CN1252801C - Method for preparaing Al epitaxial layer contained semiconductor material grown on GaAs substrate - Google Patents
Method for preparaing Al epitaxial layer contained semiconductor material grown on GaAs substrate Download PDFInfo
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- CN1252801C CN1252801C CN 03121825 CN03121825A CN1252801C CN 1252801 C CN1252801 C CN 1252801C CN 03121825 CN03121825 CN 03121825 CN 03121825 A CN03121825 A CN 03121825A CN 1252801 C CN1252801 C CN 1252801C
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Abstract
The present invention relates to a method for preparing an Al epitaxial layer containing semi-conductor material grown on a GaAs substrate. The method comprises the steps that the GaAs substrate is arranged in vacuum and the surface of the GaGs substrate is heated to 580 DEG C to remove a surface oxidation film under the protection of As molecular beams in a routine method; then, a GaAs buffer layer is grown through As: Ga beam current; the Al epitaxial layer is grown on the surface of the GaAs buffer layer; finally, a GaAs cover cap layer is covered to obtain the semiconductor material. The present invention is characterized in that the surface of the GaAs substrate is protected by the As molecular beams and In atoms with the As atom mole number of 1 to 10% are added as surface active agent when the Al epitaxial layer is grown on the surface of the GaAs buffer layer. The present invention can enhance the migration length of other atoms on an epitaxial surface so as to achieve the purposes of improving the interface quality and the body quality of multiple layer epitaxial films.
Description
Technical field
The present invention relates to prepare the method for semi-conducting material, particularly prepare a kind of on the GaAs substrate growth contain the method for semi-conducting material of Al epitaxial loayer.
Background technology
The AlGaAs/GaAs heterojunction has been widely used in electricity such as High Electron Mobility Transistor, quantum-well laser and the optics.For a quantum device, perfectly the interface of crystal structure and atomic-level flatness is very important.But because the Al atom has very strong activity, generally, its migration length at epitaxial surface is very little, especially when the Al component surpasses 0.3.Therefore the AlGaAs material of high Al component has more defective usually, and becomes the island easily in the growth course, causes very poor interface quality.So the epitaxial growth of the common III-V compound semiconductor that contains Al is very high to the requirement of growth conditions, such as to V group element such as As, the control of P equivalent is very accurate, if V group element very little, can cause material to break away from stoicheiometry, but too many words can reduce the migration length of Al atom again, and material is not carried out under growth pattern from level to level, have a large amount of dislocations and very coarse interface in the material thereby make.Control to growth temperature also is that so too low growth temperature can reduce the migration length of atom, and too high temperature can make material breakdown.
In order to improve AlGaAs crystal mass and interface quality, once adopted reduction growth rate method and interrupt method to prepare this type of semi-conducting material.Reducing the growth rate method is to adopt to reduce Al and Ga atom line, reduce the molecular beam of As simultaneously, allow the atom of absorption have time enough to move to suitable position, improve the migration length of the growing surface of adatom, reach and improve interface and crystal mass, described in document 1:J.Appl.Phys.54 (1983) 6982.But the method also has some shortcomings: low growth rate also means the increase of background impurity absorption probability, so can increase the background concentration of material, these high background concentrations can cause the weakening of the control of material concentration, and to the suitable adverse influence of having of device; Low growth rate can increase the growth time of material, improves device cost.
Interrupt method; as described in document 2:Jpn.J.Appl.Phys.25 (1986) L155; be meant behind the certain thickness material of growth; take to stop the supply of Al and Ga atom; and only protect the method for growing surface with the As line, at the interruption of growth certain hour, be generally the growth that recovers material after several seconds to a few minutes; the method can allow the III family element of growing surface absorption such as Al, Ga have time enough to move to suitable place and go, thereby reaches the purpose of improving the interface.But interruption can make impurity in the continuous accumulation of interrupting the interface, increases the background concentration of material; And interruption can not reduce the harsh degree of the condition of material growth yet, can not reduce the impurity that is coupled into when growth contains the Al material yet.
Summary of the invention
The objective of the invention is to overcome prior art and prepare background concentration height when containing the Al epitaxial loayer, defect of high cost, thereby the method for the semi-conducting material that provides a kind of preparation on the GaAs substrate, to grow to contain the Al epitaxial loayer, this method can reduce the harsh conditions of material growth, reduce the frequent degree that the material growth conditions changes, reduce the defect density and the background concentration of material, and make the material of preparation have the interface of atomic-level flatness.
The objective of the invention is to realize by the following technical solutions:
The invention provides on the GaAs substrate, the grow method of the semi-conducting material that contains the Al epitaxial loayer of a kind of preparation; with the GaAs substrate in a vacuum; with conventional method its surface is heated to 580 ℃ under the protection of As molecular beam and sloughs surface film oxide; feed As then: the Ga line; growth GaAs resilient coating; contain the Al epitaxial loayer in the regrowth of GaAs buffer-layer surface; cover the GaAs cap layer at last; obtain semi-conducting material; it is characterized in that: at 400~650 ℃; adopt the protection of As molecular beam, when the regrowth of GaAs buffer-layer surface contained the Al epitaxial loayer, 1~10% the In atom that adds As atomic molar number was as surfactant.
A kind of preparation provided by the invention growth on the GaAs substrate contains the method for the semi-conducting material of Al epitaxial loayer, the method that contains the Al epitaxial loayer with the prior art growth is compared, its advantage is: add In as surfactant, can improve the migration lengths on the GaAs substrate such as Al greatly, reduce the harsh degree of material growth conditions; In addition, this method technology is simple, does not need to regulate other parameters, and it is just passable only need to mix a spot of In when growth; And in the grown epitaxial layer process, In can be evaporated again again, can't be because of the composition that changes material that mixes of In; Use this method can obtain the interface evenness of atomic level, and reduce the defective of epitaxial loayer.
Description of drawings
Fig. 1 is the GaAs/Al of embodiment of the invention 1-3
0.4Ga
0.6The low temperature photoluminescence spectrum of three quantum-well materials of As;
Fig. 2 is the GaAs/Al of embodiment of the invention 1-3
0.4Ga
0.6The low temperature photoluminescence spectrum half-peak breadth and the wavelength relationship of three quantum-well materials of As;
Fig. 3 is the GaAs/Al of embodiment of the invention 1-3
0.4Ga
0.6The low temperature light fluorescence intensity of three quantum-well materials of As and the relation of wavelength;
Fig. 4 is the low temperature photoluminescence spectrum of three quantum-well materials of GaAs/AlAs of embodiment of the invention 4-5;
Wherein curve .1 represents In as surfactant;
The common growing method of curve 3 representatives.
Embodiment
Below in conjunction with embodiment and accompanying drawing the present invention is described in detail:
Embodiment 1: with conventional method growth Al
0.4Ga
0.6Three quantum-well materials of As/GaAs
The GaAs substrate is 1 * 10
-10Under the base vacuum of torr, the surface is heated to 580 ℃ and sloughs surface film oxide under the protection of As molecular beam, and with 500nm/ hour GaAs growth rate, Ga: As line ratio was 1: 30 then, and underlayer temperature is at 580 ℃ of thick GaAs resilient coatings of 500nm of growing down.
At 610 ℃, with above-mentioned As molecular beam, on the GaAs buffer-layer surface with 500nm/ hour GaAs growth rate, 833nm/ hour Al
0.4Ga
0.6The As growth rate thick Al of 100nm that grows successively
0.4Ga
0.6As, the GaAs that 5nm is thick, the Al that 50nm is thick
0.4Ga
0.6As, the GaAs that 2.5nm is thick, the Al that 50nm is thick
0.4Ga
0.6As, the GaAs that 1.5nm is thick, the Al that 100nm is thick
0.4Ga
0.6As covers the thick GaAs of 3nm at last and prevents Al
0.4Ga
0.6The oxidation of As does not change the size of growth temperature and As atom flow in whole process.
Embodiment 2: with interrupt method growth Al
0.4Ga
0.6Three quantum-well materials of As/GaAs
The GaAs substrate is 1 * 10
-10Under the base vacuum of torr, the surface is heated to 580 ℃ and sloughs surface film oxide under the protection of As molecular beam, and with 500nm/ hour GaAs growth rate, Ga: As line ratio was 1: 30 then, and underlayer temperature is at 580 ℃ of thick GaAs resilient coatings of 500nm of growing down.
At 610 ℃, with above-mentioned As molecular beam, on the GaAs buffer-layer surface with 500nm/ hour GaAs growth rate, 833nm/ hour Al
0.4Ga
0.6The As growth rate thick Al of 100nm that grows successively
0.4Ga
0.6As interrupted the GaAs that regrowth 5nm is thick, the Al that 50nm is thick 30 seconds
0.4Ga
0.6As interrupted 30 seconds again, the GaAs that regrowth 2.5nm is thick, the Al that 50nm is thick
0.4Ga
0.6As interrupted 30 seconds again, the GaAs that regrowth 1.5nm is thick, the Al that 100nm is thick
0.4Ga
0.6As covers the thick GaAs of 3nm at last and prevents Al
0.4Ga
0.6The oxidation of As does not change the size of growth temperature and As atom flow in whole process.
Embodiment 3: grow to contain on the GaAs substrate with method of the present invention and mix the 1%In atom when Al epitaxial loayer prepares semi-conducting material as the surfactant Al that grows
0.4Ga
0.6Three quantum-well materials of As/GaAs
The GaAs substrate is 1 * 10
-10Under the base vacuum of torr, the surface is heated to 580 ℃ and sloughs surface film oxide under the protection of As molecular beam, and with 500nm/ hour GaAs growth rate, Ga: As line ratio was 1: 30 then, and underlayer temperature is at 580 ℃ of thick GaAs resilient coatings of 500nm of growing down.
At 610 ℃, with above-mentioned As molecular beam, and 1% the In atom that adds As atomic molar number is as surfactant, on the GaAs buffer-layer surface with 500nm/ hour GaAs growth rate, 833nm/ hour Al
0.4Ga
0.6The As growth rate thick Al of 100nm that grows successively
0.4Ga
0.6As, the GaAs that 5nm is thick, the Al that 50nm is thick
0.4Ga
0.6As, the GaAs that 2.5nm is thick, the Al that 50nm is thick
0.4Ga
0.6As, the GaAs that 1.5nm is thick, the Al that 100nm is thick
0.4Ga
0.6As, because In can be evaporated again at 610 ℃, so adding In atom can't change the component of material, In just plays the effect of activator in the material growth, cover the thick GaAs of 3nm at last and prevent Al
0.4Ga
0.6The oxidation of As does not change the size of growth temperature and As atom flow in whole process.
The low temperature light fluorogram of these three embodiment as shown in Figure 1, as can be seen, the half-peak breadth of the quantum well low temperature photoluminescence spectrum that 5nm of the present invention is thick has only 5.1meV, compared with the 16meV of conventional method, interrupt method 7meV is much smaller, as shown in Figure 2, because the half-peak breadth of quantum well low temperature photoluminescence spectrum is proportional with the interface evenness, therefore, can judge that this present invention can improve other III family atoms of elements migration lengths effectively, obtains very smooth interface.In addition, other two kinds of methods of three quantum well radiation strength ratios of the present invention want high 2-3 doubly, and as shown in Figure 3, the raising of this luminous intensity can illustrate that the present invention can effectively suppress the non-radiative recombination center in the AlGaAs material.
Embodiment 4: with three quantum-well materials of interrupt method growth AlAs/GaAs
The GaAs substrate is 1 * 10
-10Under the base vacuum of torr, the surface is heated to 580 ℃ and sloughs surface film oxide under the protection of As molecular beam, and with 1000nm/ hour GaAs growth rate, Ga: As line ratio was 1: 30 then, and underlayer temperature is at 580 ℃ of thick GaAs resilient coatings of 500nm of growing down.
At 600 ℃, on the GaAs buffer-layer surface with 1000nm/ hour GaAs growth rate, 300nm/ hour the AlAs growth rate thick AlAs of 30nm that grows successively, the GaAs that 10nm is thick, interrupted the AlAs that regrowth 30nm is thick, the GaAs that 8nm is thick 30 seconds, interrupted again 30 seconds, the AlAs that regrowth 30nm is thick interrupted the GaAs that regrowth 5nm is thick again 30 seconds, the AlAs that 30nm is thick, cover the thick GaAs of 3nm at last and prevent the oxidation of AlAs, in whole growth process, the Ga during growth GaAs: As line ratio is 1: 30, Al during growth AlAs: As line ratio is 1: 5, and growth temperature is 680 ℃.
Embodiment 5: grow to contain on the GaAs substrate with method of the present invention and mix the 10%In atom when Al epitaxial loayer prepares semi-conducting material as three quantum-well materials of surfactant growth AlAs/GaAs
The GaAs substrate is 1 * 10
-10Under the base vacuum of torr, the surface is heated to 580 ℃ and sloughs surface film oxide under the protection of As molecular beam, and with 1000nm/ hour GaAs growth rate, Ga: As line ratio was 1: 30 then, and underlayer temperature is at 580 ℃ of thick GaAs resilient coatings of 500nm of growing down.
At 630 ℃, with above-mentioned As molecular beam, and 10% the In atom that adds As atomic molar number is as surfactant, on the GaAs buffer-layer surface with 1000nm/ hour GaAs growth rate, 300nm/ hour the AlAs growth rate thick AlAs of 30nm that grows successively, the GaAs that 10nm is thick, the AlAs that 30nm is thick, the GaAs that 8nm is thick, the AlAs that 30nm is thick, the GaAs that 5nm is thick, the AlAs that 30nm is thick, because In can be evaporated again at 630 ℃, so, adding the component that the In atom can't change material, In just plays the effect of activator in the material growth, cover the thick GaAs of 3nm at last and prevent the oxidation of AlAs, in whole process, do not change the size of growth temperature and As atom flow.
The embodiment of the invention 4 and 5 low temperature light fluorogram are as shown in Figure 4, the half-peak breadth of the low temperature photoluminescence spectrum that it is narrow and high luminous intensity explanation the present invention can illustrate that the present invention can effectively improve other III family atoms of elements migration lengths, obtain the non-radiative recombination center in very smooth interface and the inhibition AlAs material.
Embodiment 6: with interrupt method growth transoid High Electron Mobility Transistor (I-HEMT)
The GaAs substrate is 1 * 10
-10Under the base vacuum of torr, the surface is heated to 580 ℃ and sloughs surface film oxide under the protection of As molecular beam, and with 1000nm/ hour GaAs growth rate, Ga: As line ratio was 1: 30 then, and underlayer temperature is at 580 ℃ of thick GaAs resilient coatings of 500nm of growing down.
At 600 ℃, with above-mentioned As molecular beam, on the GaAs buffer-layer surface with 1000nm/ hour GaAs growth rate, 1250nm/ hour Al
0.2Ga
0.8The thick Al of As growth rate growth 100nm
0.2Ga
0.8As interrupted 60 seconds, carried out 1 * 10 then under same As molecular beam condition
12Cm
-2The Si plane doping, 20nm thick Al subsequently successively grows under same condition
0.2Ga
0.8As, the GaAs that 200nm is thick.
Embodiment 7: grow to contain on the GaAs substrate with method of the present invention and mix the 5%In atom when Al epitaxial loayer prepares semi-conducting material as surfactant growth transoid High Electron Mobility Transistor (I-HEMT)
The GaAs substrate is 1 * 10
-10Under the base vacuum of torr, the surface is heated to 580 ℃ and sloughs surface film oxide under the protection of As molecular beam, and with 1000nm/ hour GaAs growth rate, Ga: As line ratio was 1: 30 then, and underlayer temperature is at 580 ℃ of thick GaAs resilient coatings of 500nm of growing down.
At 600 ℃, with above-mentioned As molecular beam, and 5% the In atom that adds As atomic molar number is as surfactant, on the GaAs buffer-layer surface with 1000nm/ hour GaAs growth rate, 1250nm/ hour Al
0.2Ga
0.8The thick Al of As growth rate growth 100nm
0.2Ga
0.8As carries out 1 * 10 then under same As molecular beam condition
12Cm
-2The Si plane doping, 20nm thick Al subsequently successively grows under same condition
0.2Ga
0.8As, the GaAs that 200nm is thick.
The mobility of the two-dimensional electron gas that the suddenly otometry of embodiment 6 and 7 under the 77K temperature obtained is respectively 8350 and 78670cm
2/ Vs, because the mobility of two-dimensional electron gas depends primarily on the impurity in the material and the evenness at interface under the low temperature, therefore, significantly improving of the mobility of embodiment 7 illustrated that the present invention not only can improve the evenness at interface very effectively, can also reduce the impurity concentration in the material.
Claims (1)
1. one kind prepares on the GaAs substrate method that growth contains the semi-conducting material of Al epitaxial loayer; with the GaAs substrate in a vacuum; with conventional method its surface is heated to 580 ℃ under the protection of As molecular beam and sloughs surface film oxide; feed the As:Ga molecular beam then; growth GaAs resilient coating; contain the Al epitaxial loayer in the regrowth of GaAs buffer-layer surface; cover the GaAs cap layer at last; obtain semi-conducting material; it is characterized in that: at 600~630 ℃; adopt the protection of As molecular beam, when the regrowth of GaAs buffer-layer surface contained the binary of Al or polynary semiconducting compound epitaxial loayer, 1~10% the In atom that adds As atomic molar number was as surfactant.
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