Abstract:
A method of using ammonia to form a GaAs alloy with nitrogen atoms is described. The method includes the operation of introducing ammonia with an agent to assist in the breakdown of the ammonia into a reaction chamber with the GaAs film. Agents that are described include radiation as well as compounds that include aluminum.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS  
       [0001]    The present invention is related to co-pending application “A Method of MOCVD Growth of Compounds Including GaAsN Alloys Using an Ammonia Precursor with a Catalyst” by Michael Kneissl (attorney docket No. D/A2561) Ser. No. ______, filed on the same day and assigned to the same assignee which is hereby incorporated by reference in its entirety. 
     
    
     
       FIELD OF THE INVENTION  
         [0002]    The invention relates to the field of semiconductor processing. More specifically, the invention relates to forming a nitrogen containing group III-arsenide compound semiconductor using ammonia as a precursor.  
         BACKGROUND OF THE INVENTION  
         [0003]    Long wavelength lasers, lasers that emit light in wavelengths between 1.3 micrometers and 1.6 micrometers, are highly desirable for telecommunication system use because at these “telecom wavelengths”, a “wavelength window” exists where light absorption in optical fibers is minimized. As telecommunications increasingly rely on optical signal transmission, these long wavelength lasers have become increasingly important.  
           [0004]    Most optoelectronic components in the telecom wavelength range are grown on InP substrates. An InP substrate is preferred because the substrate easily lattice matches with high indium composition InGaAs films used in the fabrication of devices that emit 1.3-1.6 micron wavelength light. However, high substrate costs and low device yields makes InP-based optoelectronic devices rather expensive. Devices based on GaAs substrates would be much cheaper, but the difference in lattice constant normally prevents the growth of InGaAs with high In compositions (˜50% indium mole fraction is preferred to achieve relevant telecom outputs) on GaAs substrate.  
           [0005]    The bandgap in a semiconductor laser determines the frequency of light output by a semiconductor laser. Recently it has been demonstrated that by incorporating small amounts (fraction of a percent to a few percent) of nitrogen into the InGaAs film, the band gap of InGaAs alloys grown on GaAs substrate can be reduced thereby shifting the light emitted by the resulting devices to longer wavelengths. Indium Gallium Arsenide Nitride alloys have been found to be excellent semiconductor materials for fabricating the active region of VCSELS or other long-wavelength optoelectronic devices (e.g. edge-emitting laser, photodetectors or solar cells). Using elementary nitrogen as a group V source and a Molecular Beam Epitaxy (MBE) process, several groups have fabricated InGaAsN based lasers that output 1.3 micrometer wavelength light. See, M. Kondow et al., Jpn. J. Appl. Phys., Vol. 35, 1273 (1996) and M. Kondow, S. Natatsuka, T. Kitatani, Y. Yazawa, and M. Okai, Electron. Lett. 32, 2244 (1996). However, MBE is a slow growth technique and therefore not well suited to mass production of high volume optoelectronic devices such as VCSELs, egde-emitting lasers or solar cells.  
           [0006]    Metal Organic Chemical Vapor Deposition (MOCVD) is a suitable technique for volume production of InGaAsN lasers. However, the high growth temperatures and surface chemistry of MOCVD results in inefficient incorporation of elemental nitrogen (N) in the InGaAsN material. To increase the incorporation efficiency of Nitrogen in the InGaAsN, the Nitrogen is typically introduced in a dimethylhydrazine (DMHy) form as described in J. Koch, F. Hohnsdorf, W. Stolz, Journal of Electronic Materials, Vol. 29, 165 (2000) and A. Ougazzaden et al., Appl. Phys. Lett. 70, 2861 (1997) which are hereby incorporated by reference. Large oversupplies of DMHy are used to achieve sufficient amounts of nitrogen in the InGaAsN structure.  
           [0007]    The use of large quantities of DMHy as a nitrogen source has two major disadvantages. The first disadvantage is high cost. DMHy is expensive, current costs for 100 grams of DMHy is approximately $5000. A second disadvantage of using DMHy as a Nitrogen source is the relatively high impurity levels that often exist in commercially available DMHy. High impurity levels are possibly one reason why MOCVD grown InGaAsN films are often inferior to MBE grown films.  
           [0008]    Thus a better source of Nitrogen for forming InGaAsN structures is needed.  
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0009]    [0009]FIG. 1 shows a MOCVD system configured to use ammonia as a nitrogen source.  
         [0010]    [0010]FIG. 2 is a graph that shows the effect of different nitrogen concentrations on the bandgap energy and on the emission wavelength of a laser.  
         [0011]    [0011]FIG. 3 shows an edge-emitting laser structure with an InGaAsN active region formed using ammonia as a nitrogen source.  
         [0012]    [0012]FIG. 4 shows a graph that shows the effect of changing catalyst concentrations on the nitrogen mole fraction deposited in an active layer.  
         [0013]    [0013]FIG. 5 is a flow chart that describes the operations involved in formation of the semiconductor laser of FIG. 3.  
     
    
     SUMMARY OF THE INVENTION  
       [0014]    An improved nitrogen source to form a sample including both nitrogen and gallium-arsenide is described. In the method, ammonia and a source of gallium and a source for arsine is introduced into the reaction chamber. The ammonia is decomposed releasing nitrogen atoms. A catalyst may be used to facilitate ammonia decomposition. The released nitrogen atoms, the gallium and the arsine together form a film including both nitrogen, gallium and arsine.  
       DETAILED DESCRIPTION  
       [0015]    An improved method of decomposing ammonia to provide a source of nitrogen to form a sample including both nitrogen, gallium and arsenide is described. The method is applicable to various semiconductor growth processes, however, the most important semiconductor process for which the described method may be used is in a MOCVD process. The details of the MOCVD process are described in “Organomtallic Vapor-phase Epitaxy: Theory and Practice” by G. B. Stringfellow, published by Academic Press (1989), which is hereby incorporated by reference.  
         [0016]    [0016]FIG. 1 shows a MOCVD system  100  that uses ammonia gas as a nitrogen source to form an InGaAsN active layer of an optoelectronic device (e.g. VCSEL, edge-emitting laser, or solar cell). In FIG. 1, a film  105  of InGaAsN is grown on a GaAs substrate  104 , supported by support structure  108 . The support structure  108  includes a graphite suspector  112  that rotates on a fiber-pyrometer  116 . The rotational motion promotes even growth of InGaAsN film  105 . A reaction chamber  120 , typically made from quartz, substantially encloses the film  105  and the substrate  104  enabling tight control over environmental conditions around the film  105 . One controlled condition includes maintaining a vacuum within chamber  120  substantially below atmospheric pressure, typically below 100 Torr. Gas flow  124  entering and exiting the reaction chamber is also tightly controlled.  
         [0017]    In the illustrated embodiment, ammonia gas, along with other gases used to form the film, travels through gas inlet  128  into chamber  120 . The mixture of gases depends on the structure being formed. Heating source  132 , in one example, a RF-induction heating coil, raises the temperature within chamber  120  to a temperature that facilitates growth of the film. Typical temperature ranges are between approximately 500 and 750 degrees centigrade. When fabricating an indium gallium arsenide film, temperatures around 560 degrees centigrade allow for a good growth rate with good structural and electronic properties. Gas exhaust  136  permits venting of un-used gases and leftover reactant products. The constant flow of gases from gas inlet  128  to gas exhaust  136  allows tight control over the composition of the gas mixture in chamber  120 .  
         [0018]    The concentration of gases input into chamber  120  depends on the desired composition of the substrate being formed. When InGaAsN is formed using ammonia gas, high concentrations of ammonia gas, typically constituting over 50% of the gas flow into the chamber, compensates for the low overall incorporation efficiency of Nitrogen in MOCVD growth of InGaAsN. Typically, the ratio of [NH 3 ] to [AsH 3 ] during growth of InGaAsN ranges between 5:1 and 20:1.  
         [0019]    A second problem with using ammonia gas as a nitrogen source is the slow decomposition rate of ammonia at low temperature. Raising the temperature above 700 degrees centigrade may cause ammonia pyrolysis resulting in sufficient decomposition of ammonia to provide a needed supply of free nitrogen atoms; however, such high temperatures are undesirable for InGaAs material growth. Instead, one embodiment of the invention uses a catalyst to accelerate the ammonia decomposition rate. In one embodiment of the invention, the catalyst is a chemical catalyst, typically a metal organic, such as trimethlyaluminium (TMAl).  
         [0020]    [0020]FIG. 3 shows a typical InGaAsN laser device structure  300 . FIG. 2 is a graph that illustrates the changes in laser emission wavelength as a function of changing nitrogen mole fraction in the active region of the laser device structure. In FIG. 2, the nitrogen content in the active regions along axis  208  is plotted against the bandgap energy of the active region represented along axis  204 . The large bowing parameter of InGaAsN alloys (bowing parameter of approximately 18-20 eV for Nitrogen concentrations below 2%) allows significant band gap energy reductions to be achieved by adding small amounts of nitrogen (y&lt;2%) in InGaAs 1-y N y  alloys.  
         [0021]    The wavelength of light output by active devices fabricated from InGaAsN is plotted on axis  212 . As can be seen from the graph, increases in wavelength output is directly related to reduced bandgap energy  204 . Reductions in bandgap energy  204  may be achieved by increasing nitrogen content in the film. Thus, one important reason for incorporating nitrogen in the active layer of a semiconductor laser is to reduce the bandgap energy and thereby increase the wavelength output by the active device formed from the GaAs substrate. Reducing the bandgap enables the fabrication of semiconductor lasers that output light wavelengths longer than 1.3 micrometers, preferably between 1.3 and 1.55 micrometer.  
         [0022]    In order to facilitate decomposition of the nitrogen, a chemical catalyst, usually including aluminum, is used. One problem with chemical catalysts that include aluminum is that the aluminum itself forms an alloy with GaAs. Increasing Al composition in the AlGaAs alloy increases the aluminum gallium arsenide film bandgap. However, the decrease in band gap due to the incorporation of nitrogen is larger than the increase in bandgap due to the incorporation of Al in the film. Thus the overall effect is that the increase in bandgap due to the aluminum merely lessens the overall decrease in bandgap due to the nitrogen. To further minimize the effects of the aluminum, other catalysts that do not contain aluminum may be substituted. One example of such a catalyst is Trimethylantimony.  
         [0023]    One example of a gas mixture that has been successfully used in a MOCVD reaction chamber to form a GasAsN film with a 1.18% nitrogen composition includes: a concentration of H 2  at 6 slpm combined with AsH 3  at 15 sccm (670 micromol/min), NH 3  at 95 sccm (4240 micromol/min), TMGa at 8 sccm (101 micromol/min) and TMAI (trimethylaluminum) at 5.2 scem (4 micromol/min). In the MOCVD growth process, Hydrogen (H2) serves as the carrier gas transporting the different metal organic (MO) compounds from the bubbler into the chamber. AsH 3  gas provides the arsine component to the compound; NH 3  gas provides the nitrogen component to the compound; and the metal organic (MO) TMGa provides the gallium component to the GaAs compound semiconductor film.  
         [0024]    TMAl serves as a catalyst, enhancing the nitrogen incorporation in the InGAsN film. The TMAl also causes incorporation of some aluminum into the film forming an alloy with gallium, indium, and nitrogen. As previously discussed, other catalysts may be substituted for TMAl to avoid aluminum incorporation. Typical flow ranges for H 2  are in the range of 2 to 10 slpm, AH 3  flow rates are in the range of 5 sccm to 200 sccm, TMGa flow rate are in the range from 1 sccm to 100 sccm and TMAl flow rates are in the range between 1 sccm to 100 seem. During formation of the GaAsN film, the temperature was maintained at 560 degrees C. while the pressure within the chamber was maintained at 75 Torr.  
         [0025]    Increases in the nitrogen concentration in the GaAsN films may be achieved by increasing the catalyst concentration. For example, FIG. 4 plots the mole fraction of nitrogen in a GaAsN films along axis  404  as a function of the flow rate of a metal organic catalyst (TMAl) plotted along axis  408 . FIG. 4 assumes formation in a MOCVD process using a constant flow rate of ammonia. Alternatively the flow rate of ammonia can be increased to increase the nitrogen content in the InGaAsN films.  
         [0026]    As previously described, one problem with chemical catalysts is that the catalyst itself may form undesirable alloys with GaAs. Using TMAl (trimethylaluminum) as a catalyst produces undesirable aluminum gallium arsenide compounds. Instead of chemical catalysts, one embodiment of the invention uses a radiation source  150  that emits short wavelength light to enhance the decomposition of the ammonia of the invention. Use of a radiation as a catalyst can either reduce or altogether eliminate the use of chemical catalysts and the associated alloy formation. The light radiation is at a predetermined frequency easily absorbed by the ammonia, typically the frequency ranges between 200-350 nanometers. Typical radiation sources generating the desired light frequency output include excimer laser sources or frequency tripled or frequency quadrupled solid state laser sources such as Nd:YAG lasers.  
         [0027]    [0027]FIG. 5 is a flow chart that describes using a MOCVD process to form the laser structure of FIG. 3. In block  504 , GaAs is formed on a GaAs substrate  105  by combining AsH 3  and TMGa in a reaction chamber. The GaAs is positioned on a graphite suspector  112  serves as a substrate for the formation of an InGaAsN layer. The GaAs substrate of FIG. 3 serves as a bottom conductor or contact for the laser structure. The GaAs layer grown on top of the GaAs substrate is typically doped n-type. One method of achieving n-doping is uses SiH 4  as a dopant source to provide Si-dopants. The GaAs layer is typically grown at around 735 degree Celsius.  
         [0028]    In block  508 , an aluminum containing gas such as TMAl is added to the AsH 3  and TMGa gas flows to form an AlGaAs cladding layer over GaAs substrate  308  of FIG. 3. The AlGaAs layer grown on top of the GaAs layer is also n-doped using SiH 4  as a dopant source to provide Si dopant. In alternative embodiments, other dopant materials such as germanium may also be used.  
         [0029]    The AlGaAs layers serve as cladding layer surrounding active region  312  of FIG. 3. The active region is formed by depositing an undoped GaAs waveguide layer  316  in block  512  followed by deposition of an InGaAsN square quantum well layer  320  in block  516 . In one fabrication condition, the GaAs waveguide layer is grown at approximately 640 degree Celsius and the temperature is lowered to around 560 degree Celsius during growth of the InGaAsN layer. Decomposed ammonia provides the nitrogen atoms used in forming the InGaAsN layer. In block  520 , the temperature is raised again to approximately 640 degrees as a second undoped GaAs waveguide layer  324  is deposited over square quantum well  320 . The undoped GaAs layers  316 ,  324  form the walls of the square quantum well and serves also as a waveguiding layers for the separate confinement heterostucture.  
         [0030]    A second AlGaAs cladding layer  328  is deposited in block  524 . The second AlGaAs layer grown is Mg- or C-doped using Cp 2 Mg or CCl 4  as a dopant source to form a p-doped layer. In one embodiment, the AlGaAs layer is grown at approximately 735 degree Celsius. The higher growth temperature during the growth of the second AlGaAs layer also causes an annealing of the InGaAsN film. In an alternate embodiment, the InGaAsN film could be annealed by rapid thermal annealing (RTA) in a furnace under nitrogen atmosphere and with a GaAs cap to achieve an equivalent effect. An example annealing condition is to anneal the substrate at 750 degree Celsius for 3 minutes.  
         [0031]    The second AlGaAs cladding layer together with the first cladding layer forms a waveguide structure that provides optical confinement of the transverse optical mode. In block  528 , a second GaAs contact  332  is deposited over the cladding layer. The second GaAs contact layer may be formed around 640 degrees Centigrade and is usually p-doped with Mg- and/or Carbon-using Cp 2 Mg and/or CCl 4  as a dopant source. Ohmic metal contacts are deposited on the n-type GaAs substrate (e.g. AuGe) and the p-type GaAs contact layer (e.g. Ti/Pt/Au). The n- and p-type contacts couple to a current source to supply a forward current to the laser structure. Laser facets are cleaved along the GaAs (110) cleavage planes to form a laser cavity and provide optical feedback.  
         [0032]    Although the illustrated structure describes one embodiment of a traditional edge-emitting laser structure, many variations are possible. For example, some structures may utilize GaAs/AlAs quarter wavelength stacks instead of AlGaAs cladding layers. The GaAs/AlAs quarter wavelength stacks act as distributed Bragg reflectors (DBR) and form a laser cavity perpendicular to the substrate plane. The optical feedback from the DBR mirrors forms a vertical cavity surface emitting laser structure (VCSEL). In addition a transparent ITO contact instead of a metal p-contact could be used. A transparent contact allows direct current injection into the active region while simultaneously permitting light output through the transparent contact.  
         [0033]    The preceding description includes many parameters, descriptions and other details that should not be interpreted to limit the scope of the invention. Such details are provided to facilitate understanding of the invention and should not be construed as a necessary part of the invention. For example, although the detailed description describes the use fabrication of a edge-emitting structure, the concepts of the invention may also be used to form VCSEL lasers, other passive devices such as photodetector devices or solar cells, light detection systems, and electronic devices, like HBT or HEMT structures. Also, a number of details such as temperatures used during formation have been provided to facilitate fabrication, but it should be understood that other temperatures may be used and still within the scope of the invention. Thus, the scope of the invention should only be limited by the claims as set forth below.