasers. The ring lasers can be operated in strongly injection-locked mode, while at least one of them is subjected to direct injection current modulation.

Abstract: A method for generating single optical pulses of picosecond-range duration with suppressed transient emission tails.

Abstract: A light-emitting device having a self-cooled semiconductor laser having a laser cavity.

Abstract: A semiconductor device comprising a waveguide having a core, said core having inserted therein one or more layers of nanoemitters.

Abstract: A new resonant-cavity-enhanced Atomic Force Microscopy (AFM) active optical probe integrates a semiconductor laser source and an aperture AFM/near-field scanning optical microscopy (NSOM) probe in either external-resonant-cavity or internal-resonant-cavity configuration to enable both conventional AFM measurements and optical imaging and spectroscopy at the nanoscale.

Abstract: A heterogeneous scintillator material is provided comprising core/shell nanoparticles having a highly hygroscopic or deliquescent halide-based core activated with trivalent Ln3+ or divalent Ln2+ lanthanide ions (Ln=La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu) and a stable non-hygroscopic shell thereon. The heterogeneous nanoparticles can comprise highly hygroscopic lanthanide halide (LaBr3, LuI3) cores protected with stable non-hygroscopic LaF3 shells. The heterogeneous nanoparticles can comprise deliquescent alkaline earth halide (SrI2, BaI2) cores protected with stable non-hygroscopic (SrF2, BaF2) shells.

Abstract: A new active optical Atomic Force Microscopy (AFM) probe integrating monolithically a semiconductor laser source, an AFM tip, and a photodetector into a robust, easy-to use single semiconductor chip to enable both conventional AFM measurements and optical imaging and spectroscopy at the nanoscale.

Abstract: A thermal neutron detector and method employ Gd-containing nanoscintillators. Thermal neutron radiation is detected by observing scintillation events from the nanoscintillators.

Abstract: The invention provides a semiconductor light-emitting device having a monolithically integrated master laser, such as a distributed-Bragg-reflector (DBR) master laser, and injection-locked ring slave laser with modulated photon lifetime for optical communication beyond 100 GHz.

Abstract: The invention provides a semiconductor light-emitting device having a monolithically integrated master laser, such as a distributed-Bragg-reflector (DBR) master laser, and injection-locked ring slave laser with modulated photon lifetime for optical communication beyond 100 GHz.

Abstract: A neutron irradiation history sensor and detection method for detection of thermal neutrons exploit transmutation of 164Dy into 165Ho and 166Er and significant differences in optical properties of Dy, Ho, and Er in order to enable detection of relative fractions of Dy, Ho, and Er and thus the degree and timing of prior thermal neutron exposure that has occurred, providing a tamper-proof forensic record of the prior thermal neutron exposure. The irradiation history sensor and detection method advantageously employ Dy-containing nanocrytals (NCs) residing in a transparent host.

Abstract: A neutron irradiation history sensor and detection method for detection of thermal neutrons exploit transmutation of 164Dy into 165Ho and 166Er and significant differences in optical properties of Dy, Ho, and Er in order to enable detection of relative fractions of Dy, Ho, and Er and thus the degree and timing of prior thermal neutron exposure that has occurred, providing a tamper-proof forensic record of the prior thermal neutron exposure. The irradiation history sensor and detection method advantageously employ Dy-containing nanocrytals (NCs) residing in a transparent host.

Abstract: A heterogeneous scintillator material is provided comprising core/shell nanoparticles having a highly hygroscopic or deliquescent halide-based core activated with trivalent Ln3+ or divalent Ln2+ lanthanide ions (Ln=La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu) and a stable non-hygroscopic shell thereon. The heterogeneous nanoparticles can comprise highly hygroscopic lanthanide halide (LaBr3, LuI3) cores protected with stable non-hygroscopic LaF3 shells. The heterogeneous nanoparticles can comprise deliquescent alkaline earth halide (SrI2, BaI2) cores protected with stable non-hygroscopic (SrF2, BaF2) shells.

Abstract: Scintillator material comprising nanoparticles (nanocrystals) comprising lead (Pb), iodine (I), and optionally one or both of oxygen (O) and hydrogen (H) wherein the nanoparticles exhibit room-temperature scintillation under gamma irradiation. The scintillator nanoparticles can comprise Pb3O2I2. The scintillator nanoparticles can comprise PbIOH in generally equiatomic proportions or non-equiatomic variants thereof that exhibit scintillation under gamma irradiation. The scintillator nanoparticles have a particle dimension in the range of about 5 to about 100 nm. Microparticles (microcrystals) also are provided comprising lead (Pb), iodine (I), and optionally one or both of oxygen (O) and hydrogen (H) grown in a nanoparticle colloidal solution over time to a particle dimension greater than 0.1 ?m, such as about 2 microns.

Abstract: A thermal neutron detector and method employ Gd-containing nanoscintillators. Thermal neutron radiation is detected by observing scintillation events from the nanoscintillators.