Abstract: Semiconductor structures, devices, and methods that can exhibit various enhanced properties, such as, for example, enhanced light detection properties are provided. In one aspect, for example, an optoelectronic device can include a semiconductor material having an enhanced absorption region and a first defect in the enhanced absorption region, where the first defect is a deep-level defect generated by a first defect carrier type that is either a deep-level donor carrier type or a deep-level acceptor carrier type. The device can also include a second defect in the enhanced absorption region, where the second defect is either a shallow-level defect or a deep-level defect, and where the second defect is generated by a second defect carrier type that is opposite to the first defect carrier type. Furthermore, the enhanced absorption region has an external quantum efficiency of at least about 0.5% for electromagnetic radiation wavelengths greater than 1250 nm.

Abstract: Photovoltaic semiconductor devices and associated methods are provided. In one aspect, for example, a method of making a photovoltaic semiconductor device having enhanced electromagnetic radiation absorption can include applying a damage removal etch (DRE) to a semiconductor material to an RMS surface roughness of from about 0.5 nm to about 50 nm and texturing a single side of the semiconductor material. The texturing further includes irradiating a target region of the semiconductor material with laser radiation to create features having a size of from about 50 nm to about 10 microns.

Abstract: A light-sensing pixel for detecting at least a portion of the electromagnetic spectrum includes a first detector element having a micro-structured surface for detecting an infrared range of wavelengths of the electromagnetic spectrum. The light-sensing pixel further includes a second detector element for detecting a second range of wavelengths of the electromagnetic spectrum, wherein the second range of wavelengths is shorter than the first range of wavelengths and the first and second detector element are formed monolithically on a silicon substrate.

Abstract: Light emitting devices having a textured light emission surface and methods are disclosed. A light emitting device can include a semiconductor substrate having a light emission surface, a semiconductive junction and a textured region formed via laser irradiation on the light emission surface. During us of the light emitting device, light generated by the semiconductive junction can primarily emit through the light emission surface having the textured region.

Abstract: The present disclosure provides systems and methods for configuring and constructing a single photo detector or array of photo detectors with all fabrications circuitry on a single side of the device. Both the anode and the cathode contacts of the diode are placed on a single side, while a layer of laser treated semiconductor is placed on the opposite side for enhanced cost-effectiveness, photon detection, and fill factor.

Abstract: Methods, systems, and devices associated with surface modifying a semiconductor material are taught. One such method includes providing a semiconductor material having a target region and providing a dopant fluid layer that is adjacent to the target region of the semiconductor material, where the dopant fluid layer includes at least one dopant. The target region of the semiconductor material is lased so as to incorporate the dopant or to surface modify the semiconductor material. During the surface modification, the dopant in the dopant fluid layer is actively replenished.

Abstract: High speed optoelectronic devices and associated methods are provided. In one aspect, for example, a high speed optoelectronic device can include a silicon material having an incident light surface, a first doped region and a second doped region forming a semiconductive junction in the silicon material, and a textured region coupled to the silicon material and positioned to interact with electromagnetic radiation. The optoelectronic device has a response time of from about 1 picosecond to about 5 nanoseconds and a responsivity of greater than or equal to about 0.4 A/W for electromagnetic radiation having at least one wavelength from about 800 nm to about 1200 nm.

Abstract: A method for making a semiconductor device includes providing a semiconductor material and doping at least a portion of the semiconductor material to form at least one doped region. A portion of the semiconductor material is removed with a pulsed laser from at least one first region to form at least one adjacent second region.

Abstract: Photosensitive semiconductor devices and associated methods are provided. In one aspect, a semiconductor device can include a semiconductor substrate and a semiconductor layer coupled to the semiconductor substrate, where the semiconductor layer has a device surface opposite the semiconductor substrate. The device also includes at least one textured region coupled between the semiconductor substrate and the semiconductor layer. In another aspect, the device further includes at least one dielectric layer coupled between the semiconductor substrate and the semiconductor layer.

Abstract: An apparatus for detecting radiation of a plurality of wavelengths of the electromagnetic spectrum may be provided. The apparatus includes a substrate, a laser irradiated layer proximal to a first side of the substrate, and a microbolometer and at least one readout circuit proximal to a second side of the substrate in electrical communication with the laser irradiated layer. The substrate, laser irradiated layer, and the microbolometer are disposed and arranged such that radiation of a first wavelength is substantially detected by the laser irradiated layer, and radiation of a second wavelength is substantially detected by the microbolometer.

Abstract: A light-sensing pixel for detecting at least a portion of the electromagnetic spectrum includes a first detector element having a micro-structured surface for detecting an infrared range of wavelengths of the electromagnetic spectrum. The light-sensing pixel further includes a second detector element for detecting a second range of wavelengths of the electromagnetic spectrum, wherein the second range of wavelengths is shorter than the first range of wavelengths and the first and second detector element are formed monolithically on a silicon substrate.

Abstract: Optoelectronic devices having enhanced conversion efficiencies and associated methods are provided. In one aspect, for example, a method of making an optoelectronic device can include applying an absorption layer onto a support substrate, the absorption layer including a material such as CIGS, CIG, CI, CZT, CdTe, and combinations thereof. Additional steps include providing a element-rich environment in proximity to the absorption layer, and irradiating at least a portion of the absorption layer with laser radiation through the element-rich environment thereby incorporating the element into the absorption layer.

Abstract: Backside illuminated photosensitive devices and associated methods are provided. In one aspect, for example, a backside-illuminated photosensitive imager device can include a semiconductor substrate having multiple doped regions forming a least one junction, a textured region coupled to the semiconductor substrate and positioned to interact with electromagnetic radiation, and a passivation region positioned between the textured region and the at least one junction. The passivation region is positioned to isolate the at least one junction from the textured region, and the semiconductor substrate and the textured region are positioned such that incoming electromagnetic radiation passes through the semiconductor substrate before contacting the textured region. Additionally, the device includes an electrical transfer element coupled to the semiconductor substrate to transfer an electrical signal from the at least one junction.

Abstract: A light-sensing pixel is described that includes more than one detector element, each of which is sensitive to a range of wavelengths of the electromagnetic spectrums. The detectors are arranged in a readout circuit that can be constructed on a monolithic semiconductor product such that one or more of the detectors can be switched on or off to include or exclude an output contribution from said detectors and enhance the response of the pixel. Also, the detectors can included a laser-treated semiconductor sensor for efficient sensing of radiation in one or more regions of the spectrum. Arrays and imaging products using such pixels are disclosed.

Abstract: A pixel for detecting at least a portion of the electromagnetic spectrum may be provided. The pixel includes a detector element for detecting at least a portion of the electromagnetic spectrum, a bias point coupled to an output of the detector element for applying a biasing voltage to the detector element and capable of affecting the electrical output of the first detector element, an interface-trap charge pump coupled to the output of the bias point for charge pumping current from the detector, a collection point coupled to the output of the bias point for accumulating an electrical output of the detector element, and an output point for providing an electrical output of the pixel.

Abstract: The present disclosure relates to methods of treating a silicon substrate with an ultra-fast laser to create a getter material for example in a substantially enclosed MEMS package. In an embodiment, the laser treating comprises irradiating the silicon surface with a plurality of laser pulses adding gettering microstructure to the treated surface. Semiconductor based packaged devices, e.g. MEMS, are given as examples hereof.

Abstract: The present disclosure provides systems and methods for configuring and constructing a single photo detector or array of photo detectors with all fabrications circuitry on a single side of the device. Both the anode and the cathode contacts of the diode are placed on a single side, while a layer of laser treated semiconductor is placed on the opposite side for enhanced cost-effectiveness, photon detection, and fill factor.

Abstract: A detector incorporating a laser-doped element that is favorably absorbing to at least a portion of the electromagnetic spectrum, for example in the infra-red range, is used in a light detector article. Readout circuits permitting a detector to operate in a substantial range of the electromagnetic spectrum, including the visual and infra-red range, enable day and night imaging in some embodiments. Configurations for making the detectors are also provided.

Abstract: A device with increased photo-sensitivity using laser treated semiconductor as detection material is disclosed. In some embodiments, the laser treated semiconductor may be placed between and an n-type and a p-type contact or two Schottky metals. The field within the p-n junction or the Schottky metal junction may aid in depleting the laser treated semiconductor section and may be capable of separating electron hole pairs. Multiple device configurations are presented, including lateral and vertical configurations.

Abstract: A device with increased photo-sensitivity using laser treated semiconductor as detection material is disclosed. In some embodiments, the laser treated semiconductor may be placed between and an n-type and a p-type contact or two Schottky metals. The field within the p-n junction or the Schottky metal junction may aid in depleting the laser treated semiconductor section and may be capable of separating electron hole pairs. Multiple device configurations are presented, including lateral and vertical configurations.