Abstract: A photodetector structure can include a silicon substrate and a silicon layer on the silicon substrate, that can include a first portion of an optical transmission medium that further includes a silicon cross-sectional transmission face. A germanium layer can be on the silicon substrate and can include a second portion of the optical transmission medium, adjacent to the first portion can include a germanium cross-sectional transmission face butt-coupled to the silicon cross-sectional transmission face.

Abstract: A sensor having a monolithically integrated structure for detecting thermal radiation includes: a carrier substrate, a cavity, and at least one sensor element for detecting thermal radiation. Incident thermal radiation strikes the sensor element via the carrier substrate. The sensor element is suspended in the cavity by a suspension.

Abstract: Provided is a semiconductor light emitting device. The semiconductor light emitting device comprises a substrate, a first semiconductor layer on substrate, an air-gap part disposed in at least portion between the substrate and the first semiconductor layer, and a plurality of compound semiconductor layers comprising a first conductive type semiconductor layer, an active layer, and a second conductive type semiconductor layer on the first semiconductor layer.

Abstract: Provided are multimaterial devices, such as coaxial nanowires, that effect hot photoexcited electron transfer across the interface of the materials. Modulation of the transfer rates, manifested as a large tunability of the voltage onset of negative differential resistance and of voltage-current phase, may be effected by modulating electrostatic gating, incident photon energy, and the incident photon intensity. Dynamic manipulation of this transfer rate permits the introduction and control of an adjustable phase delay within a device element.

Abstract: The present invention is directed to a position sensing detector made of a photodiode having a semi insulating substrate layer; a buffered layer that is formed directly atop the semi-insulating substrate layer, an absorption layer that is formed directly atop the buffered layer substrate layer, a cap layer that is formed directly atop the absorption layer, a plurality of cathode electrodes electrically coupled to the buffered layer or directly to the cap layer, and at least one anode electrode electrically coupled to a p-type region in the cap layer. The position sensing detector has a photo-response non-uniformity of less than 2% and a position detection error of less than 10 ?m across the active area.

Abstract: A method of making a two-dimensional detector array (and of such an array) comprising, for each of a plurality of rows and a plurality of columns of individual detectors, forming an n-doped semiconductor photo absorbing layer, forming a barrier layer comprising one or more of AlSb, AlAsSb, AlGaAsSb, AlSb, AlGaPSb, and HgZnTe, and forming an n-doped semiconductor contact area.

Abstract: A photodetector detects the absence or presence of light by detecting a change in the inductance of a coil. The magnetic field generated when a current flows through the coil passes through an electron-hole generation region. Charged particles in the electron-hole generation region come under the influence of the magnetic field, and generate eddy currents whose magnitudes depend on whether light is absent or present. The eddy currents generate a magnetic field that opposes the magnetic field generated by current flowing through the coil.

Abstract: An electrode structure is provided for use in an electronic device. In certain example embodiments, an electrode structure includes a supporting glass substrate (e.g., soda-lime silica based float glass), a buffer layer (e.g., SixNy), and a conductive electrode (e.g., Mo) provided in this order. The buffer layer is advantageous in that it prevents or reduces sodium (Na) migration from the glass substrate into semiconductor layer(s) of the electronic device.

Abstract: A light-emitting structure includes a p-doped region for injecting holes and an n-doped region for injecting electrons. At least one InGaN quantum well of a first type and at least one InGaN quantum well of a second type are arranged between the n-doped region and the p-doped region. The InGaN quantum well of the second type has a higher indium content than the InGaN quantum well of the first type.

Abstract: A light-absorbing layer is composed of a compound-semiconductor film of chalcopyrite structure, a surface layer is disposed on the light-absorbing layer, the surface layer having a higher band gap energy than the compound-semiconductor film, an upper electrode layer is disposed on the surface layer, and a lower electrode layer is disposed on a backside of the light-absorbing layer in opposition to the upper electrode layer, the upper electrode layer and the lower electrode layer having a reverse bias voltage applied in between to detect electric charges produced by photoelectric conversion in the compound-semiconductor film, as electric charges due to photoelectric conversion are multiplied by impact ionization, while the multiplication by impact ionization of electric charges is induced by application of a high-intensity electric field to a semiconductor of chalcopyrite structure, allowing for an improved dark-current property, and an enhanced efficiency even in detection of low illumination intensities, wit

Abstract: The present disclosure provides an image sensor device that exhibits improved quantum efficiency. For example, a backside illuminated (BSI) image sensor device is provided that includes a substrate having a front surface and a back surface; a light sensing region disposed at the front surface of the substrate; and an antireflective layer disposed over the back surface of the substrate. The antireflective layer has an index of refraction greater than or equal to about 2.2 and an extinction coefficient less than or equal to about 0.05 when measured at a wavelength less than 700 nm.

Abstract: A photodetector is provided, comprising: a radiation-absorbing semiconductor region and a collection semiconductor region separated by and each in contact with a barrier semiconductor region; wherein, at least in the absence of an applied bias voltage, the band gap between the valence band energy and the conduction band energy of the barrier semiconductor region is offset from the band gap between the valence band energy and the conduction band energy of the radiation-absorbing semiconductor region so as to form an energy barrier between the radiation-absorbing semiconductor region and the collection semiconductor region which resists the flow of minority carriers from the radiation-absorbing semiconductor region to the collection semiconductor region. Also provided is a method of manufacturing a photodetector.

Abstract: Provided is a Si—Ge laminated thin film including at least one Si layer and at least one Ge layer, which are alternately laminated on a substrate (1). A Si layer (31) and a Ge layer (22) each have a thickness in a range of 5 to 500 nm. The Si layer (31) is amorphous and only the Ge layer (22) is crystallized. An average crystallite size of Ge in the Ge layer (22) is 20 nm or less.

Abstract: Tensile strained germanium is provided that can be sufficiently strained to provide a nearly direct band gap material or a direct band gap material. Compressively stressed or tensile stressed stressor materials in contact with germanium regions induce uniaxial or biaxial tensile strain in the germanium regions. Stressor materials may include silicon nitride or silicon germanium. The resulting strained germanium structure can be used to emit or detect photons including, for example, generating photons within a resonant cavity to provide a laser.

Abstract: Provided is a biological component detection device with which a biological component can be detected at high sensitivity by using an InP-based photodiode in which a dark current is reduced without using a cooling mechanism and the sensitivity is extended to a wavelength of 1.8 ?m or more. An absorption layer 3 has a multiple quantum well structure composed of group III-V semiconductors, a pn-junction 15 is formed by selectively diffusing an impurity element in the absorption layer, and the concentration of the impurity element in the absorption layer is 5×1016/cm3 or less, the diffusion concentration distribution control layer has an n-type impurity concentration of 2×1015/cm3 or less before the diffusion, the diffusion concentration distribution control layer having a portion adjacent to the absorption layer, the portion having a low impurity concentration.

Abstract: A method of forming a strained, semiconductor-on-insulator substrate includes forming a second semiconductor layer on a first semiconductor substrate. The second semiconductor is lattice matched to the first semiconductor substrate such that the second semiconductor layer is subjected to a first directional stress. An active device semiconductor layer is formed over the second semiconductor layer such that the active device semiconductor layer is initially in a relaxed state. One or more trench isolation structures are formed through the active device layer and through the second semiconductor layer so as to relax the second semiconductor layer below the active device layer and impart a second directional stress on the active device layer opposite the first directional stress.

Abstract: A photoelectric conversion element includes, in the following order: a substrate; a lower electrode containing titanium nitride; an organic layer including a photoelectric conversion layer; and an upper electrode containing a transparent electrode material.

Abstract: A multi junction solar cell having epitaxially-deposited III/V compounds on vicinal group IV substrates and method for making same. The solar cell includes an AlAs nucleating layer on a Ge substrate. The group IV substrate contains a p-n junction whose change of characteristics during epitaxial growth of As-containing layers is minimized by the AlAs nucleating layer. The AlAs nucleating layer provides improved morphology of the solar cell and a means to control the position of a p-n junction near the surface of the group IV substrate through diffusion of As and/or P and near the bottom of the III/V structure through minimized diffusion of the group IV element.

Abstract: An electro-optic device is disclosed. The electro-optic device includes an insulating layer, a first semiconducting region disposed above the insulating layer and being doped with doping atoms of a first conductivity type, a second semiconducting region disposed above the insulating layer and being doped with doping atoms of a second conductivity type and an electro-optic active region disposed above the insulating layer and between the first semiconducting region and the second semiconducting region. The electro-optic active region includes a first partial active region and a second partial active region and an insulating structure in between. The insulating structure extends perpendicular to the surface of the insulating layer such that there is no overlap of the first partial active region and the second partial active region in the direction perpendicular to the surface of the insulating layer. A method for manufacturing is also disclosed.

Abstract: A method of making a two-dimensional detector array (and of such an array) comprising, for each of a plurality of rows and a plurality of columns of individual detectors, forming an n-doped semiconductor photo absorbing layer, forming a barrier layer comprising one or more of AlSb, AlAsSb, AlGaAsSb, AlPSb, AlGaPSb, and HgZnTe, and forming an n-doped semiconductor contact area.

Abstract: A photoactive device is provided. The device includes a first electrode, a second electrode, and a photoactive region disposed between and electrically connected to the first and second electrodes. The photoactive region further includes an organic donor layer and an organic acceptor layer that form a donor-acceptor heterojunction. The mobility of holes in the organic donor region and the mobility of electrons in the organic acceptor region are different by a factor of at least 100, and more preferably a factor of at least 1000. At least one of the mobility of holes in the organic donor region and the mobility of electrons in the organic acceptor region is greater than 0.001 cm2/V-sec, and more preferably greater than 1 cm2/V-sec. The heterojunction may be of various types, including a planar heterojunction, a bulk heterojunction, a mixed heterojunction, and a hybrid planar-mixed heterojunction.

Abstract: Provided is a light-receiving device which has light-receiving sensitivity superior to that of a conventional Schottky diode type light-receiving device and also has sufficiently-strengthened junction of a Schottky electrode. A first contact layer formed of AlGaN and having conductivity, a light-receiving layer formed of AlGaN, and a second contact layer formed of AlN and having a thickness of 5 nm are epitaxially formed on a predetermined substrate in the stated order, and a second electrode is brought into Schottky junction with the second contact layer, to thereby form MIS junction. Further, after the Schottky junction, heat treatment is performed under a nitrogen gas atmosphere at 600° C. for 30 seconds.

Abstract: Two-terminal multi junction photodetectors and focal plane arrays for multi-color detection or imaging acquisition can be formed by connecting photodiodes with different bandgaps or wavelengths, through tunnel diodes, in series with the same polarization. Under reverse bias in the dark, the total current going through such multi junction photodetectors is dictated by the smallest reverse saturation current of the photodiodes. When in operating mode, a set of light sources with different wavelengths corresponding to each individual photodiode can be used to optically bias all the photodiodes except the detecting photodiode Under illumination, all other photodiodes work in the photovoltaic mode and have much higher maximum possible reverse currents than the detecting photodiode. As a result, the total current of the multi junction photodetector is dictated by the detecting photodiode.

Abstract: A process to form a photodiode (PD) with the waveguide structure is disclosed. The PD processes thereby reduces a scattering of the parasitic resistance thereof. The process includes steps to form a PD mesa stripe, to bury the PD mesa stripe by the waveguide region, to etch the PD mesa stripe and the waveguide region to form the waveguide mesa stripe. In the etching, the lower contact layer plays a role of the etching stopper.

Abstract: A semiconductor structure having a transistor and a thermo electronic structure. The transistor has a control electrode for controlling a flow of carriers through a semiconductor layer between a pair of electrodes. The thermo electronic structure has a first portion disposed on at least one of the pair of electrodes and a second portion disposed over a region of the semiconductor layer proximate the control electrode between the control electrode and said at least one of the pair of electrode. The thermo electronic structure extends from the first portion to the second portion for removing heat generated heat from said region in the semiconductor layer.

Abstract: A method of fabricating a frontside-illuminated inverted quantum well infrared photodetector may include providing a quantum well wafer having a bulk substrate layer and a quantum material layer, wherein the quantum material layer includes a plurality of alternating quantum well layers and barrier layers epitaxially grown on the bulk substrate layer. The method further includes applying at least one frontside common electrical contact to a frontside of the quantum well wafer, bonding a transparent substrate to the frontside of the quantum well wafer, thinning the bulk substrate layer of the quantum well wafer, and etching the quantum material layer to form quantum well facets that define at least one pyramidal quantum well stack. A backside electrical contact may be applied to the pyramidal quantum well stack. In one embodiment, a plurality of quantum well stacks is bonded to a read-out integrated circuit of a focal plane array.

Abstract: A backside illuminated (“BSI”) complementary metal-oxide semiconductor (“CMOS”) image sensor includes a photosensitive region disposed within a semiconductor layer and a stress adjusting layer. The photosensitive region is sensitive to light incident on a backside of the BSI CMOS image sensor to collect an image charge. The stress adjusting layer is disposed on a backside of the semiconductor layer to establish a stress characteristic that encourages photo-generated charge carriers to migrate towards the photosensitive region.

Abstract: According to an aspect of the invention, an imaging device includes a plurality of photoelectric conversion elements and a read-out portion. The photoelectric conversion elements are arranged above a substrate. The read-out portion reads out signal corresponding to charges which are generated from each of the photoelectric conversion elements. Each of the photoelectric conversion elements includes a first electrode that collects the charge, a second electrode that is disposed opposite to the first electrode, a photoelectric conversion layer that generates the charges and disposed between the first electrode and the second electrode, and an electron blocking layer that is disposed between the first electrode and the photoelectric conversion layer. Distance between the first electrodes of adjacent photoelectric conversion elements is 250 nm or smaller. Each of the electron blocking layers has a change in surface potential of ?1 to 3 eV from a first face to a second face.

Abstract: A method of fabricating a multi-junction solar cell on a separable substrate, and structure formed thereby are provided. The method comprises establishing a substrate having a semiconductive composition and forming a sacrificial layer upon the substrate. A solar cell portion is formed upon the sacrificial layer, such that the solar cell portion includes a plurality of multi junction layers. A stabilizing cell layer of semiconductor material is then formed on the solar cell portion, with the stabilizing cell layer having a predetermined thickness greater than a thickness of any individual one of the III-V multi junction layers. Etching is thereafter carried out to remove the sacrificial layer for releasing the solar cell portion from the substrate.

Abstract: Embodiments of detectors made using lattice matched photoabsorbing layers are disclosed. A photodiode apparatus in accordance with one or more embodiments of the present invention comprises an indium phosphide substrate, and a photoabsorbing region comprising at least an indium gallium arsenide antimonide nitride (InGaAsSbN) layer, wherein the InGaAsSbN layer has a thickness of at least 100 nanometers and is nominally lattice-matched to the indium phosphide substrate.

Abstract: An optical semiconductor device is disclosed including an active region including an active layer and a diffraction grating having a ?/4 phase shift; passive waveguide regions each including a passive waveguide and a diffraction grating, disposed on the side of an emission facet and on the side of a rear facet sandwiching the active region between the passive waveguide regions, respectively; and an anti-reflection coating applied on the emission facet, wherein the passive waveguide region on the side of the emission facet has a length shorter than a length of the passive waveguide region on the side of the rear facet side.

Abstract: A sensor including an array of light sensitive pixels, each pixel including: at least one hetero-junction phototransistor having a floating base without contact, wherein each phototransistor is a mesa device having active layers exposed at side-walls of the mesa device; and at least one atomic layer deposited high-k dielectric material adjacent to and passivating at least the side-wall exposed active layers.

Abstract: A thin film transistor includes: a gate electrode; a gate insulting film formed on the gate electrode; an oxide semiconductor thin film layer forming a channel region corresponding to the gate electrode on the gate insulating film; a channel protective layer that is formed at least in a region corresponding to the channel region on the gate insulating film and the oxide semiconductor thin film layer, and that includes a first channel protective layer on a lower layer side and a second channel protective layer on an upper layer side; and a source/drain electrode that is formed on the channel protective layer and is electrically connected to the oxide semiconductor thin film layer. The first channel protective layer is made of an oxide insulating material, and one or both of the first channel protective layer and the second channel protective layer is made of a low oxygen permeable material.

Abstract: A terahertz wave radiating element includes: a first nitride semiconductor layer formed on a substrate; a second nitride semiconductor layer formed over the first nitride semiconductor layer, and having a wider bandgap than the first nitride semiconductor layer; and source, gate, and drain electrodes formed on the second nitride semiconductor layer. The source electrode is formed by a plurality of source electrode fingers that are arranged periodically, and the drain electrode is formed by a plurality of drain electrode fingers that are arranged periodically.

Abstract: According to one embodiment, a solid state imaging device includes a photoelectric converting portion including a semiconductor region and a semiconductor film. The semiconductor region has a first region and a second region. The first region is of a second conductivity type. The first region is provided in a semiconductor substrate. The second region is of a first conductivity type. The first conductivity type is a different conductivity type from the second conductivity type. The second region is provided on the first region. The semiconductor film is of the second conductivity type. The semiconductor film is provided on the semiconductor region. An absorption coefficient of a material of the semiconductor film to a visible light is higher than an absorption coefficient of a material of the semiconductor substrate to the visible light. A thickness of the semiconductor film is smaller than a thickness of the semiconductor region.

Abstract: A photodetector is disclosed for the detection of near-infrared light with a wavelength in the range of about 0.9-1.7 microns. The photodetector, which can be formed as either an nBp device or a pBn device on an InP substrate, includes an InGaAs light-absorbing layer, an InAlGaAs graded layer, an InAlAs or InP barrier layer, and an InGaAs contact layer. The photodetector can detect near-infrared light with or without the use of an applied reverse-bias voltage and is useful as an individual photodetector, or to form a focal plane array.

Abstract: A semiconductor photodiode device includes a semiconductor substrate, a first buffer layer containing a material different from that of the semiconductor substrate in a portion thereof, a first semiconductor layer formed above the buffer layer and having a lattice constant different from that of the semiconductor substrate, a second buffer layer formed above the first semiconductor layer and containing an element identical with that of the first semiconductor layer in a portion thereof, and a second semiconductor layer formed above the buffer layer in which a portion of the first semiconductor layer is formed of a plurality of island shape portions each surrounded with an insulating film, and the second buffer layer allows adjacent islands of the first semiconductor layer to coalesce with each other and is in contact with the insulating film.

Abstract: A solar cell comprises a substrate configured to have a plurality of via holes and a first conductive type, an emitter layer placed in the substrate and configured to have a second conductive type opposite to the first conductive type, a plurality of first electrodes electrically coupled to the emitter layer, a plurality of current collectors electrically coupled to the first electrodes through the plurality of via holes, and a plurality of second electrodes electrically coupled to the substrate. The plurality of via holes comprises at least two via holes having different angles.

Abstract: A semiconductor device structure having increased photogenerated current density, and increased current output is disclosed. The device includes low bandgap absorber regions that increase the range of wavelengths at which photogeneration of charge carriers takes place, and for which useful current can be collected. The low bandgap absorber regions may be strain balanced by strain-compensation regions, and the low bandgap absorber regions and strain-compensation regions may be formed from the same ternary semiconductor family. The device may be a solar cell, subcell, or other optoelectronic device with a metamorphic or lattice-mismatched base layer, for which the low bandgap absorber region improves the effective bandgap combination of subcells and current balance within the multijunction cell, for higher efficiency conversion of the solar spectrum.

Abstract: A method of forming a plurality of discrete, interconnected solar cells mounted on a carrier by providing a first semiconductor substrate; depositing on the first substrate a sequence of layers of semiconductor material forming a solar cell structure; forming a metal back contact layer over the solar cell structure; mounting a carrier on top of the metal back contact; removing the first substrate; and lithographically patterning and etching the solar cell structure to form a plurality of discrete solar cells mounted on the carrier.

Abstract: A device separation insulating film and a device separation semiconductor layer are provided for a device separation section for separating adjacent devices from each other, end portions of the device separation insulating film and end portions of the device separation semiconductor layer are provided to overlap each other in order to surround two sides of an outer-periphery of the voltage conversion section and also to surround a channel section of the charge transfer device and the light receiving devices and an end portion of the device separation insulating film facing an end face of the light receiving device is arranged inwardly below a control electrode with respect to an end face of the control electrode on the light receiving device side.

Abstract: A photodetector 1 according to an embodiment of the present invention includes: an n-type InAs substrate 12; an n-type InAs buffer layer 14 formed on the n-type InAs substrate 12; an n-type InAs light absorbing layer 16 formed on the n-type InAs buffer layer 14; an InAsXPYSb1-X-Y cap layer 18 (X?0, Y>0) formed on the n-type InAs light absorbing layer 16; a first inorganic insulating film 20 formed on the cap layer 18, and having an opening portion 20h in a deposition direction; a p-type impurity semiconductor region 24 fowled by diffusing a p-type impurity from the opening portion 20h of the first inorganic insulating film 20, and reaching from the cap layer 18 to an upper layer of the n-type InAs light absorbing layer 16; and a second inorganic insulating film 22 formed on the first inorganic insulating film 20 and on the p-type impurity semiconductor region 24.

Abstract: Systems and methods for improving the temperature performance of AlInGaP based light emitters. Nitrogen is added to the quantum wells in small quantities. Nitrogen is added in a range of about 0.5 percent to 2 percent. The addition of nitrogen increases the conduction band offset and increases the separation of the indirect conduction band. To keep the emission wavelength in a particular range, the concentration of In in the quantum wells may be decreased or the concentration of Al in the quantum wells may be increased. Because the depth of the quantum wells in the valence band is more than is required although the addition of nitrogen reduces the depth of the quantum wells in the valence band. The net result is an increase in the conduction band offset and an increase in the separation of the indirect conduction band.

Abstract: A nitride semiconductor substrate is featured in comprising: a GaN semiconductor layer grown on a base layer, which has a substantially triangular cross-section along the thickness direction thereof, a periodic stripe shapes, and uneven surfaces arranged on the stripes inclined surfaces; and an overgrown layer composed of AlGaN or InAlGaN on the GaN semiconductor layer.

Abstract: A method for forming a thin film photovoltaic device. The method includes providing a transparent substrate comprising a surface region. A first electrode layer is formed overlying the surface region. A copper layer is formed overlying the first electrode layer and an indium layer is formed overlying the copper layer to form a multi-layered structure. The method subjects at least the multi-layered structure to a thermal treatment process in an environment containing a sulfur bearing species to form a bulk copper indium disulfide material. The bulk copper indium disulfide material comprises one or more portions of copper indium disulfide material and a surface region characterized by a copper poor surface having a copper-to-indium atomic ratio of less than about 0.95:1.

Abstract: The present invention aims to provide a semiconductor light emitting device that may be firmly attached to a substrate with maintaining excellent light emitting efficiency, and a manufacturing method of the same, and a lighting apparatus and a display apparatus using the same. In order to achieve the above object, the semiconductor light emitting device according to the present invention includes a luminous layer, a light transmission layer disposed over a main surface of the luminous layer, and having depressions on a surface facing away from the luminous layer, and a transmission membrane disposed on the light transmission layer so as to follow contours of the depressions, and light from the luminous layer is irradiated so as to pass through the light transmission layer and the transmission membrane.

Abstract: A light emitting device according to the embodiment may include a light emitting structure including a first semiconductor layer, an active layer, and a second semiconductor layer; a first electrode on the light emitting structure; and a protection layer including a first metallic material on an outer peripheral region of one of the light emitting structure and the first electrode.

Abstract: An organic light emitting device and a manufacturing method thereof, including a first signal line and a second signal line intersecting each other on an insulating substrate, a switching thin film transistor connected to the first signal line and the second signal line, a driving thin film transistor connected to the switching thin film transistor, and a light emitting diode (“LD”) connected to the driving thin film transistor. The driving thin film transistor includes a driving control electrode and a driving semiconductor overlapping the driving control electrode, crystallized silicon having a doped region and a non-doped region, a driving gate insulating layer disposed between the driving control electrode and the driving semiconductor, and a driving input electrode and a driving output electrode opposite to each other on the driving semiconductor, wherein the interface between the driving gate insulating layer and the driving semiconductor includes nitrogen gas.

Abstract: A semiconductor device includes a photodiode formed using a silicon substrate, a wide-bandgap semiconductor layer formed on the silicon substrate and having a bandgap larger than that of silicon, and a switching element formed using the wide-bandgap semiconductor layer. The switching element is electrically connected to the photodiode so as to be on/off-controlled by a control signal from the photodiode.

Abstract: A semiconductor wafer has a plurality of optical semiconductor devices (namely, semiconductor lasers) which are formed from epitaxially grown layers and arranged across the surface of the semiconductor wafer. The InGaAs epitaxial layer of the semiconductor wafer has an opening (or groove) which continuously extends along and between the plurality of optical semiconductor devices, and which exposes the layer underlying the InGaAs epitaxial layer to at least the layer overlying the InGaAs epitaxial layer. The semiconductor wafer may be scribed along this opening to form a vertically extending crack therein.