RU2461916C1 - Semiconductor light-emitting instrument - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: semiconductor light-emitting instrument based on silicon dioxide includes substrate, upper and lower electrodes and layers formed during magnetron sputtering generating semiconductive heterostructure with p-n junction. Layer of active area with p-n junction is made from porous silicon dioxide (SiO₂ ^M). Width of prohibited zone of layer of active area with p-n junction >4 eV.

EFFECT: providing possibility to reach light radiation in UV band of radiation spectrum, high brightness, simplifying the design and manufacturing procedure of semiconductor light-emitting instrument.

1 dwg, 1 ex

Description

The invention relates to the field of semiconductor light-emitting devices and can be used for the production of LEDs.

A known construction of a semiconductor light emitting device [US 20040113163], including a substrate with a textured layer formed on its surface having a rough surface, as well as layers of nitride material grown by the epitaxy method, forming a semiconductor heterostructure with a p-n junction. Owing to the presence of the indicated textured layer, the microprotrusions and micro-valleys of which form light scattering centers, the effect on the light output of the effect of total internal reflection of light arising at the interface “substrate - material layer adjacent to the substrate” is reduced in the case when the refractive index of the material of the specified layer exceeds refractive index of the substrate material. As a result, the proportion of light emitted through the substrate increases and, thereby, the external optical efficiency of the device increases.

The disadvantage of this design is that in relation to the main technological process of epitaxial growing of semiconductor layers, additional technological operations are required, including, for example, etching of the material of the layer, including the preliminary application of a photomask, and, as a result, complicating the manufacturing technology of a semiconductor light-emitting device . This design has low light output due to the low excitation energy of the phosphor, for conversion to white light.

A semiconductor light emitting device [TW 591808] (the closest analogue) is also known. The device under consideration includes a sapphire substrate, as well as a sequentially located buffer layer and layers forming a semiconductor heterostructure with a p-n junction made of nitride material and grown by epitaxy. In addition, the device under consideration contains an intermediate layer located between the buffer layer and the substrate, which according to one embodiment of the device has pores formed by etching the material of the layer. The pores in the considered intermediate layer are formed in order to reduce mechanical stresses in the material of the semiconductor heterostructure due to the mismatch of the crystal lattice of the substrate material and the material of the semiconductor layers. However, in addition to the indicated function, the pores of the intermediate layer also function as light scattering centers, due to which the effect of total internal light reflection at the “substrate - adjacent to the substrate material layer” effect on the light output is reduced, and, accordingly, the fraction of light output radiation.

The disadvantage of this invention is the complexity of the design of the device and the technology of its manufacture, low light output, due to the low excitation energy of the phosphor, for converting blue light to white.

The purpose of the invention is the manufacture of a semiconductor light emitting device that emits light in the ultraviolet range of the radiation spectrum, followed by its conversion into visible light using a phosphor.

This goal is achieved by using a layer with a pn junction from a porous film of silicon dioxide (SiO ₂ ^m ), obtained by magnetron sputtering of a composite target "silicon-graphite" (Si-C). The recombination of electrons and holes in this layer is accompanied by the emission of light quanta with energies> 4 eV.

The invention is illustrated in the drawing (figure 1). The drawing shows a General view of the claimed device.

The device comprises a substrate 1, on which are sequentially arranged: the lower electrode 2; layers forming a pn-junction heterostructure, including, in particular, n-type conductivity layer 3 made of silicon dioxide (n-SiO ₂ ); a layer of the active region 4 with a pn junction made of porous silicon dioxide (SiO ₂ ^m ); p-type conductivity layer 5 made of silicon dioxide (p-SiO ₂ ); an upper, optically transparent electrode 6 made of a conductive oxide In ₂ O ₃ ; phosphor layer 7.

The device operates as follows. When passing current in the forward direction through the inventive device in the active region 4, recombination of electrons and holes is injected respectively from layer 3 of n-type conductivity and layer 5 of p-type conductivity, which is accompanied by emission of light quanta.

An example of a specific implementation of the device

On the substrate 1, a lower aluminum (Al) electrode 2 is deposited by thermal evaporation in a vacuum. Next, a thin film of silicon dioxide 3 of n-type conductivity (n-SiO ₂ ), 25 nm thick, is deposited onto the electrode by magnetron sputtering, and an active layer is formed on it region 4 with a pn junction made of porous silicon dioxide (SiO ₂ ^m ) by magnetron sputtering of a composite target silicon-graphite (Si-C) with a thickness of 10-20 nm, then a layer of silicon dioxide 5 p-type conductivity (p-SiO ₂ ), 25 nm thick. An optically transparent electrode 6 is formed on layer 5 by magnetron sputtering of indium (In) in an oxygen atmosphere, onto which a phosphor layer 7 is then applied.

Claims (1)

A silicon dioxide-based semiconductor light-emitting device including a substrate, lower and upper electrodes, and also layers formed during magnetron sputtering forming a heterostructure with a pn junction, characterized in that the layer of the active region with a pn junction is made from porous silicon dioxide (SiO ₂ ^M ) with a band gap> 4 eV.

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