[0019] FIG. 1 shows a schematic cross-sectional view through the arrangement of an AlGaAs structure for a Vertical Cavity Surface Emitting Laser 1 , the light exiting aperture of which is produced pursuant to the method of the present invention.

[0020] The laser has a GaAs substrate on which is applied a first plurality of n-doped AlGaAs layers. The first plurality of layers is applied to the GaAs substrate in a region 4 , and the layers have essentially the same peripheral dimensions as does the GaAs substrate 3 . Beyond the region 4 , the dopings of the layers vary, as indicated in FIG. 1 .

[0021] In a further section 6 , a second plurality of layers is applied to the first plurality of layers. In the second section or region 6 , the plurality of layers are applied or processed in such a way that they form a round truncated cone or a mesa, i.e. a layer structure that projects beyond the substrate.

[0022] Adjacent to the region or section 4 having the first plurality of layers first GaAsMQW layers are provided. This is followed by an aluminum layer 8 on which is then provided a plurality of p-doped AlGaAs layers. Provided on the upper surface of the truncated cone are electrical connections or terminals for the activation of the laser, as illustrated by the arrows 10 , 11 .

[0023] The aluminum layer 8 has an oxidized outer portion 13 , which is illustrated as dark-colored, as well as a non-oxidized central portion 14 that is illustrated as light-colored and serves as an aperture for the laser. For a good laser activation, and for a good coupling of the laser to optical fibers, it is important that the non-oxidized central portion 14 form a round aperture that is defined as precisely as possible.

[0024] Such a precisely defined round aperture can be produced by the inventive method, which is described subsequently.

[0025] To form the oxidized outer portion 13 , an AlGaAs structure having the aforementioned build-up, in which the aluminum layer 8 is present in a continuous non-oxidized state, is loaded into a process chamber of a thermal treatment unit. The thermal treatment unit is, for example, a rapid heating unit, such as is known from DE-A-199 05 524, which originates from this same applicant, and which to this extent is made the subject matter of the present invention in order to avoid repetition.

[0026] The temperature of the AlGaAs structure is subsequently heated to a treatment temperature of between 300 and 700 C, which is advantageous for a good and defined oxidation of the aluminum layer 8 . After the heating of the structure, a hydrogen-rich water vapor is introduced into the process chamber of the heating unit. The hydrogen-rich water vapor can be produced, for example, by conducting hydrogen through water vapor. Alternatively, the hydrogen-rich water vapor mixture can also be produced by the burner, which will be described subsequently with reference to FIGS. 2 and 3 .

[0027] As a result of the introduction of the hydrogen-rich water vapor, the following chemical reactions occur within the process chamber:

2AlAs+3H ₂ O=Al ₂ O ₃ +2AsH ₃

AlAs+2H ₂ O=AlO(OH)+AsH ₃

AlO(OH)+AlAs+H ₂ O=Al ₂ O ₃ +2AsH ₃

AlAs+3H ₂ O=Al(OH) ₃ +AsH ₃

Al(OH) ₃ +AlAs=Al ₂ O ₃ +AsH ₃

2AlAs+6H ₂ O=Al ₂ O ₃ +As ₂ O ₃ +6H ₂

As ₂ O ₃ +6H ₂ =2AsH ₃ +3H ₂ O

[0028] In this connection, there occurs a laterally proceeding oxidation of the aluminum layer, which progresses from the side edges of the layers 8 toward the inside. The lateral velocity of the oxidation is known, and after achieving a certain progress of the oxidation, i.e. after termination of a certain period of time, the introduction of the hydrogen-rich water vapor is halted. The process chamber is subsequently rinsed with a gas, preferably an inert gas, in order to displace the hydrogen out of the process chamber. Nitrogen and/or noble gases such as argon are preferably used as inert gases.

[0029] After the process chamber is rinsed with the inert gas, dry oxygen or oxygen-rich water vapor is introduced into the process chamber. As a result of the introduction of the dry oxygen or of the oxygen-rich water vapor, the following chemical reaction occurs:

4AlAs+5O ₂ =2Al ₂ O ₃ +4AsO or

2AlAs+3O ₂ =Al ₂ O ₃ +As ₂ O ₃

[0030] In this way, an advancing of the oxidation front by passivation of the oxide layer is achieved. Thus, the advancing of the oxidation front, and the formation of the non-oxidized aperture 14 , can be precisely controlled in order to form a defined edge region of the aperture for the laser.

[0031] Instead of the rinsing step with an inert gas described above, it is also possible, for the rinsing of the process chamber, to introduce another gas, or for example pure water vapor, into the process chamber in order after the displacement of the hydrogen-rich water vapor to introduce the dry oxygen or oxygen-rich water vapor. The displacement of the hydrogen prior to the introduction of oxygen is necessary in order to prevent the formation of an oxyhydrogen or explosive gas mixture in the process chamber.

[0032] The hydrogen-rich water vapor and/or the oxygen-rich water vapor can be produced with a burner 20 , which is schematically illustrated in the cross-section of FIG. 2 . FIG. 3 schematically shows, in a block diagram, an entire unit 22 that is suitable for carrying out the above-described method, and which contains the burner 20 of FIG. 2 as well as a thermal treatment unit 24 .

[0033] The burner 20 and the unit 22 have, for example, a composition such as is described in the not pre-published German Patent Application No. 101 19 741 that originates with the same applicant and has the title “Method and Apparatus for the Production of Process Gases” dated 23 Apr. 2001, and which to this extent is made the subject matter of the present invention in order to avoid repetition.

[0034] In summary, the burner 20 has a housing 23 with a combustion chamber 25 . The combustion chamber 25 has an inlet 27 that is in communication with first and second gas inlet lines 28 , 30 . By means of the inlet lines 28 , 30 , oxygen or hydrogen can respectively be introduced into the combustion chamber 25 in a controlled manner. In the region of the inlet 27 , a heating ring 32 that surrounds the inlet lines 28 , 30 is provided in order to heat the gases introduced via the inlet lines 28 , 30 and to effect a combustion of the thereby resulting explosive or detonating mixture of hydrogen and oxygen. The combustion is monitored by an appropriate flame sensor 34 . During the combustion, water vapor results by the stoichiometric combustion of substituents of the resulting oxygen/hydrogen gas mixture. If one of the substituents is present in greater than a stoichiometric proportion, there results an oxygen-rich or hydrogen-rich water vapor mixture that can be introduced into the thermal treatment unit 24 of FIG. 3 for a thermal treatment of the VCSEL 1 .

[0035] By increasing the oxygen or hydrogen content, one can alternate between an oxygen-rich and a hydrogen-rich water vapor mixture, whereby during the switching one must take care that no explosive mixture results outside of the burner. This can be achieved, for example, in that, for example after the production of an oxygen-rich water vapor mixture, for a certain period of time stoichiometric proportions of oxygen and hydrogen are introduced into the burner in order to ensure a complete combustion and to displace the excess oxygen out of the burner. Only subsequent thereto is additional hydrogen introduced into the burner in order to now produce a hydrogen-rich water vapor mixture.

[0036] Alternatively, the burner can, of course, also be rinsed in the meantime with an inert gas that can also be simultaneously used for rinsing the thermal treatment unit 24 .

[0037] As can be recognized in FIG. 3 , the entire unit 22 , which is used for the thermal treatment process of the present invention, has a control unit 40 that via appropriate valves 42 controls the supply of various gases into the burner 20 or a connecting line between the burner 20 and the thermal treatment unit 24 . By introducing oxygen or hydrogen into a connecting line between the burner 20 and the thermal treatment unit 24 , it is possible to precisely set the oxygen or hydrogen content of the oxygen-rich or hydrogen-rich water vapor mixture.

[0038] The invention was previously described with the aid of preferred embodiments without being limited to the concretely illustrated embodiments. For example, for the production of an oxygen-rich or hydrogen-rich water vapor mixture, it is not necessary to use a burner pursuant to FIG. 2 . Rather, the mixture could also be produced by evaporating water and introducing oxygen or hydrogen into the vapor. Furthermore, the inventive method for treating a substrate having multiple layers can also be carried out at any desired process chamber pressure. For example, the method can be carried out in RTP units at normal pressure (atmospheric pressure), overpressure or underpressure. At a suitable underpressure and chamber design, a possible explosion pressure of a possible explosive gas explosion can be reduced to such an extent that no damage occurs to the chamber or substrate. In this way, a possible switching between hydrogen-rich and oxygen-rich water vapor (or vice versa) is possible without the chamber being rinsed by an inert gas or pure water vapor for avoiding an explosive gas mixture.