1. Field of the Invention
The present invention relates to a heat treatment apparatus and method of performing heat treatment on a substrate by irradiating a flashlight onto a semiconductor wafer, a glass substrate or the like (hereinafter briefly referred to as a “substrate”).
2. Description of the Background Art
In an ion activation step for an ion-implanted semiconductor wafer, a heat treatment apparatus such as a lamp annealing apparatus with a halogen lamp employed therein has conventionally been used. Such a heat treatment apparatus heats (anneals) a semiconductor wafer to temperatures ranging, for example, between about 1000 and 1100° C. thereby achieving ion activation in the semiconductor wafer. In such a heat treatment apparatus, the temperature of a substrate is raised at a speed of about several hundred degrees per second by the use of energy of light emitted from the halogen lamp.
However, it has been found out that, in the case of achieving ion activation in a semiconductor wafer using a heat treatment apparatus which raises the temperature of a substrate at a speed of about several hundred degrees per second, a phenomenon takes place in which the profile of ions implanted into the semiconductor wafer becomes gentle, that is, ions are diffused by heat. When such a phenomenon takes place, implanted ions are diffused even if a high concentration of ions are implanted into the surface of the semiconductor wafer, resulting in a problem in that more ions than required need to be implanted.
To solve the above-described problem, the technique for raising the temperature of only the surface of a semiconductor wafer within an extremely short period of time (several milliseconds or less) by irradiating a flashlight to the surface of the semiconductor wafer by the use of a xenon flash lamp or the like is proposed by, for example, Japanese Patent Application Laid-Open Nos. 59-169125 (1984) and 63-166219 (1988). Since there is not enough time for ions to diffuse in the case of raising the temperature of the wafer surface within an extremely short period of time by a xenon flash lamp, ion activation alone can be achieved without the profile of ions implanted into a semiconductor wafer becoming gentle.
A xenon flash lamp instantaneously irradiates light of extremely high energy to a semiconductor wafer, so that the surface temperature of the semiconductor wafer is raised in an instant. When energy of irradiated light exceeds a threshold value, rapid thermal expansion at the surface may cause the semiconductor wafer to break with a high probability. Therefore, in an actual heat treatment, light of energy having a certain degree of process margin lower than the threshold value is irradiated.
However, when heating a semiconductor wafer being held by a susceptor by irradiating a flashlight from a xenon flash lamp, the semiconductor wafer may break even with a flashlight having energy lower than the above threshold value. This is because, when the semiconductor wafer is going to warp to be convex due to rapid thermal expansion at the surface resulting from instantaneous flashlight irradiation, a great force is applied to a contact part, if any, between an end of the wafer and a pocket edge of the susceptor or positioning pin, whereas there is not sufficient time for the wafer to move sliding over the susceptor in order to relieve such stress. As a result, even when irradiating a flashlight having energy lower than the above-mentioned threshold value, stress generated at a contact part, if any, between an end of the semiconductor wafer and something at the time of instantaneous thermal expansion causes the semiconductor wafer to break.
The present invention is intended for a heat treatment apparatus for heating a substrate by irradiating a flashlight thereto.
According to the present invention, the heat treatment apparatus comprises: a light source having a flash lamp; a chamber provided under the light source; a susceptor for holding a substrate in a substantially horizontal position in the chamber; a lifting mechanism for lifting up the substrate held by the susceptor from an upper surface of the susceptor; and a lift control element for controlling the lifting mechanism to operate the lifting mechanism before irradiation of a flashlight from the light source to lift up the substrate held by the susceptor as well as to stop the operation of the lifting mechanism at irradiation of a flashlight from the light source to cause a gas layer to be sandwiched between the upper surface of the susceptor and the substrate for bringing the substrate into a floating state.
The substrate in a floating state can freely move at the time of flashlight irradiation. As a result, even when instantaneous flashlight irradiation causes rapid thermal expansion of the substrate surface, the substrate does not suffer a great stress. This can prevent the substrate from breaking at the time of heat treatment.
According to one aspect of the present invention, the heat treatment apparatus comprises: a light source having a flash lamp; a chamber provided under the light source; a susceptor for holding a substrate in a substantially horizontal position in the chamber; support pins insertable into the susceptor and capable of mounting thereon the substrate with top ends thereof extending out of an upper surface of the susceptor; an elevating mechanism for moving the support pins upwardly/downwardly relatively to the susceptor between a position where top ends of the support pins are located under an upper surface of the susceptor and a position where the top ends of the support pins extend out of the upper surface of the susceptor to support the substrate held by the susceptor; and an irradiation control element for controlling the light source to cause the flash lamp to irradiate a flashlight toward the substrate while the substrate is floating with a gas layer sandwiched between the upper surface of the susceptor and the substrate after the elevating mechanism moves the susceptor and the substrate mounted on the support pins upwardly/downwardly relatively to each other to mount the substrate on the upper surface of the susceptor.
The substrate in a floating state can freely move at the time of flashlight irradiation. As a result, even when instantaneous flashlight irradiation causes rapid thermal expansion of the substrate surface, the substrate does not suffer a great stress. This can prevent the substrate from breaking at the time of heat treatment.
The present invention is also intended for a heat treatment method of heating a substrate by irradiating a flashlight thereto.
It is therefore an object of the present invention to provide a heat treatment apparatus and heat treatment method which is capable of preventing a substrate from breaking during heat treatment.
These and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.
First Preferred Embodiment
The heat treatment apparatus includes a chamber 65 formed by a light transmitting plate 61, a bottom plate 62 and a pair of side plates 63 and 64 and intended for housing a semiconductor wafer W therein and performing heat treatment on the semiconductor wafer W. The light transmitting plate 61 forming the upper portion of the chamber 65 is made of, for example, an infrared transmissive material such as quartz, and functions as a chamber window for transmitting light emitted from a light source 5 to guide it into the chamber 65. The bottom plate 62 of the chamber 65 has support pins 70 provided in a standing manner and extending through a susceptor 73 and a heating plate 74 which will be described later for supporting the semiconductor wafer W from under its lower surface.
The side plate 64 of the chamber 65 has an opening 66 for transporting the substrate W into/out of the chamber 65. The opening 66 is opened and closed by a gate valve 68 rotating about a shaft 67. The semiconductor wafer W is transported into the chamber 65 by a transport robot not shown with the opening 66 being opened. During heat treatment of the semiconductor wafer W in the chamber 65, the opening 66 is closed.
The chamber 65 is provided under the light source 5. The light source 5 includes a plurality of (twenty seven in the present embodiment) xenon flash lamps 69 (hereinafter merely referred to as “flash lamps 69” as well) and a reflector 71. The plurality of flash lamps 69 are rod-like lamps each having a long cylindrical shape, and are arranged in parallel with one another with their longitudinal direction being in line with the horizontal direction. The reflector 71 is provided over the plurality of flash lamps 69 so as to cover all of them.
These xenon flash lamps 69 each have a glass tube containing a xenon gas therein with an anode and a cathode provided on its respective ends and connected to a capacitor, and a trigger electrode wound around the outer periphery of the glass tube. A xenon gas is electrically an insulator, so that no current flows in the glass tube in a normal state. However, in the case where a high voltage is applied to the trigger electrode to produce an electrical breakdown, electricity stored in the capacitor instantaneously flows into the glass tube, and the xenon gas is heated by the Joule heat at that time, whereby light is emitted. Since previously stored electrostatic energy is converted into an extremely short light pulse ranging between 0.1 and 10 milliseconds, the xenon flash lamps 69 are characterized by having the capability of emitting light extremely brighter than in a continuously lit light source.
Provided between the light source 5 and light transmitting plate 61 is a light diffusion plate 72. The light diffusion plate 72 is made of quartz glass as an infrared transmissive material with its surface subjected to light diffusion treatment.
Part of light emitted from the flash lamps 69 directly transmits through the light diffusion plate 72 and light transmitting plate 61 to enter the chamber 65. The remainder of the light emitted from the flash lamps 69 is reflected by the reflector 71 and then transmits through the light diffusion plate 72 and light transmitting plate 61 to enter the chamber 65.
In the chamber 65, the heating plate 74 and susceptor 73 are provided. The susceptor 73 is bonded to the upper surface of the heating plate 74. On the surface of the susceptor 73, displacement preventing pins 75 for the semiconductor wafer W are provided. The semiconductor wafer W is directly held by the susceptor 73 in a substantially horizontal state.
The heating plate 74 is intended to perform preheating (assist heating) on the semiconductor wafer W. The heating plate 74 is made of aluminum nitride and has therein a heater and a sensor for controlling the heater. On the other hand, the susceptor 73 is intended to position and hold the semiconductor wafer W as well as to diffuse heat energy emitted from the heating plate 74 for uniformly preheating the semiconductor wafer W. A material having relatively low thermal conductivity such as aluminum nitride, quartz or the like is employed for the susceptor 73.
The susceptor 73 and heating plate 74 are driven by a motor 40 to move upwardly/downwardly between the transporting position of the semiconductor wafer W shown in FIG. 1 and the heating position of the semiconductor wafer W shown in FIG. 2.
That is, the heating plate 74 is connected to a moving plate 42 through a tube-like member 41. The moving plate 42, guided by a guiding member 43 suspended from the bottom plate 62 of the chamber 65, is movable up and down. Secured to the lower end of the guiding member 43 is a stationary plate 44 provided at its central portion with the motor 40 for rotatably driving a ball screw 45. The ball screw 45 is in threaded engagement with a nut 48 connected to the moving plate 42 through connecting members 46 and 47. Therefore, the susceptor 73 and heating plate 74 are driven by the motor 40 to be movable up and down between the transporting position of the semiconductor wafer W shown in FIG. 1 and the heating position of the semiconductor wafer W shown in FIG. 2.
The transporting position of the semiconductor wafer W shown in
On the other hand, the heating position of the semiconductor wafer W shown in
During the process which the susceptor 73 and heating plate 74 move downwardly from the heating position shown in
Conversely, during the process that the susceptor 73 and heating plate 74 move upwardly from the transporting position shown in
In the state where the susceptor 73 and heating plate 74 for supporting the semiconductor wafer W move upwardly to the heating position, the light transmitting plate 61 is located between the light source 5 and the semiconductor wafer W held by the susceptor 73 and heating plate 74. The distance between the susceptor 73 and light source 5 at this time can be adjusted to an arbitrary value by controlling the amount of rotation of the motor 40.
Extensible bellows 77 for maintaining the chamber 65 airtight are provided between the bottom plate 62 of the chamber 65 and the moving plate 42 so as to surround the periphery of the tube-like member 41. When the susceptor 73 and heating plate 74 move upwardly to the heating position, the bellows 77 shrink, and when the susceptor 73 and heating plate 74 move downwardly to the transporting position, the bellows 77 extend so as to cut off the atmosphere within the chamber 65 from the external atmosphere.
An inlet pipe 78 communicating with an open/close valve 80 is provided on the side plate 63 opposite to the opening 66 of the chamber 65. This inlet pipe 78 is intended to introduce gas necessary for treatment, e.g., inert nitrogen gas into the chamber 65. On the other hand, the opening 66 in the side plate 64 is provided with an exhaust pipe 79 communicating with an open/close valve 81. This exhaust pipe 79 is intended to exhaust gas within the chamber 65, and is connected to exhaust means not shown through the open/close valve 81.
Further, the heat treatment apparatus includes a controller 10 for controlling the respective mechanisms including the motor 40.
Further, a lamp source (power supply circuit) 6 for light source 5 and the motor 40 of the heat treatment apparatus is electrically connected to the bus line 19. The CPU 11 of the controller 10 executes the control software stored in the magnetic disc 14, thereby controlling the timing when the flash lamps 69 are lit up as well as controlling the motor 40 to adjust the position of the susceptor 73 and heating plate 74.
A display part 21 and an input part 22 are also electrically connected to the bus line 19. The display part 21 is formed by, for example, a liquid crystal display, and displays various types of information such as processing results and recipe contents. The input part 22 is formed by, for example, a keyboard or mouse, and receives inputs such as commands or parameters. An operator of the apparatus can input commands or parameters through the input part 22 while checking the display on the display part 21. The display part 21 and input part 22 may be integrated to constitute a touch panel.
Next, a heat treatment operation performed on the semiconductor wafer W by the heat treatment apparatus of the present invention will be described.
In the heat treatment apparatus, the semiconductor wafer W is transported into the chamber 65 by a transport robot not shown through the opening 66 and is mounted on the support pins 70 while the susceptor 73 and heating plate 74 are located at the transporting position of the semiconductor wafer W shown in
Thereafter, the susceptor 73 and heating plate 74 are driven by the motor 40 to move upwardly and temporarily stop just before the susceptor 73 comes into contact with the semiconductor wafer W mounted on the support pins 70 (step S12). The susceptor 73 and heating plate 74 are previously heated to a predetermined temperature by the action of a heater incorporated in the heating plate 74. Therefore, the semiconductor wafer W mounted on the support pins 70 is gradually heated by the susceptor 73 in the state where the susceptor 73 is located slightly under the semiconductor wafer W (step S13). This heating step is a preparatory heating step for a preheating step which will be described later, and is executed for about a second.
Subsequently, the susceptor 73 and heating plate 74 are driven by the motor 40 to further move upwardly to the heating position of the semiconductor wafer W shown in FIG. 2. During this step, the semiconductor wafer W mounted on the support pins 70 is transferred to the susceptor 73, and is mounted horizontally on the upper surface of the susceptor 73 (step S14). At this time, as described above, a gas layer is sandwiched between the upper surface of the susceptor 73 and the lower surface of the semiconductor wafer W, causing the semiconductor wafer W to float over the upper surface of the susceptor 73 during about seventy seconds just after the semiconductor wafer W is transferred from the support pins 70 to the susceptor 73.
In the state where the susceptor 73 and heating plate 74 are located at the heating position of the semiconductor wafer W, the semiconductor wafer W is in close proximity to the susceptor 73 being heated while floating over the susceptor 73, and is thus preheated, so that the temperature of the semiconductor wafer W is raised progressively (step S15).
In this state, the semiconductor wafer W is continuously heated by the susceptor 73. During the temperature rise of the semiconductor wafer W, a temperature sensor not shown monitors the surface temperature of the semiconductor wafer W. It requires about sixty seconds until the surface temperature of the semiconductor wafer W reaches a preheated temperature T1 and becomes stable after the semiconductor wafer W is mounted on the upper surface of the susceptor 73. The preheated temperature T1 ranges from, for example, about 200 to 600° C. Heating the semiconductor wafer W to the preheated temperature T1 of such degree will not cause diffusion of ions implanted into the semiconductor wafer W.
After a while, when the surface temperature of the semiconductor wafer W reaches the preheated temperature T1 after a lapse of sixty seconds after the semiconductor wafer W is mounted on the upper surface of the susceptor 73, the processing progresses to step S16, in which the controller 10 controls the lamp source 6 to light up the flash lamps 69 for performing flash heating. In the present embodiment, the controller 10 controls the lamp source 6 so as to perform flash heating after a lapse of sixty-one seconds after the semiconductor wafer W is mounted on the upper surface of the susceptor 73.
On the other hand, as described above, the semiconductor wafer W is floating over the upper surface of the susceptor 73 for about seventy seconds after the semiconductor wafer W is mounted on the upper surface of the susceptor 73. Therefore, the flash lamps 69 irradiate a flashlight toward the semiconductor wafer W while the semiconductor wafer W is floating with a gas layer sandwiched between the upper surface of the susceptor 73 and the lower surface of the semiconductor wafer W.
A period of time during which the flash lamps 69 are lit up in the flash heating step ranges between about 0.1 and 10 milliseconds. The flash lamps 69 irradiate an extremely strong flashlight since previously stored electrostatic energy is converted into such an extremely short light pulse.
With such flash heating, the surface temperature of the semiconductor wafer W instantaneously reaches a temperature T2. This temperature T2 ranges between about 1000 and 1100° C. which is necessary for ion activation in the semiconductor wafer W. Rising the surface temperature of the semiconductor wafer W to such temperature T2 enables activation of ions implanted into the semiconductor wafer W.
At this time, the surface temperature of the semiconductor wafer W is raised to the temperature T2 within an extremely short period of time ranging between about 0.1 and 10 milliseconds, so that ion activation in the semiconductor wafer W is completed in a short while. This prevents diffusion of ions implanted into the semiconductor wafer W, which can avoid the occurrence of the phenomenon in which the profile of ions implanted into the semiconductor wafer W becomes gentle. Since a period of time required for ion activation is extremely shorter than that required for ion diffusion, ion activation is completed even in a short period of time ranging between about 0.1 and 10 milliseconds that does not cause diffusion of ions.
Further, since the surface of the semiconductor wafer W is heated to the preheated temperature T1 ranging from about 200 to 600° C. using the heating plate 74 before the flash lamps 69 are lit up to heat the semiconductor wafer W, the surface temperature of the semiconductor wafer W can be rapidly raised to the temperature T2 ranging between about 1000 and 1100° C. by the flash lamps 69.
After a lapse of about ten seconds after the flash heating step is completed, the susceptor 73 and heating plate 74 are driven by the motor 40 to move downwardly to the transporting position of the semiconductor wafer W shown in
When heating the semiconductor wafer W by lighting up the flash lamps 69, instantaneous flashlight irradiation causes rapid thermal expansion of the wafer surface, so that the semiconductor wafer W is going to warp to be convex. At this time, the semiconductor wafer W may break due to stress generated at a contact part, if any, between an end of the semiconductor wafer W and a positioning pin or the like at the time of instantaneous thermal expansion, as already described.
In the present embodiment, flash heating is performed after a lapse of sixty-one seconds after the semiconductor wafer W is mounted on the upper surface of the susceptor 73, i.e., while the semiconductor wafer W is floating with a gas layer sandwiched between the upper surface of the susceptor 73 and the semiconductor wafer W. Therefore, at the time of flashlight irradiation, there is no frictional force between the semiconductor wafer W and susceptor 73, so that the semiconductor wafer W can freely move. As a result, even when instantaneous flashlight irradiation causes rapid thermal expansion of the wafer surface, the semiconductor wafer W does not suffer a great stress, which can prevent the semiconductor wafer W from breaking at the time of flashlight irradiation.
Second Preferred Embodiment
Next, a second preferred embodiment of the present invention will be described. A heat treatment apparatus according to the present embodiment has exactly the same structure as that of the first preferred embodiment, explanation of which is thus omitted here. The present embodiment differs from the first preferred embodiment only in the procedure of heat treatment operation performed on the semiconductor wafer W.
The susceptor 73 and heating plate 74 are previously heated to a predetermined temperature by the action of a heater incorporated in the heating plate 74. Therefore, the semiconductor wafer W comes into contact with the susceptor 73 as heated and is thus preheated in the state where the susceptor 73 and heating plate 74 is located at the heating position of the semiconductor wafer W. The temperature of the semiconductor wafer W is therefore increasingly raised.
In this state, the semiconductor wafer W is continuously heated by the susceptor 73. During the temperature rise of the semiconductor wafer W, a temperature sensor not shown always monitors whether or not the surface temperature of the semiconductor wafer W reaches the preheated temperature T1 (step S3). The preheated temperature T1 ranges from, for example, about 200 to 600° C., as in the first preferred embodiment.
After a while, when the surface temperature of the semiconductor wafer W reaches the preheated temperature T1, the processing progresses to step S4, in which the controller 10 drives the motor 40 to temporarily move the susceptor 73 and heating plate 74 downwardly so that the semiconductor wafer W held by the susceptor 73 is transferred to the support pins 70. That is, the semiconductor wafer W held by the susceptor 73 is caused to be lifted over the upper surface of the susceptor 73 before a flashlight is irradiated from the light source 5. At this time, the susceptor 73 and heating plate 74 are not required to move downwardly to the transporting position of the semiconductor wafer W shown in
Thereafter, the processing progresses immediately to step S5, in which the susceptor 73 and heating plate 74 are driven by the motor 40 to move upwardly again so that the semiconductor wafer W mounted on the support pins 70 is transferred to the susceptor 73. At this time, as described above, just after the semiconductor wafer W is transferred from the support pins 70 to the susceptor 73, the semiconductor wafer W floats over the upper surface of the susceptor 73 with a gas layer sandwiched between the upper surface of the susceptor 73 and the lower surface of the semiconductor wafer W.
Then, the flash lamps 69 are lit up to perform flash heating while the semiconductor wafer W is floating over the upper surface of the susceptor 73 (step S6). A period of time during which the flash lamps 69 are lit up in the flash heating step ranges between about 0.1 and 10 milliseconds.
With such flash heating, the surface temperature of the semiconductor wafer W instantaneously reaches the temperature T2. This temperature T2 ranges between about 1000 and 1100° C. which is necessary for ion activation in the semiconductor wafer W. Rising the surface temperature of the semiconductor wafer W to such temperature T2 enables activation of ions implanted into the semiconductor wafer W.
Upon completion of the flash heating step, the susceptor 73 and heating plate 74 are driven by the motor 40 to move downwardly to the transporting position of the semiconductor wafer W shown in
In the present embodiment, the susceptor 73 is moved downwardly just before (about a second before) a flashlight is irradiated from the light source 5 to cause the top ends of the support pins 70 to extend out of the upper surface of the susceptor 73, so that the semiconductor wafer W held by the susceptor 73 is temporarily lifted over the upper surface of the susceptor 73. Then, when a flashlight is irradiated from the light source 5, the susceptor 73 is moved upwardly again to cause the top ends of the support pins 70 to be located under the upper surface of the susceptor 73, and a gas layer is sandwiched between the upper surface of the susceptor 73 and the lower surface of the semiconductor wafer W to ensure that the semiconductor wafer W floats over the upper surface of the susceptor 73.
Therefore, at the time of flashlight irradiation, there is no frictional force between the semiconductor wafer W and susceptor 73, so that the semiconductor wafer W can freely move. As a result, even when instantaneous flashlight irradiation causes rapid thermal expansion of the wafer surface, the semiconductor wafer W does not suffer a great stress, which can prevent the semiconductor wafer W from breaking at the time of flashlight irradiation. However, if the semiconductor wafer W is kept away from the susceptor 73 for a long time, the surface temperature of the semiconductor wafer W decreases from the preheated temperature T1. Therefore, the controller 10 is required to control the motor 40 such that the susceptor 73 moves upwardly again immediately after moving downwardly.
Third Preferred Embodiment
Next, a third preferred embodiment of the present invention will be described. A heat treatment apparatus according to the present embodiment has the same structure as that of the first preferred embodiment except for an additional mechanism for discharging nitrogen gas from the upper surface of the susceptor 73 toward the lower surface of the semiconductor wafer W.
In the heat treatment apparatus of the present embodiment, a gas supply pipe 90 is provided in the susceptor 73 and heating plate 74 so as to hang down therefrom. The gas supply pipe 90 has its top end inserted into the susceptor 73 and heating plate 74 to form a discharge port 93 on the upper surface of the susceptor 73. The discharge port 93 is directed toward the lower surface of the semiconductor wafer W.
The gas supply pipe 90 has its base end communicating with a gas pipe 91. The gas pipe 91 is connected to a nitrogen gas supply source not shown, and an open/close valve 92 is provided on a path therebetween. Since the gas supply pipe 90 moves upwardly/downwardly as the susceptor 73 and heating plate 74 move upwardly/downwardly, the gas pipe 91 and gas supply pipe 90 are connected by a flexible tube or the like.
Opening the open/close valve 92 allows nitrogen gas to be discharged from the discharge port 93 toward the lower surface of the semiconductor wafer W held by the susceptor 73. Opening/closing of the open/close valve 92 is also controlled by the controller 10.
The rest of the components except those described above are the same as in the first preferred embodiment, and are indicated by the same reference numerals of
That is, the support pins 70 are caused to extend out of the upper surface of the susceptor 73 in the step S4 shown in
Therefore, similarly to the second preferred embodiment, there is no frictional force between the semiconductor wafer W and susceptor 73 at the time of flashlight irradiation, so that the semiconductor wafer W can freely move. As a result, even when instantaneous flashlight irradiation causes rapid thermal expansion of the wafer surface, the semiconductor wafer W does not suffer a great stress, which can prevent the semiconductor wafer W from breaking at the time of flashlight irradiation. However, if the semiconductor wafer W is kept away from the susceptor 73 for a long time, the surface temperature of the semiconductor wafer W decreases from the preheated temperature T1. Therefore, the controller 10 is required to control the open/close valve 92 such that the nitrogen gas discharge is stopped immediately after the semiconductor wafer W is caused to be lifted.
Modification
Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the above examples. For instance, the light source 5 is provided with twenty-seven flash lamps 69 in the respective preferred embodiments, however, the number of flash lamps 69 is not limited as such but may be determined arbitrarily.
In the above preferred embodiments, the support pins 70 are provided securely while the susceptor 73 and heating plate 74 move upwardly/downwardly so that the semiconductor wafer W is transferred between the support pins 70 and susceptor 73 and heating plate 74, however, the support pins 70 may be moved upwardly/downwardly with respect to the susceptor 73 and heating plate 74 so that the semiconductor wafer W is transferred therebetween. Specifically, the support pins 70 are not fixed to the bottom plate 62, but is made movable up and down by an elevating mechanism such as an air cylinder. The susceptor 73 and heating plate 74 are provided securely. With such structure, a gas layer is also sandwiched between the upper surface of the susceptor 73 and the lower surface of the semiconductor wafer W to bring the semiconductor wafer W into a floating state over the upper surface of the susceptor 73 for about seventy seconds after the support pins 70 move downwardly and the semiconductor wafer W is mounted on the upper surface of the susceptor 73. In other words, the susceptor 73 and support pins 70 may be moved upwardly/downwardly relatively to each other.
The first preferred embodiment has described that flash heating is carried out sixty-one seconds after the semiconductor wafer W is mounted on the susceptor 73, however, this is not restrictive, but flash heating may be carried out within seventy seconds after the semiconductor wafer W is mounted on the upper surface of the susceptor 73. During about seventy seconds after the semiconductor wafer W is mounted on the upper surface of the susceptor 73, the semiconductor wafer W is in a floating state over the upper surface of the susceptor 73. Therefore, carrying out flash heating during that period can prevent the semiconductor wafer W from breaking at the time of flashlight irradiation. However, when the susceptor 73 has a thickness of, e.g., 5 mm, it is preferable that flash heating should be performed after a lapse of forty seconds or more after the semiconductor wafer W is mounted on the upper surface of the susceptor 73. This is because it requires about thirty-five seconds for the semiconductor wafer W to be heated to the preheated temperature T1 after being mounted on the upper surface of the susceptor 73.
Although the third preferred embodiment has described that nitrogen gas is discharged toward the lower surface of the semiconductor wafer W to cause the semiconductor wafer W to be lifted, another gas (e.g., air) may be used instead of nitrogen gas to cause the semiconductor wafer W to be lifted. However, it is preferable to use inert and clean nitrogen gas since it is blown onto the semiconductor wafer W heated to the preheated temperature T1.
In the third preferred embodiment, nitrogen gas may be discharged from a plurality of positions. For instance, a plurality of support pins 70 may each be provided with a through hole, from which nitrogen gas is discharged.
Further, the above preferred embodiments have described that ion activation is achieved by irradiating light onto the semiconductor wafer W, however, a substrate to be treated by the heat treatment apparatus according to the present invention is not limited to a semiconductor wafer. For instance, a glass substrate on which various silicon films such as a silicon nitride film and a polycrystalline silicon film are formed may be subjected to the treatment performed by the heat treatment apparatus according to the present invention.
While the invention has been shown and described in detail, the foregoing description is in all aspects illustrative and not restrictive. It is therefore understood that numerous modifications and variations can be devised without departing from the scope of the invention.
Number | Date | Country | Kind |
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2002-353521 | Dec 2002 | JP | national |
2003-349695 | Oct 2003 | JP | national |
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4571486 | Arai et al. | Feb 1986 | A |
4649261 | Sheets | Mar 1987 | A |
4958061 | Wakabayashi et al. | Sep 1990 | A |
5228206 | Grant et al. | Jul 1993 | A |
6329304 | Kuznetsov et al. | Dec 2001 | B1 |
6399922 | Okase et al. | Jun 2002 | B2 |
Number | Date | Country |
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57-162340 | Oct 1982 | JP |
59-169125 | Sep 1984 | JP |
60-258928 | Dec 1985 | JP |
63-166219 | Jul 1988 | JP |
2001-237195 | Aug 2001 | JP |
Number | Date | Country | |
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20040112890 A1 | Jun 2004 | US |