Injection incoherent emitter

Abstract

An injection incoherent Emitter outputs a directed beam of light resulting from spontaneous emission. The Emitter provides small divergence angles and enhanced external efficiency, as well as increased energy and light power. Specific ranges of compositions and thicknesses for layers and sublayers in the entire heterostructure, as well as for the layers of the emission output area may be employed to create this Emitter. Different embodiments for the heterostructure and output areas permit emission from the Emitters in different but controllable directions. One such direction is perpendicular to the active layer. Other embodiments include multibeam incoherent Emitters, including embodiments that emit from lines and arrays of Emitters, wherein each Emitter has an independently controllable beam.

Description

BACKGROUND OF THE INVENTION

[0002] 1. Field of the Invention

[0003] The invention relates to optoelectronic technology, and more particularly, to effective, powerful, superbright and compact semiconductor diodes that are sources of spontaneous emission having a narrow beam pattern.

[0004] 2. Description of the Related Art

[0005] The injection incoherent emitter (hereafter referred to as the “Emitter”) is a device that converts electricity into optical emission of a specific spectral composition and spatial distribution (in the absence of an optical resonator). Different types of injection incoherent Emitters are known for a broad range of wavelengths, from infrared to blue and ultraviolet emissions. These Emitters include LEDs that produce surface emission, such as bright multipass LEDs (see, for example, F. A. Kish, et al., Appl. Phys. Lett., Vol. 64, No. 20, pp. 2839-2841 (1994); H. Sugawara, et al., Jap. J. Appl. Phys., Vol. 31, No. 8, pp. 2446-2451 (1992); M. Watanabe, et al., U.S. Pat. No. 5,537,433, Jul. 16, 1996; S. Nakamura, et al., Jap. J. Appl. Phys. Lett., Vol. 34, L1332 (1995)). These Emitters also include end Emitters (see, for example, A. T. Semenov, et al., Electron. Lett., Vol. 29, pp. 854-857 (1993); G. A. Alphonse, et al., IEEE J. of Quant. Electronics, Vol. QE-24, pp. 2454-2457 (1988)). Widespread use of these emission sources, however, is hampered by their insufficiently high efficiency, strength and power of the emission. The divergence of these emission sources is also too high for a number of applications.

[0006] An exemplary Emitter is described in F. A. Kish, et al., Appl. Phys. Lett., Vol. 64, No. 20, pp. 2839-2841 (1994). This exemplary Emitter is multipass and includes a heterostructure comprising semiconductor compounds AlGaInP. This Emitter contains an active layer with a broad forbidden band equal to Ea (eV), and thickness da in the range of 1-1.5 μm. This Emitter also has two optically uniform cladding layers, one of p-type conductance and the other of n-type conductance. Each cladding layer comprises one sublayer arranged, respectively, on the first and second surfaces of the active layer; the second surface being opposite to the first surface. Emission output areas (hereafter referred to as the “OA”) are located on surfaces of the cladding layers not adjacent to the active layer. These OA are made of a homogeneous semiconductor compound transparent to the emitted light, and more particularly, are made of GaP having p- and n-types of conductance, respectively. The OA are in the form of rectangular parallelepipeds having inner surfaces of area Sin (μm2) placed on the surfaces of the cladding layers not adjacent to the active layer. Side surfaces of the parallelepipeds form linear slope angles ψ of 90° with the inner and outer (i.e. exterior) surfaces of the OA, as well as with the active layer plane. An injection area for the current carriers having an area Sia (μm2) coincides with the active layer. The injection area is created by forming ohmic contacts on the p- and n-type OA. Metal coating layers are also required. When a direct current is applied in the injection area, non-equilibrium carriers recombine, producing spontaneous emission that propagates from the injection area to all sides of the active layer, including to both OA of p- and n-types. After disorderly, multiple reflections, a certain portion of the spontaneous emission is removed at various angles from the LED through the output surfaces. These output surfaces are located partially on the exterior surface of the p-type OA and on the side surfaces of the OA of both types. The divergence angle θ1 of the output emission in the vertical planes and the divergence angle θ2 of output emission in the horizontal planes have the maximum permissible value (up to 180°). The vertical planes are defined herein to be planes perpendicular to the active layer plane. The horizontal planes are defined herein to be planes perpendicular to the vertical planes and located on the output surfaces. Note that each direction of emission that passes through the horizontal plane could correspond to its own vertical plane that contains emission beams of the indicated direction. The known Emitter disclosed in F. A. Kish, et al., Appl. Phys. Lett., Vol. 64, No. 20, pp. 2839-2841 (1994) outputs light having a wavelength of 604 nanometers, with an external efficiency of 11.5% and with a light emission power (relative to 1A of current) of 93.2 lm/A. The density of the working current for continuous operating conditions does not exceed 100 A/cm2. The direction of the light rays in relation to the output surfaces in this case is disorderly, i.e., chaotic.

SUMMARY OF THE INVENTION

[0007] An Emitter is provided with increased external efficiency, increased energy and power, and increased emission intensity and light intensity. The possibility of directed, spontaneous emission for a broad range of directions is achieved. Multi-beam Emitters that emit from linear and two-dimensional arrays of Emitters, with independent inclusion of each beam are also possible. Emitters having the foregoing features can be fabricated using simplified manufacturing technology.

[0008] One aspect of the present invention is an injection incoherent Emitter that comprises a heterostructure and at least one emission output area. The heterostructure comprises at least one active layer, a plurality of cladding layers, and at least one ohmic contact. The at least one emission output area is located on the heterostructure. The emission output area adjoins at least one of the cladding layers. The emission output area is transparent for emission. The emission output area comprises at least one emission output area layer having a refractive index noaq, where q=1, 2, . . . p is defined as a whole number that designates the ordinal number of the emission output area layer enumerated from a boundary of the emission output area with the heterostructure. The emission output area and the heterostructure together have an effective refractive index nef. The effective refractive index nef of the heterostructure and the emission output area and the refractive index noa1 of the emission output area are selected to satisfy the correlations:

arc cos(nef/noa1)≦arc cos(nef min/noa1)

[0009] and

nef min is greater than nmin.

[0010] In the correlations, nef min is the minimum value of nef for heterostructures and adjoining emission output areas that produce spontaneous emission, and nmin is the least of the refractive indices in the heterostructure cladding layer.

BRIEF DESCRIPTION OF THE DRAWINGS

[0011] The preferred embodiment will be described in detail below in connection with FIGS. 1-25, in which:

[0012] FIG. 1 is a schematic illustration of a cross-section of an Emitter that passes through the central axis of symmetry of the emission output area made in the form of a truncated right angle cone, with the side surface of the emission output area forming a linear slope angle ψ with the inner surface of the output area, wherein ψ equals (π/2−φ);

[0013] FIG. 2 is a schematic illustration of a cross-section of an Emitter that passes through the central axis of symmetry of the emission output area made in the form of a truncated right angle cone, with the side surface of the emission output area forming a linear slope angle ψ with the inner surface of the output area, wherein ψ equals (3π/4−φ/2);

[0014] FIG. 3 is a schematic illustration of a cross-section of an Emitter that passes through the central axis of symmetry of the emission output area made in the form of a truncated right angle cone, with the side surface of the emission output area forming a linear slope angle ψ with the inner surface of the output area, wherein ψ equals (π/4−φ/2);

[0015] FIG. 4 is a schematic illustration of an axial cross-section that passes through the central axis of symmetry of the emission output area of an Emitter made in the form of a right angle cylinder;

[0016] FIG. 5 is a schematic illustration of a cross-section along one of the sides of the Emitters whose emission output area is formed as a rectangular parallelepiped, the emission optical area comprising two electrical conducting layers, the refractive index noa2 of the second layer exceeding the refractive index noa1 of the first layer that borders the heterostructure;

[0017] FIG. 6 is a schematic illustration of a cross-section along one of the sides of the Emitters whose emission output area is formed as a rectangular parallelepiped, the emission optical area comprising two layers, the first layer being conducting, and the second being insulating, the injection areas being electrically connected in series;

[0018] FIG. 7 is a schematic illustration of a view from above (i.e., from the side of the emission output area) for the Emitter having the cross-section depicted in FIG. 1;

[0019] FIG. 8 is a schematic illustration of a view from above (i.e., from the side of the emission output area) for the Emitter having the cross-section depicted in FIG. 2;

[0020] FIG. 9 is a schematic illustration of a view from above (i.e., from the side of the emission output area) for the Emitter having the cross-section depicted in FIG. 4;

[0021] FIG. 10 is a schematic illustration of a view from above (i.e., from the side of the emission output area) for the Emitter having the cross-section depicted in FIG. 5;

[0022] FIG. 11 is a schematic illustration of a cross-section of the Emitters in accordance with the present invention installed on a holder;

[0023] FIG. 12 is a schematic illustration of a longitudinal view of an Emitter for which the emission output passes through one side facet of the hexahedral emission output area, wherein the spatial extent of the near field emission is small but the emission is bright;

[0024] FIG. 13 is a schematic illustration of a cross-sectional view of the Emitter of FIG. 12;

[0025] FIG. 14 is a schematic illustration of a cross-section along the length of a linear sequence of injection areas for an Emitter with a set of spontaneous emission beams whose emission output area is common for each linear sequence of injection areas, wherein the emission output area is in the form of a set of orderly interconnected right angle cylinders;

[0026] FIG. 15 is a schematic illustration of the cross-section perpendicular to the length of the linear sequence of injection areas for the Emitter with a set of spontaneous emission beams whose emission output area is common for each linear sequence of injection areas, wherein the emission output area is in the form of a set of orderly interconnected right angle cylinders;

[0027] FIG. 16 is a schematic illustration of a top plan view of the Emitter depicted in FIGS. 14 and 15;

[0028] FIG. 17 is a schematic illustration of a cross-section on the symmetry plane for an Emitter having an emission output area made in the form of a set of nine truncated right angle cones arranged in order and connected together;

[0029] FIG. 18 is a schematic illustration of the plan view for the Emitter whose emission output area is made in the form of a set of nine truncated right angle cones arranged in order and connected together;

[0030] FIG. 19 illustrates the results of experimental measurements of divergence angles of emission in vertical (θ1) and horizontal (θ2) planes; and

[0031] FIG. 20 illustrates plots of the dependence of emission power on current for an experimental Emitter sample.

[0032] FIG. 21 schematically illustrates a longitudinal section of an Emitter with a one-layer output region and different thicknesses of the cladding layer for the middle and edge injection regions.

[0033] FIG. 22 schematically illustrates a longitudinal section of an Emitter with a two-layer output region and different thicknesses of the cladding layer for the middle and edge injection regions.

[0034] FIG. 23 schematically illustrates a longitudinal section of an Emitter with two-layer output regions, disposed on both sides of the active layer, and identical thicknesses of the cladding layer for the middle and edge injection regions.

[0035] FIG. 24 schematically illustrates a longitudinal section of an Emitter with a one-layer output region and identical thicknesses of the cladding layers for the middle and edge injection regions.

[0036] FIG. 25 schematically presents a view from below for the Emitters whose longitudinal sections are depicted in FIGS. 21-24.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0037] In one embodiment of the present invention, an injection incoherent Emitter includes a heterostructure that contains an active layer, cladding layers, at least one ohmic contact, and an emission output area. At least on one side of the active layer, the emission output area adjoins the heterostructure at the corresponding cladding layer. The emission output area is made of one or more layers characterized by refractive index noaq and emission optical loss factor αoaq (cm−1) and having thickness doaq (μm), where q=1, 2 . . . p are defined as whole numbers that designate the ordinal number of the output area layer enumerated from its boundary with the heterostructure. The emission emission output area is also transparent for emission. The heterostructure with emission output area connected to it is characterized by effective refractive index nef. The effective refractive index nef and refractive index noa1 satisfy the correlations:

0 <arc cos(nef/noa1)=φ≦arc cos(nef min/noa1)=φmax, and nef min, is greater than nmin,

[0038] In the foregoing correlations, nef min is the minimum value of nef of all possible nef for the heterostructure sets that are of practical value with emission output areas, nmin is the least of the refractive indices in heterostructure cladding layers, φ is the angle of propagation made with the plane of the active layer as measured from a normal to the wavefront for radiation propagating within the radiation output region, and φmax is the upper bound for possible propagation angles.

[0039] One particular innovative aspect of the Emitters is the significant features of the entire heterostructure and of the emission output area, which impact on the functioning and the resulting output characteristics of the Emitters. The number of layers and sublayers of the heterostructure as well as their thicknesses and composition were selected for the proposed Emitter so that a narrow-beam pattern is obtained mainly in the vertical planes for intensive, spontaneous emission that emerges from the injection area. This narrow beam pattern is primarily directed at angles of propagation φ in relation to the active layer plane. A necessary condition for production of a narrow-beam pattern is fulfillment of the correlation known as the condition for leaking modes of laser radiation that are propagated in the optical resonator of laser diodes. This condition, described in J. K. Buttler, et al., IEEE Journ. Quant. Electron., Vol. QE-11, p. 402 (1975), requires that:

nef <noa  (1)

[0040] The value of the effective refractive index nef can be obtained by calculation from the correlation β=(2π/λ)nef, where β is the modulus of complex magnitude of constant propagation for an emission wave in one of the directions in the active layer, while λ is the emission wavelength.

[0041] In accordance with one preferred embodiment, it has been confirmed experimentally that the condition (1) is also applicable for spontaneous emission. Consequently, the angle of propagation φ of the directional spontaneous emission is defined as equal to the angle of leaking modes of laser radiation—namely,

φ=arc cos(nef/noa1)  (2)

[0042] In addition, the entire range of propagation angles φ of directional, spontaneous emission may be used, and correspondingly, the ratio (nef/noa1) may be used. The conditions (1) and (2) define the lower boundary of angle φ (φ is greater than zero). The upper boundary of these propagation angles φmax is defined by the formulas:

arc cos(nef/noa1)≦arc cos(nef min/noa1)=φmax  (3)

nef min is greater than nmin  (4)

[0043] In formulas (3) and (4), nef min is the minimum value nef of all possible nef for the sets of heterostructures of practical value with emission output areas, and nmin is the least of the refractive indices in the heterostructure cladding layers. Numerical calculations have been made for certain practical heterostructures (e.g., heterostructures based on compounds InGaAs/GaAs/AlGaAs), and the calculations have indicated that the critical angle of outflow φmax is approximately 30° to 35°.

[0044] The divergence angle Δφ in the vertical planes for spontaneous emission propagating in the OA is determined by spectral dispersion and emission diffraction. The angle of dispersion divergence Δφ1 depends on wavelength λ, which changes within the spectral band Δλ of spontaneous emission. The angle Δφ1 can be defined by numerical calculation using formula (2), with known dependencies of the refractive indices nef and noa1 on wavelength λ in the range of Δλ.

[0045] The complete divergence angle Δφ of emission in the vertical plane inside OA equals Δφ1+Δφ2. The angle Δφ2 is the angle of diffraction divergence. By using the known approximate correlation discussed in Kh. Keysi, M. Panish, “Lazery na geterostrukturakh” (Lasers on Heterostructures), Part 1, Publ. “Mir”, Moscow, 1981, pp. 89-97, the angle Δφ2 can be written as:

Δφ2≅γ×λ/(nef×Dia×sin φ)  (5)

[0046] In the correlation (5), γ is the numerical coefficient that indicates which level of emission intensity defines angle Δφ2 (γ equals one at level 0.5, and γ equals two at level 0.1). The value Dia is the size of the injection area in the plane of the active layer in the selected direction. The divergence angle θ1 of the output emission in the vertical plane outside the OA is determined using the known Fresnel formulas (see, e.g., R. Ditchbern, Fizicheskaya optika [Physical Optics], Publ. Nauka, Moscow, 1965, pp. 398-402). In particular, θ1 is approximately equal to arc sin [n×sin(Δφ)]. Based on the smallness of angle Δφ, angle θ1 can be estimated as:

θ1≅(noa1/n0)×Δφ  (6)

[0047] Here n0 is the refractive index of the medium that borders with the output surface. For air, n0 equals one.

[0048] The efficiency of input ηin into the OA of the resulting directional spontaneous emission is defined by the ratio of the number of spontaneous photons entering from the injection area into the OA at propagation angles from (φ−Δφ/2) to (φ+Δφ/2) to the total number of spontaneous photons in the injection area. We found that ηin can be defined as:

ηin=αout/(αout+αia+αend)  (7)

[0049] In formula (7), αout (cm−1) is the useful loss coefficient of the directional spontaneous emission emerging from the injection area into the OA, or concisely identified as the coefficient of the directional emission, αia (cm−1) is the optical loss coefficient defined by the absorption and scattering of emission in the injection area, and αend (cm−1) is the loss coefficient defined by the outgoing emission through the end boundaries of the injection area. Consequently, ηin, the efficiency of input (which to a significant degree determines the external efficiency of the Emitter), is mainly controlled by the thickness and/or composition (refractive index) of the cladding sublayers that adjoin the OA. With selection of αout>>(αia+αend) the quantity ηin could be close to one. Depending on the nature of the cladding layers, both one-sided and two-sided output of spontaneous emission from the injection area are possible.

[0050] The assumption upon which the Emitter designs is based, that the appropriate selection of the heterostructure can provide for narrow-beam spontaneous emission, is not obvious. There are prevalent opinions that spontaneous emission inside the heterostructure is not directional due to the chaotic propagation of individual spontaneous photons (see, for example, Yu. R. Nosov, “Optoelektronika” [Optoelectronics], Moscow, Publ. “Radio i svyaz” [Radio and Communications], p. 141 (1989). By implementing the essential features of the preferred Emitter, a narrow beam pattern of spontaneous emission in vertical planes is obtained. Effective removal of the spontaneous emission results in super-high external efficiency in terms of energy, light power, emission intensity, and light intensity. Additionally, the production of outputs in various controllable directions, including emission perpendicular to the active layer, is possible. The performance of this Emitter has been demonstrated experimentally and confirmed by calculation. Applying the features combined in the preferred embodiment may lead to multi-beam Emitters. Such multi-beam sources may include those that emit from a line or an array of Emitters with independent control of their beams.

[0051] Possible embodiments may include varying the compositions, the widths, the thicknesses, and the number of layers and sublayers in both the heterostructure and the OA. Also, different and unusual configurations of the OA can be realized to obtain a highly efficient output comprising directional spontaneous emission.

[0052] The selection of the OA design is based on the fact that one distinguishing characteristic of the Emitter is that the spontaneous emission has a narrow beam pattern in the vertical planes. In the corresponding horizontal planes, however, the spontaneous emission is propagated with equal probability in any direction. Unlike the leaking mode in injection lasers, the range of angular distribution for the spontaneous emission is about 2π. Here, as well as in the well-known Emitter described in F. A. Kish, et al., Appl. Phys. Lett., Vol. 64, No. 20, pp. 2839-2841 (1994), the horizontal plane is defined as a plane that is perpendicular to the corresponding vertical plane, which, in turn, is perpendicular to the active layer plane. The distribution of emission establishes the dependence of the effective output of spontaneous emission from the OA on the configuration of the OA. More particularly, the angle of emission determines the linear slope angles ψ between the side surface of the OA and its inner surface (i.e., the surface adjacent to the cladding). The greatest efficiency can be achieved when the OA is selected in the form of a solid of revolution in relation to the axis that is perpendicular to the plane of the injection area and passes through its center (e.g., in the form of a truncated right cone or right circular cylinder). Different directions of emission removal (relative to the active layer plane) are established by the appropriate selection of the slope angles ψ,which in turn depend on angle φ. In individual cases, the OA may be made not only in the form of a solid of revolution but also, for example, in the form of a hexahedron, although, in this case, the efficiency of emission extraction from the OA will be diminished.

[0053] The active layer may be formed of at least one sublayer. The cladding layers are located, correspondingly, on the first and second surfaces of the active layer; the second surface being opposite to the first surface. The cladding layers are formed from cladding sublayers Ii and IIj, respectively, where i=1, 2, . . . k and j=1, 2, . . . m are defined as whole numbers that designate the ordinal number of the cladding sublayers enumerated from the active layer. In each cladding layer, there is at least one cladding sublayer. These cladding sublayers have corresponding refractive indices, nIi and nIIj.

[0054] Possible embodiments include Emitters having heterostructure designs in which at least one cladding layer may be formed as a gradient (i.e., the layer has a monotonically changing composition). This gradient cladding layer is viewed as a finite number of sublayers in the cladding layer having corresponding nIi and nIIj obtained by dividing each gradient cladding layer. Other embodiments of the Emitter include heterostructure designs for which the active layer can be made in the form of one or several active sublayers separated from each other by barrier sublayers. The sublayers comprising the active layer may have quantum-dimensions thicknesses while the cladding layer may comprise one or several sublayers and may be formed as a gradient. These different heterostructure designs make it possible to improve the internal efficiency of converting injected nonequilibrium carriers into spontaneous photons, and at the same time, to increase the overall efficiency of the Emitter.

[0055] The operating Emitter has at least one injection area. The injection area in the working device essentially coincides with the active layer for that part of it, i.e., the area in which there is injection of nonequilibrium carriers. The presence of a number of injection areas makes it possible to create multi-beam Emitters.

[0056] In preferred embodiments to be manufactured, the thickness of the cladding layer that adjoins the OA is less than the thickness of the cladding layer located on the opposite side of the active layer. Additionally, the refractive index of the cladding sublayer that adjoins the area of emission output is preferably greater than the refractive index of the external cladding sublayer that is located on the opposite side of the active layer.

[0057] Advantageously, the Emitter produces one-sided propagation of spontaneous emission from the injection area into the OA with a significant improvement in directionality and an increase of external efficiency.

[0058] The direct projection of the injection area onto the inner OA surface must not be beyond the boundaries of the OA surface. Selection of the thickness doa1 depends on the propagation angle φ, the maximum size Dia of the injection area, and the slope angle ψ. Consequently, the dimensions and the area Sia of the injection area preferably do not exceed the dimensions and the area Sis of the introduced inner surface of the emission output area that adjoins the heterostructure, and more specifically, the corresponding cladding layer of the heterostructure. Additionally, the thickness of the emission output area doaq preferably is in a range between 1 and 10,000 μm.

[0059] In some preferred embodiments of the present invention, the area of emission output is conducting and an ohmic contact is formed to the introduced exterior surface of the emission output area. This arrangement permits simplification of the technology for manufacturing the Emitter.

[0060] In preferred embodiments of the Emitter, the OA is made of optically homogeneous material. The requirement that the OA be transparent for spontaneous emission means that in order for the Emitter to operate efficiently, the OA must be characterized as having low optical losses due to absorption and scattering of spontaneous emission. For a one-layered OA, this requirement is satisfied when the following condition is met:

αoa1>>(μ×Dis)−1  (8)

[0061] In condition (8), αoa1 is a coefficient of optical losses for OA, μ is a number that could change approximately from 0.4 to 1.5 depending on the OA configuration, and Dis is the size of the OA inner surface in the chosen direction. For semiconductor materials, for example, the width of the forbidden band for the OA Eoa1 must be greater than the width of the forbidden band of the active layer Ea. Note that the forbidden band of the active layer Ea defines the emission wavelength λ. In those cases, where the OA is non-conducting, in order to obtain low values of αoa1 (cm−1), the OA preferably comprises at least two layers. The first layer of the OA, which borders the heterostructure, should be conducting, and the second layer of the OA should comprise a material that has a lower optical loss factor αoa2 than αoa1 for the first layer. In this case, the second layer could be insulating. This design improves the efficiency of the Emitter by reducing the optical losses for absorption and scattering of emission when passing through the OA.

[0062] By selecting a refractive index noa1 for the first layer that is different from the refractive index noa2 for the second layer, the propagation of emission in the OA layers is controllable. The refractive indices noa1, noa2 also control the thickness of the OA and its layers. Emission is propagated through the first layer at propagation angle φ equal to arc cos(nef/noa1) while emission is propagated through the second layer, at propagation angle φ2 equal to arc cos(nef/noa2). (See equation (2).) Similarly, for the qth layer of the OA:

φq =arc cos(nef/noaq)  (9)

[0063] The propagation angle φq on the boundary of two OA layers will thus be changed in any direction. For example, for an OA consisting of two layers, the angle φ2 will be greater than the angle φ if the refractive index noa2 of the second layer is selected to be greater than the refractive index noa1 of the first layer that borders the heterostructure. For the opposite case, where nnoa2 is less than noa1, the thickness of the second layer could be less than in the case where noa2 is greater than noa1. Having a thinner second layer reduces the thickness of the OA, thereby simplifying the technology and reducing the manufacturing expenses of the Emitter. Further simplification of the technology and decrease in the thickness doa1 of the output area, all the way down to micron dimensions, is possible if noa2 is selected as less than neff. In this case, the radiation leakage condition (1) is not satisfied for the second layer of the output area, and at least some of the outgoing leakage radiation at the boundary with the second layer of the output area undergoes total internal reflection back into the heterostructure. Another method of reducing the propagation angles φq comprises introducing sublayers Ii, and/or IIj with refractive index more than nef into the cladding layers of the heterostructure with OA connected to it (which together has an effective refractive index nef).

[0064] In addition, at least one layer of the OA preferably is made of semiconductor material, and at least one layer of the OA is preferably made of an introduced substrate material, thereby simplifying the Emitter manufacturing technology.

[0065] In all of the embodiments discussed above having a multi-layer OA with an electrically conducting first layer, ohmic contact is made to the first electrically conducting OA layer. This arrangement reduces the thermal losses due to resistance and simplifies the Emitter manufacturing technology. Preferably, the thickness of the electrically conducting layer is not bigger than the minimum linear dimension of the injection area. The effectiveness of the ohmic contact depends on the dimensions of the injection area and on the densities of currents that pass through the proposed Emitter. Of further note, the OA can generally be made of more than semiconductor materials. In particular, the refractive index noa1, and more generally a refractive index noaq (see Equation (9)), and the optical loss factor αoaq need only satisfy the necessary requirements set out in Equation (1) and Equation (8).

[0066] In one preferred embodiment of the present invention has at least one emission output area is formed as truncated right circular cone, one whose base is located on the cladding sublayer adjoining it. The side surface of the cone is formed by its generatrix. Emitters having an OA with this conical configuration could emit in different directions and obtain maximum efficiency, power and strength of emission for emissions at normal incidence to the output surfaces.

[0067] In addition, this embodiment preferably contains the following features:

[0068] To produce emission at the propagation angle φ relative to the active layer plane, the linear slope angles ψ of the generatrix of the side surface of the emission output area with respect to the inner surface of the OA are selected in the range from (π/2−φ−σ) to (π/2−φ+σ). Consistent with its usage above, σ is the angle of total internal reflection from the output surface for emission that propagates in the emission output area.

[0069] To produce emission output directed at a right angle relative to the plane of the active layer and towards the side of the Emitter where the OA is located, the linear slope angles ψ between the side surface generatrix of the emission output area and its inner surface should be selected from the range (3π/4−φ/2−σ/2) to (3π/4−φ/2+σ/2).

[0070] To produce emission output directed at a right angle relative to the plane of active layer and towards the location of the heterostructure, the linear slope angles ψ between the side surface generatrix of the emission output area and its inner surface should be selected from the range (π/4−φ/2−σ/2) to (π/4−φ/2+σ/2).

[0071] Alternatively, an emission output area can be formed comprising at least one cylinder whose base is located on the cladding layer adjoining it. Such an arrangement simplifies the manufacturing technology and produces enhanced characteristics of the Emitter when directional multiple reflections to the OA are used.

[0072] One additional preferred embodiment includes an Emitter in which the OA comprises at least one hexahedron whose base is located on the cladding layer adjoining it. In this embodiment, the following features are preferred:

[0073] Select the linear slope angle ψ between at least one of the planar side surfaces of the hexahedron and the inner surface of the emission output region to be in the range from (π/2φΔφ/2) to (π/2−φ+Δφ/2), where Δφ is the emission divergence angle in the vertical plane.

[0074] Select the linear slope angle ψ between at least one of the planar side surfaces of the hexahedron and inner surface of the emission output area to be in the range from (3π/4−φ/2−Δφ/2) to (3π/4−φ/2+Δφ/2).

[0075] Select the linear slope angle ψ between at least one of the planar side surfaces of the hexahedron with the inner surface of the emission output area to be in the range from (π/4−φ/2−Δφ/2) to (π/4−φ/2+Δφ/2).

[0076] Select the linear slope angle ψ between at least one of the planar side surfaces of the hexahedron and the inner surface of the emission output area to be equal to π/2. Selection of the OA design in the form of a hexahedron makes it possible to simplify the manufacturing technology, and also reduces the spatial extent of the near field emission, while simultaneously increasing the brightness of the Emitter.

[0077] For those Emitters in which the OA is made in the form of a cylinder, or in the form of a hexahedron, and whose output surface is perpendicular to the active layer plane, the propagation angle φ should be smaller than the angle of total internal reflection σ, which makes it possible to exclude the total internal reflection of the emission exiting the OA from the output surface and the corresponding losses.

[0078] Additionally, at least on part of the introduced output surfaces, anti-reflection coatings may be introduced, while on another part of the output surfaces, reflecting coatings may be introduced to further increase the efficiency, power, strength of emission and brightness of the Emitters.

[0079] Embodiments of the present invention include Emitters with a plurality of output beams of directional emission. These embodiments differ from those described above in that during their production, at least two injection areas with identical propagation angles φ are formed in the heterostructure. Separate ohmic contacts may be formed with the outside of the heterostructure to provide individual supply of power current for independent control of the beams to each injection area.

[0080] In one embodiment of the multi-beam Emitter, an OA could be provided for each injection area with independent ohmic contact.

[0081] In another embodiment of the multi-beam Emitter, one single common OA could be provided at least for part of the injection area, both with independent contact and without it.

[0082] Emitters that have a linear sequence of the output beams of directional spontaneous emission and that are independently engaged by power supply current can be produced. Emitters can be fabricated by implementing the following measures:

[0083] Injection areas of similar dimensions having independent contacts are arranged in order and along one line in the heterostructure, thereby creating a linear sequence of the injection areas.

[0084] Metal coating layers are preferably made in the form of strips that electrically connect the injection areas in the linear sequence. These strips are preferably formed on the side of the emission output area, at least on part of their external surfaces.

[0085] Emitters that are arranged so as to produce an array of output beams of directional spontaneous emission that are independent engaged by power supply current can be produced. The objectives of the invention are achieved in the fabrication of these Emitters by implementing the following measures:

[0086] In the heterostructure, at least two linear sequences of the injection areas are formed.

[0087] Metal coating layers are preferably made in the form of strips that are each electrically connected to independent contacts for one injection area in the linear sequences of injection areas. These strips are preferably on the side of the injection area, at least on part of their external surfaces.

[0088] In order to increase efficiency by reducing losses of nonequilibrium carriers due to their spreading and surface recombination, the injection area dimensions are preferably limited by barrier layers inserted up to and including the active layer.

[0089] In order to increase efficient matching of the Emitters with the power source through sequential electrical connection of the injection areas, at least two neighboring injection areas are electrically isolated up to the second insulating OA layer. The ohmic contacts of these injection areas, however, remain electrically connected through a metal coating layer.

[0090] Preferred embodiments may comprise a heterostructure designs formed with specific composites, thicknesses, and number of layers and sublayers. These embodiments also include non-apparent designs for the emission output area which is made of materials having refractive indices with specific magnitudes, and with a specific number of layers. With these Emitter, directional, spontaneous emission can be formed with subsequent efficient emergence of this emission from the output area. Removal efficiency is also improved by selecting the corresponding slope angles v for the OA side surface. All of the foregoing design features enable increased external efficiency, increased energy and light power, increased emission and light intensity of the injection incoherent Emitter, and also produce spontaneous emission of high directionality for a range of different directions. Additionally, creation of a multi-beam Emitter that emits from lines and arrays of Emitters, with independent engagement of each beam is possible using simplified manufacturing technology.

[0091] Preferred embodiments can be realized using basic production processes that are well known. The range of wavelength emission for the currently developed Emitters extends from infrared to ultraviolet emissions. Accordingly, different heterostructures can be used depending on the wavelength desired:

[0092] For ultraviolet, blue and green emissions (0.36 μm<λ<0.58 μm) the most effective heterostructures are based on semiconductor compounds in the AlGaN/GaN/GaInN system, as well as ZnCdSSe/GaAs;

[0093] For red and yellow emissions (0.58 μm<λ<0.69 μm), compounds in the AlGaInP/GaAs system are preferred;

[0094] For infrared emissions, wherein 0.77 μm<λ<1.2 μm, compounds in the AlGaAs/GaAs system and in the InGaAs/GaAs/AlGaAs system are preferred;

[0095] For infrared emissions, wherein 1.2 μm<λ<2.0 μm, compounds in the GaInAsP/InP system are preferred; and

[0096] For infrared wherein 2.0 μm<λ<4.0 μm, compounds in the AlGaInSbAs/GaAs system are preferred.

[0097] The corresponding materials for the OA that meet conditions (1) and (8) in each of the indicated ranges of wavelengths and for the chosen heterostructure must be selected. The following semiconductor materials for the OA are preferred:

[0098] GaN for the AlGaN/GaN/GaInN system;

[0099] ZnSe for the ZnCdSSe/GaAs system;

[0100] GaP for the AlGaInP/GaAs system;

[0101] GaP for the AlGaAs/GaAs system;

[0102] GaAs and GaP for the InGaAs/GaAs/AlGaAs system;

[0103] Si and GaAs for the GaInAsP/InP system; and

[0104] Si and GaAs for the AlGaInSbAs/GaAs system.

[0105] The designs described above could be successfully implemented using recently developed technology of “wafer bonding” (see, for example, H. Wada, et al., IEEE Photon. Technol. Lett., Vol. 8, p. 173 (1996)).

[0106] The embodiments of the present invention comprising Emitters with directional spontaneous emission are applicable at least for emission at all the aforementioned wavelength ranges using the heterostructure systems described above. White emission Emitters used for illumination can be produced by the following methods:

[0107] either by mixing emissions of three basic colors of red, green and blue; or

[0108] by exciting luminescent red and green emissions from the Emitter of blue emission in a substance especially selected for this purpose.

[0109] The present invention is further explained by specific variations of its design with references to the attached drawings. The present invention is not limited to the embodiments described. Rather, the present invention may include other embodiments having features that are encompassed within the combination of features recited in the claims.

[0110] As schematically illustrated in FIGS. 1 and 7, an Emitter 1 in accordance with one of the embodiments of the present invention includes a heterostructure 2 that was developed by the well-known method of MOCVD (metal organic chemical vapor deposition). The heterostructure 2 contains an active layer 3 placed between cladding layers 4 and 5, with sublayers Ii and IIj, respectively, where i=1 . . . k, while j=1 . . . m. Although not shown in FIG. 1, it should be understood that the active layer 3 in this case comprises several active sublayers, with barrier sublayers dividing the active sublayers. An emission output area (OA) 7 comprises a semiconductor having the shape of a truncated right circular cone defined by a generatrix at an angle ψ. The OA 7 is located on the surface of sublayer IIm of the cladding layer 5 (i.e., on the surface of a sublayer not adjacent to the active layer 3). The OA 7 has a side surface 8 having a linear slope angle (generatrix angle) ψ defined with respect to the inner surface 6 that is equal to 72° (or in one embodiment 71°). The height of the cone is 921 μm. The circular base of the cone has a diameter of 3000 μm that corresponds to the diameter of the inner surface 6 of the output area 7. The top of the conical OA 7 is circular and has a diameter smaller than 2,401 μm, which defines an exterior surface 9 of the OA 7. The Emitter 1 has an injection area 10 that coincides with the active layer 3, their surfaces being the same. The injection area 10 is circular and has a diameter Dia of 3000 μm and an area Sia equal to 0.07065 cm2. The thickness of the injection area 10 equals the thickness of active layer 3. A first ohmic contact 11 is formed on the side of the Emitter 1 that is opposite to the OA 7, while a second ohmic contact 12 is formed on exterior surface 9 of the OA 7. The first cladding layer 4 in this embodiment comprises sublayers 13 (I1) and 14 (I2), while the second cladding layer 5 comprises sublayers 15 (II1) and 16 (II2). A semiconductor contact layer 17 is located on the surface of sublayer Ik of first cladding layer 4 far from active layer 3, and, in a particular embodiment, is located on the sublayer 14. The contact layer 17 is designed to reduce the Emitter's ohmic resistance. The contact layer 17 may not be required when making heterostructures 2 of the Emitter from other semiconductor compounds (e.g., GaInAsP/InP, as discussed above). The composition, thicknesses, refractive indices, type, carriers concentrations and absorption indexes of the layers and sublayers of the heterostructure 2, as well as the contact layer 17 and the OA 7 are given in the Tables below. The emission wavelength λ for the composition of the active layer 3 of the heterostructure 2 specified in the Tables is 604 nanometers.

[0111] The conventional arrows in FIG. 1, as well as in subsequent FIGS. 2-5, 12, 13 and 15, depict the directions of laser radiation propagated within and outside the OA 7. The linear slope angles ψ between the inner surface 6 and the side surface 8 are read in the direction from the inner surface 6 in accordance with convention.

[0112] In a preferred embodiment, the Emitter 1 is mounted on a support (holder) 18, for example, such as the support 18 with conical sloped reflecting walls 19 shown in FIG. 11. The support 18 is also an electrical terminal. Contact between the ohmic contact of Emitter 1 and the support 18 is provided, for example, by electrically conducting paste containing silver. The other ohmic contact 12 of the Emitter 1 is connected with a wire 20 to another electrical terminal 21. The required power is fed to the ohmic contacts 11 and 12 via the support 18 and the terminal 21. The support 18 with Emitter 1 therein can be advantageously filled with a transparent compound (not shown in FIG. 11) having a refractive index no equal to 1.5.

[0113] The primary parameters for this and subsequent Emitters 1 were obtained by numerical calculations. The values of the effective refractive index nef, propagation angle φ, coefficient αout characterizing the directional emission, as well as the dispersion divergence angle Δφ1 for the directional spontaneous emission were calculated by a program based on a matrix method for solving Maxwell's equations with the appropriate boundary conditions for the multilayer heterostructures. See, for example, J. Chilwall, et al., J. Opt. Soc. Amer. A. Vol. 1, No. 7, pp. 742-753 (1984).

[0114] The following results were obtained specifically for Emitters 1 with the heterostructure 2 and the OA 7 having the characteristics given in the Tables:

[0115] the effective refractive index nef equals 3.2921 (or one embodiment 3.2673);

[0116] the propagation angle φ equals 18° (or in one embodiment) 19°;

[0117] the factor αout of the directional emission into OA equals 966 cm−1 when the current density through device j is 100 A/cm2 (in one embodiment, the coefficient αout for outgoing radiation leaking from the injection area into output area 7 is equal to 385.6 cm−1);

[0118] the index αia of absorption of the injection areas equals 5.05 cm−1; and

[0119] the angle of divergence resulting from dispersion Δφ1 for spontaneous emission inside the OA 7 equals 11.6 mrad (milliradians). (For the numerical calculations, the spontaneous emission spectral line half-width was assumed to be 20 nanometers).

[0120] The divergence angle resulting from diffraction Δφ2 (see Equation (5)) was only 0.2 mrad. Based on this, the complete divergence angle Δφ inside the OA 7 equals 11.8 mrad. The divergence angle θ1 n the vertical plane of emission after exiting the OA 7, as determined by Equation (6), equals 40.8 mrad (2.3°). In the near field, the output spontaneous emission has the shape of the ring shaped or annular surface located on side surface 8 of the OA 7. The width of this ring equals 930 μm, while its total area is 0.028 cm2. Output emission along the entire perimeter of the ring is inclined at an angle φ relative to active layer 3 plane equal to 18° (or 19° in one embodiment).

[0121] External efficiency η was calculated by the formula for the embodiment of Emitter 1 wherein the spontaneous emission is normally incident on the output surface:

η=η1×ηin×ηα×(1−R)×[1+(ηin×θα2×R)1+(ηin×ηα2×R)2+(ηin×ηα2×R)3+ . . . ]  (10)

[0122] In Equation (10), ηi is the internal quantum efficiency defined by the ratio of the number of emerging photons of spontaneous emission to the number of injected pairs of electrons and holes; R is the reflection factor for spontaneous emission normally incident on the output surface of the OA 7; and ηα is the efficiency that defines emission optical losses (absorption, scattering) during a single passage through the OA 7. The value of ηα in Equation (10) is determined by the following relation:

ηα−exp(−αoa1×μ×Dis)  (11)

[0123] In Equation (11), μ is the number which, depending on the OA configuration, can vary approximately from 0.4 to 1.5, and Dis is the diameter of inner surface 6 of OA 7.

[0124] The calculation of ηin in Equation (10) was made using Equation (7). In the calculations, ηi was assumed to be equal to one (which is usually true for quality heterostructures). In the second Table, the index of optical losses for every layer of heterostructure was assumed to be 5 cm−1, and the index of optical losses αoa1 for OA was assumed to be 0.6 cm−1. See, for example, Opticheskiye svoystva poluprovodnikov, [Optical Properties of Semiconductors], ed. by R. Willardson and A. Bir, Publ. “Mir”, pp. 454-458, Moscow, 1970. The losses for spontaneous emission emerging from the edge surfaces of injection area 10 were not considered in the calculations since they are small in magnitude (i.e., αend was assumed to equal zero). Efficiency factors ηin, defined in Equation (7), and ηα, defined in Equation (11), equaled 0.9947 and 0.9180, respectively. (The value of ηin in one embodiment is 0.9872.) In the calculation of ηα, as defined by Equation (11), the numerical coefficient μ was taken to be (0.5 cosφ) or, more specifically, 0.4756. The external efficiency η of the Emitter 1 was calculated to be equal to 0.8608 (or 0.8709 in one embodiment) using Equation (10) and commonly accepted assumptions.

[0125] The output power P (Watts) of the spontaneous emission was defined according to the formula:

P=η×J× (hν)  (12)

[0126] where J (Amperes) is the working current that passes through the injection area, while hν is the emission quantum energy expressed in volts. The power of the spontaneous emission P that can be defined for a current J equal to 7.065 A and can be obtained for a working current density of 100 A/cm2 is 12.5 W (or 12.6 W). The power of the emission relative to one unit of area for emission in the near field equals 83.3 W/cm2 (or 84.3 W/cm2). Based on the visibility curve, for an emitted wavelength of 604 nanometers, the power of the spontaneous emission, 12.5 W, corresponds to light power Plight equal to 4,952 lumens. The intensity of light Qlight, defined by the ratio of the light power Plight to full solid angle (2π×Δφ) in which it is radiated, equals 19,327 candelas (cd). In one embodiment the power of the spontaneous emission, light power Plight, and are 12.6 W, 5,010 lumens, and 19,553 candelas (cd), respectively.

[0127] In the next embodiment of the Emitter 1, which is depicted in FIGS. 17 and 18, the OA 7 consists of a set of orderly truncated right circular cones and “connectors” 22 that connect the exterior surfaces of all the indicated cones in two mutually perpendicular directions. Nine cones and twelve connectors are shown in FIG. 18. The inner surfaces 6 of the OA 7, like the injection areas 10, which have the same shape and area, are circular and are connected by the lower bases of the connectors 22. The circular inner surfaces 6 of the OA 7 lie on the cladding layer 4 and are arranged with a periodicity equal to twice diameter of the circles. The contact layer 17 comprises a GaAs substrate. Current is supplied through the one-piece ohmic contact 11 that is located on the contact layer 17 and through the ohmic contact 12 that is located on the exterior surface 9 of all the cones and their connectors 22. A thickness of the OA 7 of only one micron or more can be ensured in this Emitter 1 by selecting the small areas for the injection area 10 (for example, by using injection areas 10 having diameters of approximately 10 μm or more). The manufacturing technology for this Emitter 1 design is simplified since the OA 7 layers can be grown in one process with the heterostructure 2, and the shape of the OA 7 can be formed using an chemically assisted ion-beam etching. See, for example, J. D. Chinn, et al., J. Vac. Sci. Technol., Vol. A1, pp. 701-704 (1983). At the same time, this Emitter 1 of FIGS. 17 and 18 has high external efficiency as a result of having only small losses due to absorption in the OA 7. Additionally, this Emitter 1 does not have any basic limitations in size or shape of the near field emission and consequently, could have high emission power and high light power. One or more of the OA 7 cones can advantageously be made with a large diameter (not shown in FIGS. 17 and 18) in order to connect one or several conducting wires 20 to the side of the OA 7.

[0128] In another embodiment of the Emitter 1 shown in FIGS. 2 and 8, the linear slope angles ψ, measured between side surface 8 of a conical OA 7 and the injection area plane 10, is (3π/4−φ/2), which in this case corresponds to, 126° (or 125° 30′ in another embodiment). Consequently, the emission in the near field has a shape of a ring 900 μm wide and is localized at the exterior most regions of exterior surface 9 of the OA 7 (i.e., the emission is located at the positions where it is reflected off the side surface 8 of the OA 7). Spontaneous emission exits the OA 7 in a direction perpendicular to the surface shown where the spontaneous emission emerges. Antireflection coatings 23 are formed on this surface. The coefficient μ for this Emitter 1 equals 0.685. Accordingly, the coefficient ηα, and consequently, the coefficient η are reduced in comparison with those values for the first embodiment of the Emitter 1. The other characteristics of the Emitter 1 of the second embodiment resemble those of the first embodiment.

[0129] FIG. 3 illustrates another embodiment of Emitter 1 wherein the slope angles ψ of the side surface 8 of a conical OA 7 defined with respect to the plane of the injection area 10 equal (π/4−φ/2), which is equal to 36° in this case (or 35° 30′ in one embodiment). Emission emerges from the inner surface 6 at the exterior regions of the annular OA 7. These exterior regions of the annular OA 7 have the antireflection coating 23 thereon and are free of the heterostructure 2, the contact 11 and the contact layer 17. In this embodiment, the coefficient μ is equal to 1.435.

[0130] In yet another embodiment of the Emitter 1 illustrated in FIGS. 4 and 9, the OA 7 comprises a right circular cylinder with a diameter Dis equal to 3,000 μm. In FIGS. 4 and 9, the heterostructure 2 with the OA 7 attached yields an effective refractive index nef that produces a propagation angle φ as defined in Equation (2) that does not exceed an angle σ (the angle of total internal reflection), which equals 16° 50′. This requirement was satisfied for this Emitter 1, by increasing the thickness of the cladding sublayer I2 14 and the cladding sublayer II1 15 to 0.1 μm, while reducing the thickness of the cladding sublayer II2 16 to 0.1 μm. (See Table 1 & 2.) Employing these thicknesses reduced the angle φ to 16° 30′. Additionally, in contrast to the embodiments described above, in this Emitter 1, some of the spontaneous emission emerges, while some is reflected from the side surface 8. The reflected light is reflected several more times before it emerges from the OA 7 (see FIG. 4). The number of these reflections depends on the reflection factor Rn for spontaneous emission at output surface of the OA 7 with inclined incidence on it, which, in turn, depends on the angle of incidence of emission on side surface 8, equal to the angle φ. In the Emitter 1 of FIGS. 4 and 9, movement of the beam in the OA 7 is orderly, which makes it possible for the beam to emerge from the OA 7 with low losses. The thickness of the OA 7 is advantageously selected to be 3,000 μm, which ensures three reflections of the beams before they reach the exterior surface 9. The angle of emission incidence on the side surface 8 of the OA 7 equals 16° 30′, while the angle of refraction is equal to 79° 20′. Other calculation data are:

[0131] the factor αout of the directional emission equals 966 cm−;

[0132] the coefficient ηin equals 0.9872 (or in one embodiment 0.9947);

[0133] the coefficient ηαequals 0.9098;

[0134] Rn for non-polarized spontaneous emission equals 0.4198; and

[0135] with three reflections inside the OA 7, the external efficiency θ equals 0.8098 (or 0.8314 in one embodiment).

[0136] The quantity η was calculated using the following formula that was obtained for an Emitter 1 embodiment having inclined spontaneous emission incident on the output surface (in particular, with a cylindrical OA 7):

η=η1×ηin×ηα×(1−Rn)×[1+(ηα×Rn)1+(ηα×Rn)2+(ηα×Rn)3+ . . . ]  (13)

[0137] Thus, with the current J equal to 7.065 A (j equals 100 A/cm2), the P from Equation (12) equals 11.74 W, Plight equals 4,653 lumens, and Qlight equals 18,276 cd. In one embodiment, P equals 12.05 W, Plight equals 4,777 lumens, and Qlight equals 18,764 cd.

[0138] Note that in formulas (10) and (13) presented above for calculation of the external efficiency η, does not include the coefficient η0, determining spontaneous emission losses connected with the fraction of emission photons which are not captured by heterostructure 2 with adjoining output area 7, or more precisely, the waveguide formed by active layer 3 and cladding layers 4 and 5 in heterostructure 2. The value of the coefficient η0 for low current densities is approximately equal to the numerical aperture of the aforementioned waveguide, and for current densities exceeding the current density for inversion of carriers in the active layer, the coefficient η0 may be close to unity. In the modifications of Emitter 1 presented, in estimation of the external efficiency η, and also the power characteristics P, Popt, and Qopt dependent thereon, corrections connected with the specific value of the coefficient η0 should be taken into account.

[0139] The OA 7 for another embodiment of the Emitter 1 is shown in FIGS. 5 and 10. The OA 7 of FIGS. 5 and 10 is made as a rectangular parallelepiped, and comprises two layers 24 and 25 whose refractive indices are defined by the correlation (1); however, in this case, the refractive index of layer 25 is greater than the refractive index in the layer 24. Both the layer 24 and the layer 25 are conducting layers. The inner surface 6 as well as the injection area 10 are shaped as rectangles. The factor Rn, in contrast to the previous embodiments, depends on the emission incidence angle in the horizontal plane on the sides of the OA 7, and changes from 0.3 to 1. This results in a certain decrease in external effectiveness for this embodiment. The emission divergence angle θ2 in the horizontal plane, after emergence of emission from the OA 7 for each side, equals π radians. The aforementioned dual-layer OA 7 composition reduces the total OA 7 thickness. Other characteristics and features of the Emitter 1 of FIGS. 5 and 10 are similar to the previous embodiments. Note that the Emitter 1 of FIGS. 5 and 10 is the easiest to manufacture.

[0140] For the aforementioned embodiments of FIGS. 1-4, in order to simplify the manufacturing technology and to lower the net cost of the Emitters, the antireflection coatings 23 need not be applied to the output surfaces of the OA 7. However, multiple reflections from the side surface 8 of the OA 7 (as shown in FIGS. 4 and 5, and as well as being defined in formula (13)) may result. In addition, multiple re-emissions from the injection area 10 of emissions reflected into it from the side surface 8 of the OA 7 (as illustrated in FIGS. 1, 2 and 3, as well as being defined in formula (10)) may be produced. As a result of the two effects, the external efficiency factor (formula (10) and formula (13)) could be somewhat smaller than when antireflection coatings are employed. Note also that in order to simplify the production technology of the proposed Emitters 1, the injection areas 10 of the Emitters 1 may be formed without barrier regions (see, for example, FIGS. 1-5).

[0141] Also as in the preceding embodiment (see FIG. 5 and FIG. 10), in the next embodiment of Emitter 1, the output region 7 is implemented as a rectangular parallelepiped and consists of two electrically conductive layers 24 and 25. But in this case, the refractive index noa2 of layer 25 is not only less than the refractive index noa1 for layer 24, but is also less than neff. The distinguishing condition that noaq be greater than neff is not extended to the other layers of output region 7, besides its first layer. Further, to reduce the ohmic resistance, a contact layer made from semiconductor with a bandgap of width less than in layer 25 is applied to the outer surface 9 of layer 25 of output area 7, and the injection area in the plane of the layers of heterostructure 2 is limited in size by means of insulating barrier layers. The injection area is shaped as a rectangular strip, and its length lia, for example, equal to the length lis of the inner surface of the rectangular parallelepiped of output region 7, is greater than the width W of the injection area by approximately an order of magnitude or more.

[0142] By selecting the current density passing through the injection area to exceed the current density for inversion of carriers in the injection area, we may ensure predominantly forced recombination of electron-hole pairs with generation of stimulated emission. In conventional superluminescent emitters (see, for example, A. T. Semenov et al., Electron. Lett., v.29, pp. 854-857 (1993)), this stimulated emission, called superluminescent emission, is directed through the waveguide (formed by active layer 3 and cladding layers 4 and 5 of heterostructure 2) along the long side of the injection area strip. In this embodiment of the Emitter 1, superluminescent emission leaks into the first layer 24 of output region 7 as two plane waves (this is an approximation, but sufficiently acceptable) at propagation angles φ (see Equation 2) in two mutually opposite directions. In this case, if the thickness toa1 of layer 24 is less than lis multiplied by tanφ, then a certain fraction of the outgoing leakage superluminescent emission, after incidence on the second layer 25 of output area 7, is totally reflected therefrom. After this, the reflected radiation goes back into the aforementioned waveguide of heterostructure 2, and then the process of leakage of superluminescent emission into layer 24 followed by total internal reflection from layer 25 is repeated again. The number of such multiple reflections of the rays is mainly determined by the magnitude of the angle φ (see Equation 2), the thickness toa1 of layer 24 of output area 7, and the length lia of the injection region. The stimulated emission will exit mainly through the opposite lateral planes (width W) of the first layer 24. In preferred embodiments, antireflective coatings should be applied to the aforementioned lateral surfaces of Emitter 1 in order to increase the external efficiency η. In individual cases, it may be advisable to apply a coating with a specified reflection coefficient. This may make it possible to reduce the operating currents for which a specified value of the external efficiency is achieved.

[0143] Selection of the compositions and thicknesses of the layers of heterostructure 2 and output area 7, ensures that (for a specified range of operating current densities) leakage of superluminescent emission from the heterostructure 2 into the first layer 24 of output area 7 at such a rate that the gain for the radiation in the waveguide of heterostructure 2 will be sufficiently low so that, without any special measures being taken (as, for example described in the paper by Ching-Fuh Lin et al., IEEE Technol. Letters, v.8, No. 2, pp. 206-208 (1996)), no lasing occurs. In this case, for appropriate values of the operating currents, we may achieve high values of the external efficiency η for the injection incoherent emitter, and high values of the radiation output power P. In practice, the major radiation losses in this modification of Emitter 1 may be determined mainly by absorption of radiation as it passes through layer 24 of output area 7, i.e., in this case, η is approximately equal to ηα (see Equation 11).

[0144] The nearfield radiation area of Emitter 1 on the lateral planes of the first layer 24 will be limited by the dimensions of the rectangle, one of whose sides is slightly greater than the thickness toa1 of layer 24, and the other side of which is slightly greater than the width W of the injection area strip. The angle of divergence θ1 in the vertical plane may be estimated as approximately equal to the wavelength λ divided by the thickness toa1 of the first layer 24 of output region 7. By selection of the thickness toa1 (preferably from the range 1 μm to 100 μm), we can not only decrease the angle of divergence θ1 on the output surface of Emitter 1, but we can also significantly reduce the radiation density on its output surface, which is important for achieving high radiation power.

[0145] From preliminary measurements of the first experimental models of the embodiment of the Emitter 1 (for λ equal to 810 nm, for toa1, lis, and W equal to 3 μm, 1000 μm, and 150 μm respectively), it follows that the external efficiency η may be greater than 60%, the power of the emitter may be more than 8 W, and the angles of divergence, the angles θ1 and θ2 (i.e., the angle in the horizontal plane), may be less than 20° and 7° respectively.

[0146] In the next embodiment, in contrast to the preceding one, the injection area is made in the form of a narrow (preferably of width≈2-5 μm) and long (preferably of length from 0.5 to several mm) rectangular strip, flaring out (preferably with flare angle 5° to 15°), the length of the flared section of which may be preferably from 0.5 to 2 or more millimeters. Such a configuration makes it possible to reduce the operating currents of Emitter 1 for which predominantly stimulated emission occurs (i.e., θ0 approaches unity). This in turn leads to further increase in the external efficiency. Further, the configuration of the injection area in question makes it possible to substantially reduce the angle of divergence θ2 of the radiation in the horizontal plane when emerging from the flared end of the strip.

[0147] In a number of cases, embodiments of Emitter 1 are possible, similar to those considered above, in which a two-layer output area 7 is made on both sides of active layer 3 of heterostructure 2, and also embodiments in which the role of the second layer 25 of output region 7 is played by the optically mirrored outer surface 9 of the first layer 24 of output region 7.

[0148] It is important to note that due to the decrease in the thicknesses toa1 and toa2 in the embodiments considered above with a two-layer output area 7, wafer bonding technology is not needed, and heterostructure 2 and output area 7 may be fabricated in a single epitaxial growth production process. This simplifies the fabrication technology for the emitters and makes it less expensive, and makes it a general-purpose technology as applied to different wavelengths.

[0149] In another embodiment, a more effective coupling of powerful Emitters with a power source that provides increased voltage can be achieved by forming the injection areas 10 and electrical connections thereto with barrier areas 26 and 27 introduced between the injection areas 10, as shown in FIG. 6. The OA 7 in FIG. 6 comprises an electrical conducting layer 28 and an insulating layer 29. The barrier layer 26 on one side of injection area 10 provides electrical isolation, at least up to the cladding layer 5. The barrier layer 27 on the other side of the injection area 10 provides electrical isolation, at least up to the insulating layer 29 of the OA 7. In this embodiment, independent ohmic contacts 30 of the two neighboring injection areas 10, which are separated by barrier layer 27, are connected in pairs by metal coating layers 31, as shown in FIG. 6.

[0150] As shown in FIGS. 12 and 13, for embodiments of the Emitter 1 having near field emissions of a small spatial extent and an enhanced emission brightness, can be made with an OA 7 comprising a hexahedron whose internal surface 6 and external surface 9 are rectangles. The sides of the rectangle of the inner surface 6 are 1,000 μm×3,000 μm. The injection area 10 has the same dimensions and the same area. The side surfaces 8 of the hexahedron form 4 faces. An antireflection coating 23 is formed on one of the faces (output surface), and reflecting coatings 32 are formed on the remaining three faces. All the faces have the same slope angles ψ, equal to (π/2−φ), which, is 72° (or in one embodiment 71°). In the working device, the emission falling on the three faces will be reflected and returned to the injection area 10 at the same propagation angle φ equal to 18° (or in one embodiment 19°). Note that the full divergence angle Δφ, in the same way as for the aforementioned embodiment of FIG. 1, equals 0.68° (11.8 mrad). The quantity Δφ/2 equal to 0.34° corresponds to the accuracy with which sloped edges of OA 7 must be made for Emitter 1 to reach maximum efficiency. An evaluation demonstrates that most of this returned emission will be extracted from OA 7 through the output surface approximately with the same external efficiency η as for Emitter 1 of the first embodiment discussed herein. In this case, power P (defined by the formula (12)) equals 5.3W (or 5.36 W) for a current J equal to 3.0 A. The resulting power, relative to a unit of area of the near field emission, equals 800.6 W/cm2 (or 809.9 W/cm2), which is almost ten times higher than for the first embodiment of the Emitter 1. Divergence angles θ1 and θ2 for this Emitter 1 in the vertical and horizontal planes equal 2.3° and 90°, respectively. The light intensity Qlight in this case equals 19,327 (or 19,553 cd in one embodiment).

[0151] Note that the reduction in the dimensions of the spatial extent of the near field emission and the increase in the brightness of the near field emission can also be obtained for other embodiments of the Emitter 1 that are illustrated in FIGS. 2 and 8, in FIGS. 3 and 9, in FIG. 4, and in FIGS. 5 and 10, by applying reflecting coatings on some of their output surfaces.

[0152] FIGS. 14, 15 and 16 illustrate further embodiments of the Emitter 1 with a set of independently controllable beams. In the embodiment of FIGS. 14, 15 and 16, 200 linear sequences (lines) of injection areas 10 are formed on the layer 5 of the heterostructure 2 using barrier regions 26. Each of the linear sequences (lines) comprises 500 injection areas 10. The diameter of each injection area 10 equals 18 μm, and with the same spacing of 30 μm. The injection areas 10 are arranged in two mutually perpendicular directions. Each line corresponds to the OA of a linear sequence of right circular cylinders with a diameter of 18 μm. The cylinders are coaxial with each injection area 10 in the line, and are linked by connectors 22 to create a common linear OA 33 that is 9 μm thick. Each connector 22 is 12 μm long and is 6 μm wide. The total size of the Emitter 1 in FIGS. 14, 15 and 16 is 15 mm×6 mm. On the exterior surfaces 9 of the common OA 33 of each line, the ohmic contacts 12 are formed with metal coating layers 34 on them, corresponding to 200 bands. From the opposite side to the injection areas 10, independent ohmic contacts 30 and metal coating layers 31 (500 bands) connect the injection areas 10 in a direction perpendicular to the line length. Preparation for the Emitter 1 uses the known methods of planar technology, including photolithographic processes with double-sided bonding, and chemical assisted ion-beam etching (CAIBE). During manufacture, the Emitter 1 is installed on the fixing plates that are not shown in the figures. Calculations made for this Emitter 1 yielded the following results:

[0153] Output emission oriented at 10° 40′ angle to side surface 8 of OA 7 has a divergence Δφ equal to 9° 10′;

[0154] External efficiency factor η for three reflections equals 0.9566 (or in one embodiment 0.9821);

[0155] Power P (from formula (12)) from one injection area 10 is 2 mW for a current of 1.017 mA or in one embodiment 1.044 mA (j equals 400 A/cm2);

[0156] Each emission beam (of 10,000 beams) can be engaged independent of the others; and

[0157] Beam density is 11,111 cm−2.

[0158] FIGS. 19 and 20 set forth the results of preliminary measurements of an experimental Emitter model produced in accordance with the present invention. The results confirm that the present invention generates spontaneous emission having a narrow beam pattern. The Emitters that were used in the preliminary measurements are based on a special calculated heterostructure (made of GaInAs/GaAs/AlGaAs compounds) that provides intensive emission efflux for a wavelength of 980 nanometers. The injection area has dimensions 50 μm×500 μm. The OA 7 is a hexahedron with the side surfaces 8 of three faces at slope angles ψ equal to 90°, and with one output side surface 8 on a face at a slope angle ψ equal to 72°. In the experimental embodiment used for the measurements, there are no coatings on the Emitter 1. It follows from the measurement data (e.g., the curve 35 in FIG. 19), that the divergence angle θ1 of the spontaneous output emission (at level 0.5) in the vertical plane equals 3.3°. In this case, the emission is sloped to the active layer plane at an angle of 19°, which compares well with the calculation angle of 18.5°. In the horizontal plane, as expected, emission is essentially not directed (see the curve 36 in FIG. 19). The measurement results of the watt-ampere characteristic curve (the curve 37 in FIG. 20) indicate that it is possible to obtain high efficiency for the Emitters 1 in accordance with the preferred embodiments of the present invention. Note that the measurements are made for an experimental model that is not of the optimal design, the power is measured from the inclined side face, and the width of the injection area in this case is 50 μm. Note also that in a continuous operating mode, there is a linear dependence of the power P (in milliwatts) on the working current J (in milliamperes) all the way to current densities j equal to 400 A/cm2. This indicates satisfactory heat removal in the Emitters of the present invention.

[0159] FIGS. 21 and 25 schematically present additional embodiments of the Emitter 1 that are implemented as a rectangular parallelepiped and with three injection areas 10, a middle and two edge regions, (not shown in FIGS. 21-25) disposed along a single line in active layer 3. In the middle portion of the Emitter 1, the injection area has the shape of a rectangular strip whose length is at least several times greater than its width. On the cladding layer 4 side, the middle injection area has an independent ohmic contact 30, which makes it possible to pass a current density through it that is different from the current density in the other two edge output areas 7. The edge injection areas have a flared funnel shape, as shown in FIG. 25. Antireflective coatings 23 (not shown in FIGS. 21-25) are applied to the output surfaces of Emitter 1. Output areas 7 in the edge injection areas comprise a single layer whose thickness is at least equal to the product of the length lia of the edge injection areas 10 multiplied by tanφ. The thicknesses of the cladding layer 5 are different in the middle and edge portions of Emitter 1 (see FIG. 21). Consequently, strong leakage of radiation occurs in the edge injection areas, while virtually no leakage occurs in the middle injection area. This circumstance, in aggregate with the selected dimensions of the middle injection area (length preferably from 0.5 mm to 1.0 mm and width preferably from 2 μm to 5 μm.), for low current densities, should ensure a predominant specific fraction of stimulated emission propagating along the length of the middle strip injection area in two mutually opposite directions. With a further increase in current, stimulated (superluminescent) emission is fed from the middle injection area to the edge injection areas, and the emission with a high degree of efficiency initiates conversion of electrical power, supplied to the edge injection regions, to superluminescent radiation power, with its subsequent output from output area 7 with small angles of divergence in both the vertical and horizontal planes. In this case, the previously introduced coefficient η0, appearing in the formula for calculating the external efficiency η, will be close to unity.

[0160] This embodiment permits further reduction in the operating currents for Emitter 1 for which predominantly stimulated (superluminescent) emission is realized. This makes it possible to achieve high external efficiency (greater than 60% to 70%) and output power (greater than 5 W to 10 W from one Emitter 1) with high quality of their emission and operational reliability.

[0161] In another embodiment, the edge portions of Emitter 1, output area 7 comprises of two electrically conductive layers 24 and 25, where the refractive index noa2 of the second layer 25 is less than the effective refractive index neff of heterostructure 2.

[0162] The thickness of the first layer 24, in contrast to the preceding embodiments of Emitter 1, may be significantly less than the product of the length lia of the edge injection areas multiplied by tan φ. Emitters 1 with a similar two-layer output aera 7 have been discussed above. Introducing an independent contact to the middle injection area and using the middle injection area of heterostructure 2 without leakage of radiation not only simplifies fabrication, but also to provides enhanced performance.

[0163] In another embodiment (not shown) the contact layer 17 and ohmic contact 11 are made continuous, i.e., independent contact 30 is omitted and there is no need to separately power the injection regions. An advantage of such an Emitter 1 is its operational simplicity.

[0164] In yet another embodiment depicted in FIGS. 23 and 25 leakage of radiation occurs in it on both sides of active layer 3. This is achieved by selection of the thicknesses of cladding layers 4 and 5, which are identical for all three injection regions of Emitter 1. Accordingly, Emitter 1 contains, on both sides of active layer 3, two two-layer output areas 7, in each of which there are two electrically conductive layers 24 and 25, where the refractive indices noa2 of layers 25 are preferably less than the effective refractive index neff.

[0165] In another embodiment depicted in FIGS. 24 and 25 all three injection areas, both the one-layer output region 7 and the cladding layers 5 are substantially identical.

[0166] The presence of independent contact 30 made to the middle injection region makes it possible to increase the current density through it up to the level at which the relative fraction of leakage radiation becomes small compared with the superluminescent emission going out from the middle injection area to the edge injection areas. In this case, in order for the aforementioned level of the current density to be attainable and acceptable, heterostructures 2 are selected by numerical calculation to have a steep slope for the dependence of the resultant modal gain in heterostructure 2 on current density. Specifically, such behavior is characteristic of the types of heterostructures 2 selected in the preceding two embodiments of Emitter 1. An advantage of the last two embodiments of Emitter 1 is simplification of their fabrication technology. They are also preferably used in pulsed mode.

[0167] Note that in a number of cases, embodiments can be used that, in contrast to those presented in FIGS. 21 and 25, contain two out of the three injection areas. Further, in a number of cases the injection areas may have the shape of rectangular strips. Also note that further increase in the radiation power may be achieved by integrating several modifications of Emitter 1 of the same type in a single chip.

[0168] Injection incoherent Emitters are used in information display devices such as light-emitting indicators, traffic signals, fall-color displays, screens, and projection televisions. Such Emitters can be employed in fiber-optic communications and in information transmission systems. Additionally, injection incoherent Emitters can be used in developing medical equipment and for exciting solid-state and fiber lasers and amplifiers. These Emitters can also be employed as white light LEDs instead of traditional incandescent bulbs and fluorescent light sources.

[0169] Various embodiments of the present invention have been described above. Although this invention has been described with reference to these specific embodiments, the descriptions are intended to be illustrative of the invention and are not intended to be limiting. Various modifications and applications may occur to those skilled in the art without departing from the true spirit and scope of the invention as defined in the appended claims.

TABLE 1
Designation,						Coefficient
No. of layers,		Layer	Index of		Carriers	of optical
sublayers,	Composition	thickness,	refraction,	Conductivity	concentration	losses,
regions	of layer	d, microns	n	Type	N, cm−3	α, cm−1
1	2	3	4	5	6	7
Contact layer 17	GaAs	0.3	3.878	P	2 × 1019	104
Cladding layer 4
with sublayer 14	(Al0.7Ga0.3)0.5In0.5P	1.2	3.241	P	5 × 1017	1.0
and sublayer 13	(Al0.5Ga0.5)	0.07	3.341	—	—	1.0
	0.5In0.5P
Active layer 3	(Al0.22Ga0.78)	0.008	3.482	—	—	5.0
0.5In0.5P
Cladding layer 5
with sublayer 15	(Al0.5Ga0.5)	0.07	3.341	—	—	1.0
	0.5In0.5P
and sublayer 16	(Al0.7Ga0.3)In0.5P	0.2	3.241	N	5 × 1017	1.0
Outlet region 7	GaP	921	3.46	N	1 × 1018	0.6

[0170]

TABLE 2
Designation,						Coefficient
No. of layers,		Layer	Index of		Carriers	of optical
sublayers,	Composition	thickness,	refraction,	Conductivity	concentration	losses,
regions	of layer	d, microns	n	Type	N, cm−3	α, cm−1
1	2	3	4	5	6	7
Contact layer 17	GaAs	0.3	3.878	P	2 × 1019	104
Cladding layer 4
with sublayer 14	(Al0.7Ga03)0.5In0.5P	1.2	3.241	P	5 × 1017	5.0
and sublayer 13	(Al0.5Ga0.5)	0.07	3.341	—	—	5.0
	0.5 In0.5P
Active layer 3	(Al0.22Ga0.78)	0.008	3.482	—	—	5.0
	0.5 In0.5P
Cladding layer 5
with sublayer 15	(Al0.5Ga0.5)	0.07	3.341	—	—	5.0
	05 In0.5P
and sublayer 16	(Al0.7Ga0.3)In0.5P	0.2	3.241	N	5 × 1017	5.0
Outlet region 7	GaP	921	3.46	N	1 × 1018	0.6

Claims

1. An injection incoherent Emitter comprising: a heterostructure comprising: at least one active layer; cladding layers; and at least one ohmic contact, and at least one emission output area on at least one side of the active layer, the emission output area adjoining the heterostructure, the emission output area being transparent for emission, the emission output area comprising at least one emission output area layer having a refractive index noaq, where q=1, 2, . . . p is defined as a whole number that designates the ordinal number of the emission output area layer enumerated from a boundary of the emission output area with the heterostructure, the emission output area and the heterostructure together having an effective refractive index nef, the effective refractive index nef of the heterostructure and the emission output area and the refractive index noa1 of the emission output area being selected to satisfy the correlations:arc cos(nef/noa1)≦arc cos(nef min/noa1)andnef min is greater than nmin,where nef min is the minimum value of nef for heterostructures and adjoining emission output areas that produce spontaneous emission, and where nmin is the least of the refractive indices in the heterostructure cladding layer.

2. The injection incoherent Emitter as defined in claim 1, wherein the active layer of the heterostructure comprises at least one sublayer.

3. The injection incoherent Emitter as defined in claim 1, wherein a first cladding layer is located on a first surface of the active layer and a second cladding layer is located on a second surface of the active layer, the first cladding layer comprising a plurality of cladding sublayers Ii where i=1, 2, . . . k, the second cladding layer comprising a plurality of cladding sublayers IIj, where j=1, 2, . . . m, where i and j are defined as whole numbers that designate the ordinal number of respective cladding sublayers enumerated from the active layer, the cladding sublayers having respective refractive indices nIi and nIIj.

4. The injection incoherent Emitter as defined in claim 3, wherein at least one heterostructure cladding layer is formed as a gradient.

5. The injection incoherent Emitter as defined in claim 1, wherein the heterostructure comprises at least one injection area.

6. The injection incoherent Emitter as defined in claim 5, wherein: the injection area has dimensions and an area Sia and the emission output area has a surface adjoining a boundary layer of the heterostructure with dimensions and an area Sis; and the dimensions and area Sia of the injection area do not exceed the dimensions and area Sis of the emission output area surface adjoining the boundary layer of the heterostructure.

7. The injection incoherent Emitter as defined in claim 1, wherein each cladding layer has a respective thickness, the thickness of the cladding layer adjoining the emission output area being less than the thickness of the cladding layer located on the opposite side of the active layer.

8. The injection incoherent Emitter as defined in claim 1, wherein each cladding layer has a respective refractive index, the refractive index of the cladding sublayer adjoining the emission output area being greater than the refractive index of the cladding sublayer located on the opposite side of the active layer.

9. The injection incoherent Emitter as defined in claim 1, wherein the emission output area layer has a thickness doaq in the range 1 μm to 10,000 μm.

10. The injection incoherent Emitter as defined in claim 1, wherein the emission output area is conducting.

11. The injection incoherent Emitter as defined in claim 10, wherein: the emission output area has an internal surface and at least one exterior surface opposite the internal surface; and ohmic contact is formed to the at least one exterior surface of the emission output area.

12. The injection incoherent Emitter as defined in claim 1, wherein the emission output area comprises optically homogeneous material.

13. The injection incoherent Emitter as defined in claim 1, wherein: the emission output area comprises at least a first layer and a second layer; the first layer borders the heterostructure, conducts, and comprises a material having an optical loss factor αoa1; and the second layer comprises material that has an optical loss factor αoa2 that is lower than the optical loss factor αoa1 for the first layer.

14. The injection incoherent Emitter as defined in claim 13, wherein the second layer is insulating.

15. The injection incoherent Emitter as defined in claim 14, wherein: the heterostructure includes at least two neighboring injection areas, the neighboring injection areas being electrically separated at least to the insulating second layer of the emission output area; and the neighboring injection areas include ohmic contacts that are electrically connected by a metal coating layer.

16. The injection incoherent Emitter as defined in claim 13, wherein the first layer has a refractive index noa1 and the second layer has a refractive index noa2, the refractive index noa2 of the second layer being smaller than the refractive index noa1 of the first layer.

17. The injection incoherent Emitter as defined in claim 1, wherein at least one layer of the emission output area comprises a semiconductor.

18. The injection incoherent Emitter as defined in claim 1, wherein at least one layer of the emission output area comprises a substrate material.

19. The injection incoherent Emitter as defined in claim 1, wherein an ohmic contact is made to a first emission output area layer, said layer being conductive.

20. The injection incoherent Emitter as defined in claim 1, wherein the emission output area comprises at least one truncated right cone, the cone having at least one base located on the heterostructure.

21. The injection incoherent Emitter as defined in claim 20, wherein: the truncated right cone of the emission output area has a side surface and an inner surface; the side surface is generated by a generatrix having a linear slope angle ψ with respect to the inner surface, the angle ψ selected to be in the range (π/2−φ−σ) to (π/2−φ+σ), wherein: φ is a propagation angle between a plane defined by the active layer and a perpendicular to an emission front propagating in the emission output area; and σ is an angle of total internal reflection from the side surface for emission propagating in the emission output region.

22. The injection incoherent Emitter as defined in claim 20, wherein: the truncated right cone of the emission output area has a side surface and an inner surface; the side surface is generated by a generatrix having a linear slope angle ψ with respect to the inner surface, the angle ψ selected to be in the range (3π/4−φ/2−σ/2) to (3π/4−φ/2+σ/2), wherein: φ is a propagation angle between a plane defined by the active layer and a perpendicular to an emission front propagating in the emission output area; and σ is an angle of total internal reflection from the side surface for emission propagating in the emission output region.

23. The injection incoherent Emitter as defined in claim 20, wherein: the truncated right cone of the emission output area has a side surface and an inner surface; the side surface is generated by a generatrix having a linear slope angle ψ with respect to the inner surface, the angle ψ selected to be in the range (π/4−φ/2−σ/2) to (π/4−φ/2+σ/2), wherein: φ is a propagation angle between a plane defined by the active layer and a perpendicular to an emission front propagating in the emission output area; and σ is an angle of total internal reflection from the side surface for emission propagating in the emission output region.

24. The injection incoherent Emitter as defined in claim 1, wherein the emission output area is formed as at least one right circular cylinder, the cylinder having a base located on the heterostructure.

25. The injection incoherent Emitter as defined in claim 1, wherein the emission output area is formed as at least one hexahedron, the hexahedron having a base located on the heterostructure.

26. The injection incoherent Emitter as defined in claim 25, wherein: the at least one hexahedron has at least one side surface and an inner surface, the side surface having a linear slope angle ψ with respect to the inner surface is selected from a range of (π/2−φ−Δφ/2) to (π/2−φ+Δφ/2); φ is a propagation angle between a plane defined by the active layer and a perpendicular to an emission front propagating in the emission output area; and Δφ is an emission divergence angle in a vertical plane.

27. The injection incoherent Emitter as defined in claim 25, wherein: the at least one hexahedron has at least one side surface and an inner surface, the side surface having a linear slope angle ψ with respect to the inner surface is selected from a range of (3π/4−φ/2−Δφ/2) to (3π/4−φ/2+Δφ/2); φ is a propagation angle between a plane defined by the active layer and a perpendicular to an emission front propagating in the emission output area; and Δφ is an emission divergence angle in a vertical plane.

28. The injection incoherent Emitter as defined in claim 25, wherein: the at least one hexahedron has at least one side surface and an inner surface, the side surface having a linear slope angle ψ with respect to the inner surface is selected from a range of (π/4−φ/2−Δφ/2) to (π/4−φ/2+Δφ/2); φ is a propagation angle between a plane defined by the active layer and a perpendicular to an emission front propagating in the emission output area; and Δφ is an emission divergence angle in a vertical plane.

29. The injection incoherent Emitter as defined in claim 25, wherein the at least one hexahedron has at least one side surface and an inner surface, the side surface having a linear slope angle ψ with respect to the inner surface of π/2.

30. The injection incoherent Emitter as defined in claim 1, wherein: φ is an angle between a plane defined by the active layer and a perpendicular to an emission front propagating in the emission output area; and σ is an angle of total internal reflection from a side surface of the emission output area for emission propagating in the emission output region, the angle of total reflection σ being greater than the propagation angle φ.

31. The injection incoherent Emitter as defined in claim 1, wherein the emission output area has at least one output surface, at least a portion of the at least one output surface having an antireflection coating thereon.

32. The injection incoherent Emitter as defined in claim 1, wherein the emission output area has at least one output surface, at least a portion of the at least one output surface having a reflection coating thereon.

33. The injection incoherent Emitter as defined in claim 1, wherein the heterostructure comprises at least two injection areas, each injection area having a propagation angle, the propagation angles of the injection areas being the equal.

34. The injection incoherent Emitter as defined in claim 33, wherein an independent ohmic contact is made to each injection area from an external side of the heterostructure.

35. The injection incoherent Emitter as defined in claim 33, wherein each injection area is associated with one of the at least one emission output areas.

36. The injection incoherent Emitter as defined in claim 35, wherein at least two of the injection areas are associated with a common one of the at least one emission output areas.

37. The injection incoherent Emitter as defined in claim 1, wherein the heterostructure comprises a plurality of injection areas having equal dimensions, the injection areas being arranged along a line as a linear sequence of injection areas.

38. The injection incoherent Emitter as defined in claim 37, wherein the plurality of injection areas are electrically connected by a metal coating layer formed in at least one band.

39. The injection incoherent Emitter as defined in claim 38, wherein the heterostructure comprises at least two linear sequences of injection areas, the plurality of injection areas in each linear sequence being connected by a respective band.

40. The injection incoherent Emitter as defined in claim 39, further comprising a band which electrically connects one injection area from each of the linear sequences.

41. The injection incoherent Emitter as defined in claim 1, wherein each injection area is bounded by injected barrier layers.