RU2639263C1 - METHOD OF PRODUCING MULTILAYER HETEROEPITAXIAL STRUCTURES IN AlGaAs SYSTEM BY LIQUID-PHASE EPITAXY METHOD - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to methods for producing multilayer semiconductor structures in an AlGaAs system by the liquid-phase epitaxy (LPE) method. The LPE method is used for producing optoelectronic devices and power electronic devices. When the method is developed, an additional layer of Al_xGa_1-xAs composition of 0.85≤x≤0.95 is grown after the formation of the last functional layer of the heterostructure, followed by removal of the additional layer by chemical selective etching.

EFFECT: improved electrophysical parameters of epitaxial structures grown by liquid-phase epitaxy method, while the precision exception of additional operation to remove excess thickness of the functional layer.

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Description

The invention relates to the field of microelectronic technology, and more particularly to methods for manufacturing multilayer semiconductor structures in an AlGaAs system by liquid phase epitaxy (LPE). The LPE method is used for the manufacture of optoelectronic devices (light-emitting diodes, photodetectors, etc.) and power electronics devices (pin diodes, transistors, etc.).

A feature, and at the same time a drawback, of most implementations of the LPE method is the inability to stop the growth of the epitaxial layer under certain conditions (reaching the required layer thickness, a certain desired temperature, etc.) since the substrate remains under the melt solution up to room temperature when unloading occurs growth device from the reactor. In the preparation of multilayer structures, this refers to the last epitaxial layer. This feature leads to a number of undesirable consequences:

- the excess thickness of the last epitaxial layer formed when it is necessary to stop growth at a sufficiently high temperature;

- the formation in the surface part of the epitaxial layer of a region with properties very different from that of the bulk, especially during rapid cooling when the reactor is pulled out of the furnace, which leads to a sharp change in the composition of the solid solution due to the characteristics of the AlGaAs system state diagram and / or a significant change in the doping level associated with the dependence of the distribution coefficients of impurities on temperature and cooling rate;

- the formation of defects on the surface due to thermal stresses in the heterostructure and the formation of a second solid phase from the components of dopants.

These problems can in principle be irreparable and lead to the complete unsuitability of the grown structure for the further manufacture of devices or to eliminate these consequences, additional technological operations have to be introduced - chemical-mechanical polishing and precision chemical etching. Additional operations lead to a rise in price of the product, and, as a rule, to a deterioration in its quality.

All known methods of stopping the growth of the epitaxial layer are reduced to removing the melt from the surface of the layers after the end of the growth process.

Known methods (US patent 3694275, publ. 26.091972; US; patent 3752118, publ. 08/14/1973), in which bringing the substrates into contact with the molten solution and subsequent removal of the molten solution from the surface of the epitaxial layers is based on immersing the substrates in the solution -melt with their subsequent extraction from it. In devices of this type, this process is carried out either by rotating the device around the longitudinal axis or by vertical movement of the substrates.

The known method (US patent 3853643, publ. 10.12.1974) stop the growth of the epitaxial layer by pulling the substrate from under the melt solution in a device with a number of sliding elements.

However, the removal of the solution-melt from the surface of the layers after the completion of the building process has its drawbacks. They are associated with the surface quality of the layers — the presence of surface irregularities makes it difficult to remove the used melt solution, and crystallization, which continues from the droplets of the melt solution remaining on the surface of the layers when the furnace is cooled to room temperature, causes the appearance of additional irregularities, defects, difficult to remove oxides and local compositional heterogeneities on the surface of epitaxial layers. In most cases, subsequent mechanical removal of the crystallized residues of the melt solution is unacceptable due to occurring violations of the surface of the epitaxial layer, and chemical etching is not always possible due to the difficulty of selecting selectively acting etchants.

The technical problem to which the developed method is aimed is to eliminate the drawback of the LPE method, due to the fact that the formed structure remains under the melt solution when the temperature drops to room temperature with an uncontrolled increase in the external functional layer.

The technical result obtained by the implementation of the developed method consists in improving the electrophysical parameters of epitaxial structures grown by the LPE method, while eliminating the technologically complex additional operation to precisely controlled removal of the excess thickness of the functional layer.

To achieve the indicated technical result, it is proposed to use the developed method, including growing an additional (protective) Al _x Ga _1-x As layer of 0.85≤x≤0.95 after the formation of the last functional layer of the epitaxial structure and its subsequent chemical removal.

The proposed method is based on the features of the state diagram of the ternary Al-Ga-As system. For the entire temperature range used in LPE (500-1000 ° C) in the layers of an Al _x Ga _1-x As solid solution of the composition 0.85≤x≤0.95 upon cooling, the distribution coefficient of aluminum increases and its composition only increases. In this case, when the melt solution is cooled to room temperature, corresponding to the composition of the solid phase 0.85≤x≤0.95, an epitaxial layer of small thickness is formed - not more than 15 microns. The high AlAs content in the protective layer allows the use of selective chemical etching methods for its subsequent removal. At the same time, all the negative phenomena associated with cooling to room temperatures indicated above have been completely eliminated.

When growing epitaxial layers of a composition with an x value of less than 0.85, this technical result is unattainable because the required degree of etching selectivity is not provided. As a result, the protective layer is not completely removed at local sites of the structure surface, and a further increase in the etching duration in order to eliminate these sites leads to a violation of the surface of the last functional layer of the structure, which makes the structures unsuitable for further use.

When growing epitaxial layers of a composition with an x value of more than 0.95, this technical result is unattainable because on the surface of the protective layer, due to the extremely high aluminum content, stable natural oxides are formed that impede uniform chemical etching.

Example 1

Obtaining p-i-n GaAs structures for power diodes.

The components of the initial charge were pre-weighed. The content of gallium arsenide in the molten solution was determined from the calculation of the state diagram of Ga-Al-As. The gallium, charge components, and GaAs p + -type substrates were loaded into a graphite pumping cassette with a vertical arrangement of substrates. The gap between the substrates was chosen 2.5 mm. In a quartz reactor in a hydrogen atmosphere with a dew point of about -80 ° C, preliminary annealing of gallium melts with additional impurities (homogenization) was performed to dissolve all charge components in the melts and to form solution-melts of the required composition for 90 minutes at a temperature of 940 ° C and flow hydrogen through a reactor of 3 l / min, after which the system was cooled to a temperature of 910 ° C, at which the first melt solution was brought into contact with GaAs substrates of p + type conductivity and crystallization of the Ga epitaxial buffer layer began As p-type conductivity 8–11 μm thick with a carrier concentration of about 5⋅10 ¹⁶ cm ^-3 by forced cooling of the growth system at a rate of about 0.7 ° C / min. Then, at a temperature of 900 ° C, melt solutions were changed. The main GaAs pin layer was grown from the second melt solution to a temperature of 850 ° C, where again the melt solutions were changed. Then the last functional layer was grown — a heavily doped n-type contact layer. Then, the last time, melt solutions were changed already for growing a protective Al _x Ga _1-x As layer of composition x = 0.9 in the temperature range 840–835 ° C. After this, the epitaxy was stopped, the system was cooled to room temperature. The graphite cartridge was unloaded, the structures were washed from the remnants of the solution-melt according to standard technology. Then, the protective layer was removed from the obtained structures by selective etching. The removal of the protective layer from the surface of Al _x Ga _1-x As structures of composition x≤0.6 is carried out at a temperature of 110-140 ° C for 20-30 minutes in an etchant that contains components in the following proportions, vol. %:

- phosphoric acid (85%) - 15-25;

- hydrochloric acid (37%) - 15-25;

- glycerin - the rest.

After removing the protective layer, the finished structures had a smooth surface. The thickness of the epitaxial layers was 80 μm, and the concentration of carriers on the surface was in the range (1.5–2.5) × 10 ¹⁸ cm ^–3 . The resulting structures for surface quality fully met all the requirements for the further manufacture of devices.

For comparison, a similar process was carried out, characterized in that the epitaxy was stopped at a temperature of 840 ° C without the use of a protective layer, the system was cooled to room temperature. The graphite cartridge was unloaded, the structures were washed from the remnants of the solution-melt according to standard technology. On the surface of the finished structures, multiple defects were observed in the form of pits and tubercles formed as a result of spontaneous crystallization in the melt. The surface of structures of this quality was unsuitable for further use and required additional processing.

A similar process was also carried out, characterized in that the epitaxy was stopped at a temperature of 600 ° C without the use of a protective layer, the system was cooled to room temperature. The graphite cartridge was unloaded, the structures were washed from the remnants of the solution-melt according to standard technology. The structures had a smooth surface without traces of spontaneous crystallization. The thickness of the epitaxial layers was 140 μm, the concentration of carriers on the surface was (8.5–9.5) × 10 ¹⁸ cm ^–3 . Such a structure was also not suitable for further use, since it had an excess thickness. As a result, an additional expensive chemical-mechanical polishing operation was required to remove the excess epitaxial layer, however, even after it, the basic electrophysical parameters were significantly lower than in the case with the protective layer:

1. Reverse voltage, V (at a reverse current of 10 μA)

- with a protective layer - 800-950;

- without a protective layer - 550-700 (leakage currents were observed);

2. Reverse current, μA (at a reverse voltage of 600 V)

- with a protective layer - 0.5-1.5;

- without a protective layer - 5-50;

Example 2

Obtaining AlGaAs heterostructures for light emitting diodes.

The components of the initial charge were pre-weighed. The content of gallium and aluminum arsenide in the molten solution was determined from the calculation of the Ga – Al – As state diagram. The gallium, charge components, and GaAs p + -type substrates were loaded into a graphite pumping cassette with a vertical arrangement of substrates. The gap between the substrates was 1.5 mm. In a quartz reactor in a hydrogen atmosphere with a dew point of about -80 ° C, preliminary annealing of gallium melts with additional impurities (homogenization) was performed to dissolve all components of the charge in the melts and form solution-melts of the required composition for 90 minutes at a temperature of 840 ° C and flow hydrogen through a reactor of 3 l / min, after which the system was cooled to a temperature of 800 ° C, at which the first solution-melt was brought into contact with GaAs p + -type substrates and crystallization of the Al _x Ga _1-x As co epitaxial layer started tava x = 0.2 p-type conductivity doped with zinc, 8-10 μm thick with a carrier concentration of about 5⋅10 ¹⁷ cm ^-3 , by forced cooling of the growth system at a rate of about 0.5 ° C / min. Then, at a temperature of 770 ° C, melt solutions were changed. From the second melt solution, an active region of a p-type GaAs LED doped with zinc, 1.5–2.0 μm thick with a carrier concentration of about 5 × 10 ¹⁶ cm ^–3, to a temperature of 764 ° C was grown by forced cooling of the growth system with at a rate of about 0.5 ° C / min, where again the melt solutions were changed. An Al _x Ga _1-x As layer of composition x = 0.35 n-type conductivity doped with tellurium, 12-15 μm thick with a carrier concentration of about 1⋅10 ¹⁸ cm ^-3 , was grown from the third melt solution by forced cooling of the growth system at a rate of about 1.5 ° C / min to a temperature of 730 ° C. Then, in the temperature range 730–720 ° C, a protective Al _x Ga _1-x As layer of composition x = 0.9 was grown from the fourth melt solution. After this, the epitaxy was stopped, the system was cooled to room temperature. The graphite cartridge was unloaded, the structures were washed from the remnants of the solution-melt according to standard technology. Then, the protective layer was removed from the resulting structures. After removal of the protective layer, the finished structures had a smooth surface with individual point defects in the form of inclusions of the second phase containing tellurium impurity with a density of 0.23 cm ^-2 .

For comparison, a similar process was carried out, characterized in that the epitaxy was stopped at a temperature of 730 ° C without pouring a protective layer, the system was cooled to room temperature. The graphite cartridge was unloaded, the structures were washed from the remnants of the solution-melt according to standard technology. On the surface of the finished structures, multiple point defects were observed in the form of inclusions of the second phase, apparently containing tellurium with a density of 15.6 cm ^-2 .

Diodes were fabricated from the epitaxial structures obtained in both processes using standard methods of photolithography, etching, sputtering, and contact burning. The results of measuring the electrophysical characteristics of light-emitting diodes have shown that devices obtained using a protective layer have better performance in the following parameters:

1. Radiation power, mW / sr:

- with a protective layer - 1.1-1.2;

- without a protective layer - 0.88-0.95;

2. Reverse current, µA (with a reverse voltage of 6 V):

- with a protective layer - 1.0-1.5;

- without a protective layer - 10.2-20.9.

Thus, the proposed method for producing multilayer heteroepitaxial structures in the AlGaAs system by the HPE method allows one to exclude the precision operation of removing an excessively grown functional layer, replacing it with the operation of removing an additional layer.

Claims (1)

A method for producing multilayer heteroepitaxial structures in an AlGaAs system using the LPE method, characterized in that an additional Al _x Ga _1-x As layer of 0.85≤x≤0.95 is grown after the last functional layer of the heterostructure is formed, followed by removal of the additional layer by chemical selective etching .