JP2011044532A - Device for rotationally holding semiconductor substrate - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device for holding a semiconductor substrate which, when a film is deposited on the semiconductor substrate in a vapor-phase state in a reaction furnace by metal organic vapor phase epitaxy, enables a film of high quality to be formed on the semiconductor substrate without using a gas wheel system, dispenses with opening the reaction furnace supplied with a vapor-phase substance and manually putting the substrate in and out, and improves supply efficiency of the vapor-phase substance supplied to the reaction furnace, and to provide a conveyance device for the device for holding the semiconductor substrate. <P>SOLUTION: In a device for rotationally holding the semiconductor substrate, a susceptor 12 is fixed to a rotationally driving shaft 15 detachably in an up/down direction, opening parts 13 where a plurality of substrate holders 14 to be mounted with substrates are arranged are formed penetrating the susceptor 12 in a thickness direction, and an engagement part 16 with which the substrate holders 14 engage in the up/down direction in a disengageable manner is provided beneath the susceptor 12, the engagement part 16 enabling the substrate holders 14 to rotate as the susceptor 12 rotates. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a semiconductor substrate rotation holding device and a semiconductor substrate rotation holding device transport device, and more particularly, to a semiconductor substrate used for forming a film in a vapor state on a semiconductor substrate by metal organic vapor phase epitaxy. The present invention relates to a rotation holding device and a transfer device for a semiconductor substrate rotation holding device.

  Conventionally, chemical vapor deposition (CVD) has been used to form a thin film on the surface of a semiconductor. In the chemical vapor deposition method, a thin film is formed by supplying a plurality of types of vapor phase substances to a semiconductor element in a reaction furnace and reacting them at a high temperature.

When a film is formed in a vapor phase on the surface of the semiconductor substrate in the reaction furnace by such a metal organic chemical vapor deposition method, a rotation holding device for the semiconductor substrate is disposed and used in the reaction furnace. .
As shown in FIGS. 22 and 23, the conventional semiconductor substrate rotation holding device 60 is formed in a disk shape and rotates, and is formed in a disk shape and opened in the susceptor 61. A plurality of substrate holders 63, which are detachably disposed in the plurality of openings 62 and are formed so as to rotate in the openings 62 by the rotation of the susceptor 61. have.

  The susceptor 61 is formed in a thin disk shape, and is disposed on the same plane in the opening 65 of the ring-shaped frame portion 64. The susceptor 61 is fixed to the rotation shaft portion 66 on the back surface side of the central portion, and rotates in the opening 65 by the rotation of the rotation shaft portion 66. On the inner peripheral surface portion of the opening portion 65 of the ring-shaped frame portion 64, a tooth portion 67 projecting inwardly of the opening portion 65 is formed over the entire circumference along the thickness direction, and a spur gear 68 is formed. Is configured.

  On the other hand, as shown in FIG. 22, the susceptor 61 is provided with eleven openings 62 along the entire peripheral direction, and the substrate holders 63 are rotatable in the openings 62, respectively. And is detachable. On the periphery of the substrate holder 63, a tooth portion 71 that meshes with the tooth portion 67 protrudes outward along the thickness direction of the substrate holder 63, and forms a spur gear 69 in the same manner as described above. Yes.

As a result, when the susceptor 61 is rotated by the rotational movement of the rotating shaft portion 66, the substrate holder 63 is moved into the opening 62 by meshing with the tooth portion 67 of the ring-shaped frame portion 64 of the tooth portion 71. The susceptor 61 and the substrate holder 632 form a so-called planetary mechanism.
Then, a semiconductor substrate is mounted on the substrate holder 63, and a plurality of kinds of vapor phase substances are supplied to the semiconductor element in a predetermined environment in the reaction furnace, and reacted at a high temperature to form a film on the semiconductor substrate. To do.

However, when a film is formed in the vapor phase on the surface of the semiconductor substrate, it is assumed that the susceptor 61 on which the semiconductor substrate is placed on each of the substrate holders 63 is transferred using, for example, a robot arm. In this case, in order to convey the susceptor 61 above the ring-shaped frame portion 64 and dispose the susceptor 61 in the opening 65 of the ring-shaped frame portion 64, the inner surface of the ring-shaped frame portion 64 is formed in the thickness direction. It is necessary to mesh the teeth 69 of all the substrate holders 63 in the vertical direction with the teeth 67 provided along.
As a result, since it is difficult to properly and smoothly mesh the teeth 67 of the substrate holder 63 with the teeth 67 of the ring-shaped frame 64, the reaction is performed using a transfer device having a robot arm. It is difficult to transport the susceptor 1 to the furnace.

Therefore, conventionally, when the film formation work on the semiconductor substrate in the reaction furnace is completed, and when the next new semiconductor substrate is replaced, the reaction furnace is opened and film formation is performed manually. It was necessary to take out the completed semiconductor substrate and place a new semiconductor substrate on the substrate holder.
As a result, there has been a problem that the replacement work of the semiconductor substrate on which the film is formed is very complicated and the production efficiency is not good.

  In addition, the inside of the reaction furnace is a closed space of nitrogen, and originally it is necessary to exclude moisture and oxygen. As described above, each time the semiconductor substrate was replaced, the reaction furnace was opened and the work was performed. In each case, since the outside air is mixed in each case, there is a problem that it is necessary to form a sealed space with nitrogen again and the working efficiency is low.

Further, in the conventional semiconductor substrate rotation holding device 60 using a planetary mechanism using a spur gear, the spur gear 69 of the substrate holder 63 is properly meshed with the spur gear 68 of the ring-shaped frame portion 64. Therefore, it is necessary to form the substrate holder 63 with a predetermined diameter. As a result, the diameter of the susceptor 61 also has a predetermined size.
As a result, the substrate holders 63 arranged in the radial direction are largely separated from each other, and a large gap S is formed in the central portion of the susceptor 61. Therefore, a plurality of types of gas phase substances are generated in the reaction furnace. Even if it is supplied, the gas phase substance staying in the void S does not contribute to the film formation of the substrate effectively, so that there is a problem that the supply efficiency of the gas phase substance is not good.

Conventionally, a so-called “gas wheel method” has also been proposed in which gas is supplied to the groove formed on the back side of the substrate holder so that the substrate holder is rotated from the susceptor and the susceptor is also rotated. It was.
However, such a “gas wheel method” is configured to rotate the substrate holder while floating from the susceptor while supplying gas, so that the gas for forming a film on the semiconductor substrate is used. Since a gas different from the phase material is supplied, the flow of the gas phase material for film formation supplied in the vicinity of the substrate holder is obstructed, and the film may not be sufficiently formed. Had.

  An object of the present invention is to form a high-quality film on a semiconductor substrate without using a gas wheel method when a film is formed in a vapor phase on a semiconductor substrate in a reaction furnace by metal organic vapor phase epitaxy. In addition, it is possible to improve the production efficiency without opening the reaction furnace to which the gas phase material has been supplied and manually loading and unloading the substrate, and to improve the supply efficiency of the gas phase material supplied to the reaction furnace. It is an object of the present invention to provide a semiconductor substrate holding device and a semiconductor substrate holding device transfer device.

In order to solve the above-mentioned problem, in the invention according to claim 1, it is used in a reaction furnace to form a film in a vapor phase state on a semiconductor substrate by metal organic vapor phase epitaxy, and is formed in a disk shape. A susceptor that rotates and is formed in a disk shape, is detachably disposed in a plurality of openings provided in the susceptor, and is configured to rotate in the opening by the rotation of the susceptor. Includes a plurality of substrate holders on which a semiconductor substrate is placed, and a rotation holding shaft for rotating the susceptor, which is provided below the susceptor and rotating the semiconductor substrate, wherein the susceptor is a rotation drive shaft. The opening is formed so as to penetrate in the thickness direction of the susceptor, and the substrate holder is provided below the susceptor. And releasably engage in the vertical direction, the engaging portion for rotating the substrate holder within the opening is formed by the rotation of the susceptor, the engaging portion is formed by a planar ring-shaped support member, the support member A plurality of first engagement protrusions are radially arranged on the upper surface of the substrate holder at regular intervals along the circumferential direction, and the first engagement protrusions are formed on the lower surface of the substrate holder. When the plurality of second engaging protrusions that can be engaged are arranged radially along the peripheral edge and the substrate holder is disposed in the opening, the second engaging protrusion is below the opening. is projected disposed towards it, characterized in the said first engaging projections and the engaging child.

Therefore, in the semiconductor substrate rotation holding apparatus according to claim 1, the susceptor is detachably fixed in the vertical direction with respect to the rotation drive shaft, and the opening portion has a thickness of the susceptor. The substrate holder is removably engaged in the vertical direction below the susceptor, and is provided with an engaging portion through which the substrate holder can be rotated by the rotation of the susceptor. Since the planetary mechanism is configured by the holder and the engaging portion, the susceptor can be attached and detached in the vertical direction with respect to the rotation drive shaft while holding the substrate holder.
As a result, it is possible to transport the susceptor by detaching it from the rotational drive shaft by mounting the transport device, and to transport the susceptor and attach it to the rotational drive shaft.
In addition, the first engagement protrusion can be engaged with the second engagement protrusion in the vertical direction, and the engagement can be released in the vertical direction.

According to a second aspect of the present invention , the first engaging protrusion is formed by a plurality of elongated rectangular parallelepipeds protruding upward along the thickness direction of the engaging portion, and the second engaging protrusion. The joint protrusion is formed by a plurality of elongated rectangular parallelepipeds protruding downward along the thickness direction of the substrate holder.

Therefore, in the invention described in claim 2 , the first engagement protrusion formed in the shape of an elongated rectangular parallelepiped and the second engagement protrusion formed in the shape of an elongated rectangular parallelepiped are engaged in the vertical direction.

In the invention described in claim 3, the interval between the first engaging protrusions adjacent to each other is formed to be larger than the width dimension equal to or greater than the second width dimension, and The distance between the second engaging protrusions adjacent to each other is formed to be larger than the width of the first engaging protrusion, and the first engaging protrusion and the second engaging protrusion are Engage with each other with a gap.

Therefore, in the invention described in claim 3 , the susceptor having the substrate holder is fixed to the rotation drive shaft, and the engagement protrusion formed on the lower surface portion of the substrate holder is the engagement protrusion of the engagement portion. In the case where the first engagement protrusion and the second engagement protrusion are disposed between each other, the first engagement protrusion and the second engagement protrusion are disposed with a gap therebetween.

According to a fourth aspect of the present invention , the opening has a diameter that is substantially the same as the radial dimension of the susceptor, and three openings are provided at equal intervals, and the substrate holder is provided in each of the openings. It is arranged.
Therefore, in the invention described in claim 4 , any of the above substrate holders are arranged close to each other.

According to a fifth aspect of the present invention , a plurality of protrusions are provided at the upper end of the rotational drive shaft, and the protrusion is removably inserted in the vertical direction at the center of the susceptor. A plurality of recesses that can be combined are formed.

Therefore, in the invention according to claim 5 , the susceptor is joined to the rotation drive shaft by engaging the plurality of recesses with the plurality of protrusions formed at the upper end of the rotation drive shaft. And the susceptor can be detached from the rotary drive shaft.

In the first aspect of the invention, the susceptor is detachably fixed in the vertical direction with respect to the rotational drive shaft, and the opening is formed to penetrate in the thickness direction of the susceptor. Below the susceptor, the substrate holder is releasably engaged in the up-down direction, and an engaging portion is provided that allows the substrate holder to rotate by the rotation of the susceptor. When a film is formed in a vapor phase on a semiconductor substrate in a reaction furnace by a phase growth method, a high-quality film can be formed on the semiconductor substrate without using a gas wheel method.

  In addition, the susceptor is detachably fixed in the vertical direction with respect to the rotational drive shaft, and the planetary mechanism using a spur gear is not used as in the prior art, and the substrate holder and the engaging portion are engaged in the vertical direction. Since the planetary mechanism to be combined is configured, the susceptor can be removed and attached in the vertical direction with respect to the rotational drive shaft, and a semiconductor substrate on which a gas phase substance is supplied and a film is formed in a reaction furnace, It is not necessary to open the reaction furnace and remove it manually, and it is not necessary to mount a newly processed semiconductor substrate on the substrate holder. The susceptor is reacted using a transfer device while the semiconductor substrate is placed on the substrate holder. Can be removed from the furnace.

  Moreover, since the substrate holder on which the semiconductor substrate to be subjected to film formation is placed on the susceptor can be transferred and installed in the reaction furnace using the transfer device, the semiconductor substrate can be loaded into the reaction furnace. In addition, the unloading efficiency can be improved, and as a result, the processing efficiency related to the film formation of the semiconductor substrate can be improved.

  Furthermore, since it is not necessary to open the reaction furnace each time the semiconductor substrate on which film formation has been completed is taken out of the reaction furnace, the gas phase substance supplied into the reaction furnace is not wasted, The supply efficiency of the phase substance can be improved.

In the invention described in claim 2 , when the susceptor having the substrate holder disposed in the opening is joined to the rotational drive shaft in the vertical direction and removed, the first engagement protrusion and the second engagement protrusion are The first engaging protrusion and the second engaging protrusion can be easily disengaged while being easily engaged.

According to a third aspect of the present invention , a susceptor having a substrate holder is fixed to the rotation drive shaft, and an engagement protrusion formed on the lower surface portion of the substrate holder is in contact with the engagement protrusion of the engagement portion. In the case of being disposed between, the first engagement protrusion and the second engagement protrusion are disposed with a gap therebetween, so that the susceptor and the substrate holder have a diameter. Due to the difference in curvature due to the different dimensions, the arrangement angle between the second engagement protrusion and the first engagement protrusion is different. Therefore, when the susceptor is mounted on the rotary drive shaft, Even when the engaging protrusion is not disposed between the adjacent first engaging protrusions but is disposed on the first engaging protrusion, the susceptor rotates to cause the first vibration vibration or inertial force. The position of the engaging protrusion is moved between the pair of first engaging protrusions, Second engaging projection reliably engages the first engagement projections.

According to a fourth aspect of the present invention , the three substrate holders are provided at equal intervals along the circumferential direction of the susceptor, and the diameter dimension of the substrate holder is substantially the same as the radial dimension of the susceptor. As a result, the substrate holder occupies most of the susceptor, and unlike the conventional case where a planetary mechanism is configured by a spur gear, a large gap is formed between the substrate holders at the center of the susceptor. It will never be done.

  As a result, when a plurality of types of gas phase materials are supplied in the reaction furnace, it is possible to prevent a situation in which the gas phase materials stay in the voids and do not contribute effectively to the film formation of the substrate. The gas phase material is not wasted, and the supply efficiency of the gas phase material can be improved.

In the invention according to claim 5 , the susceptor joins the susceptor to the rotation drive shaft by engaging the plurality of recesses with a plurality of protrusions formed at the upper end of the rotation drive shaft. In addition, since the susceptor can be detached from the rotational drive shaft, the susceptor can be easily attached to and detached from the rotational drive shaft.

It is a conceptual diagram which shows planarly one Embodiment of the rotation holding | maintenance apparatus of the semiconductor substrate which concerns on this invention. FIG. 2 is a cross-sectional view corresponding to the line 2-2 in FIG. 1, showing an embodiment of a semiconductor substrate rotation holding device according to the present invention. It is a cross section which shows one Embodiment of the rotation holding apparatus of the semiconductor substrate which concerns on this invention, and shows a substrate holder slip ring. It is a top view which shows one Embodiment of the rotation holding apparatus of the semiconductor substrate which concerns on this invention, and shows a susceptor main body. FIG. 5 shows an embodiment of a semiconductor substrate rotation holding device according to the present invention, and is a cross-sectional view corresponding to line 5-5 in FIG. It is a back view which shows one Embodiment of the rotation holding apparatus of the semiconductor substrate which concerns on this invention, and shows a susceptor main body. FIG. 2 is a cross-sectional view corresponding to line 2-2 of FIG. 1 showing an embodiment of a heater arrangement, showing an embodiment of a semiconductor substrate rotation holding device according to the present invention. FIG. 5 is a plan view showing an engagement portion, showing an embodiment of a semiconductor substrate rotation holding device according to the present invention. FIG. 9 is a cross-sectional view taken along line 9-9 of FIG. 8, showing an embodiment of a semiconductor substrate rotation holding device according to the present invention. It is a cross section which shows one Embodiment of the rotation holding apparatus of the semiconductor substrate which concerns on this invention, and shows a susceptor slip ring. It is a top view which shows one Embodiment of the rotation holding apparatus of the semiconductor substrate which concerns on this invention, and shows a substrate holder. FIG. 12 is a cross-sectional view corresponding to the line CC in FIG. 11, showing an embodiment of a semiconductor substrate rotation holding device according to the present invention. It is a reverse view which shows one Embodiment of the rotation holding apparatus of the semiconductor substrate which concerns on this invention, and shows a substrate holder. 1 is a conceptual cross-sectional view corresponding to line 2-2 showing an embodiment of a semiconductor substrate rotation holding device and a transfer device according to the present invention, showing a case where a transfer device is used to transfer a susceptor and attach it to a rotary drive shaft. is there. 1 shows an embodiment of a rotation holding device and a transfer device for a semiconductor substrate according to the present invention, a transfer device is used to transfer a susceptor and attach it to a rotation drive shaft, and the engaging protrusion is not completely engaged, It is a conceptual sectional view showing the state where the susceptor is slightly inclined. 1 shows an embodiment of a rotation holding device and a transfer device for a semiconductor substrate according to the present invention, a transfer device is used to transfer a susceptor and attach it to a rotation drive shaft, and the engaging protrusion is not completely engaged, It is a conceptual sectional view showing the state where the susceptor is rotated in an inclined state. 1 shows an embodiment of a semiconductor substrate rotation holding device and a transfer device according to the present invention, wherein the transfer device is used to transfer a susceptor and attach it to a rotation drive shaft; It is a conceptual sectional view showing the state where it rotates in a horizontal state. FIG. 2 is a cross-sectional view corresponding to line 2-2 showing an embodiment of a semiconductor substrate rotation holding device and transfer device according to the present invention. 1 is a conceptual cross-sectional view showing an embodiment of a semiconductor substrate rotation holding device and a transfer device according to the present invention, in which a susceptor is transferred using a transfer device to replace a semiconductor substrate, and a transfer arm unit; It is a figure which shows the state which lifts a susceptor by. 1 is a conceptual cross-sectional view showing an embodiment of a semiconductor substrate rotation holding device and a transfer device according to the present invention, in which a susceptor is transferred using a transfer device to replace a semiconductor substrate, and a transfer arm unit; It is a figure which shows the state which lifted the susceptor by. 1 is a conceptual cross-sectional view illustrating a case where a semiconductor substrate rotation holding device and a transport device according to an embodiment of the present invention are used and a susceptor is transported using the transport device to replace a semiconductor substrate, and the susceptor is removed. It is a figure which shows the state which completed. It is a top view which shows one Embodiment of the rotation holding apparatus and the conveying apparatus of the conventional semiconductor substrate. FIG. 23 is a cross-sectional view corresponding to the line DD of FIG. 22, showing an embodiment of a conventional semiconductor substrate rotation holding device and transfer device.

  Hereinafter, the present invention will be described in detail based on embodiments shown in the accompanying drawings.

〔overall structure〕
As shown in FIGS. 1 and 2, the semiconductor substrate rotating and holding apparatus 10 according to the present embodiment is used in a reaction furnace to form a film in a vapor phase state on a semiconductor substrate by metal organic vapor phase epitaxy. The susceptor 12 is formed in a disk shape and rotates, and is detachably disposed in the three openings 13 formed in the disk shape and opened in the susceptor 12, and the opening of the susceptor 12 by the rotation of the susceptor 12. A plurality of substrate holders 14 on which the semiconductor substrate is placed, and a rotary drive shaft 15 that is provided below the susceptor 12 and rotates the susceptor 12. Have.

  The susceptor 12 is detachably fixed in the vertical direction with respect to the rotary drive shaft 15, and the opening 13 is formed through the thickness of the susceptor 12, and the substrate is below the susceptor 12. An engagement portion 16 is provided in which the holder 14 is releasably engaged in the vertical direction, and the substrate holder 14 can be rotated by the rotation of the susceptor 11.

[Susceptor]
As shown in FIGS. 1 and 2, the susceptor 12 includes a thin disc-shaped susceptor body 17 and a susceptor ring 18 that is fixed over the entire periphery of the upper peripheral edge of the susceptor body 17. Yes.
In this embodiment, as shown in FIGS. 4 and 5, the susceptor 12 is formed to have a diameter of 145 mm, the opening 13 has a diameter of 55.2 mm, and the center-to-center radius L is 37 mm. In this case, three are formed at equal intervals, and the substrate holder 14 is disposed in the opening 13. In the present embodiment, the openings 13 are arranged at an angular position of 120 degrees.

  As shown in FIG. 5, the opening 13 is formed penetrating along the thickness direction of the susceptor body 17, and the cross-sectional shape is formed in a tapered shape that contracts toward the back surface of the susceptor.

  A substrate holder slip ring 19 shown in FIG. 3 is disposed in the opening 13. The substrate holder slip ring 19 is made of glassy carbon, is formed in a substantially planar ring shape, and is configured so that the substrate holder 14 can be rotatably accommodated therein.

  As shown in FIG. 3, the substrate holder slip ring 19 has the same outer cross-sectional contour shape as the cross-sectional shape of the opening 13, and a step portion 20 is formed on the inner peripheral portion.

[Susceptor / Junction]
As shown in FIGS. 4 to 6, the susceptor main body 17 includes a joint portion 21 with the rotation drive shaft 15 projecting from the central portion on the back surface side, and a peripheral protrusion 22 formed at the lower peripheral portion. ing.

  The joint portion 21 includes a short cylindrical bulge portion 23 formed below the susceptor 12 and two concave portions 24 and 24 formed in the bulge portion 23 and opening in the back surface direction. The pair of recesses 24, 24 are formed in a pair in the diameter direction. Further, a step portion 25 to which the susceptor ring 18 shown in FIG. 2 is fixed is formed on the periphery of the surface portion.

[Susceptor / Rotating shaft]
As shown in FIG. 2, the rotary drive shaft 15 is formed in an elongated cylindrical shape as a whole and is joined to an appropriate rotary drive unit in the reaction furnace.

  A joint receiving portion 26 of the susceptor 12 is formed at the upper end portion. As shown in FIGS. 14 and 21, the joint receiving portion 26 is formed to have a larger diameter than the rotational drive shaft main body portion 27, and protrudes upward from the peripheral edge portion of the joint upper end surface portion 28. An annular holding portion 29 that is held from the outside, and two projecting portions 30 and 30 that project upward from the inside of the annular holding portion 29 and are engaged and disposed in the two concave portions, Consists of.

Therefore, when the susceptor 12 is joined to the rotary drive shaft 15, the two protrusions 30, 30 are engaged and disposed in the two recesses 24, 24, thereby causing the rotary drive shaft 15 to be engaged. Is transmitted to the susceptor 12 to rotate the susceptor 12.
As shown in FIG. 7, a plurality of heaters 31 are disposed around the rotational drive shaft 15 over substantially the entire radial direction of the susceptor 12 so as to heat the susceptor 12 from below. Yes.

(Engagement part)
As shown in FIG. 2, FIG. 7, FIG. 14, FIG. 20 or FIG. 21, the susceptor 12 is engaged with the substrate holder 14 when the susceptor 12 is joined to the rotary drive shaft 15 below the periphery of the susceptor 12. An engaging portion 16 that rotates the substrate holder 14 is disposed.

As shown in FIGS. 8 and 9, the engaging portion 16 is formed of a planar ring-shaped support member, and has an outer diameter of 132.6 mm and an inner diameter of 117 mm. The engaging portion 16 includes a susceptor mounting portion 32 formed in an inverted L shape in a side cross section, a plurality of first engaging protrusions 33 formed radially on the upper surface portion of the susceptor mounting portion 32, and the above The first engaging projection 33 is configured by an annular susceptor slip ring 34 shown in FIG. 10 disposed on the susceptor mounting portion 32 outside in the length direction.

The first engagement protrusion 33 is a plurality of elongated rectangular parallelepipeds protruding upward along the thickness direction of the engagement portion 16, and has a length dimension of 3.5 mm, a width dimension of 1 mm, and a height dimension of 1.3 mm. In the present embodiment, 60 are formed as a whole.
The first engaging protrusion 33 is formed on the inner half in the width direction of the upper surface portion 35 of the engaging portion 16, and the susceptor shown in FIG. The slip ring 34 is fixed.
The susceptor slip ring 34 is formed in a flat ring shape, and when arranged, the susceptor 12 is configured to contact the lower surface of the peripheral edge of the susceptor body 17 and rotate smoothly.

[Substrate holder]
As shown in FIGS. 11 to 13, the substrate holder 14 disposed in the opening 13 is formed in a small and thin disk shape, and includes a substrate holder main body 36 and an upper portion of the substrate holder main body 36. And the substrate mounting portion 37 formed to have a large diameter.

A plurality of second engaging projections 38 that can engage with the first engaging projections 33 formed on the susceptor mounting portion 37 are formed radially on the periphery of the lower surface portion of the substrate holder main body portion 36. ing. A recess 39 for placing the substrate is formed over substantially the entire upper surface of the substrate placement portion 37.
The thickness of the substrate mounting portion 37 is the same as the distance between the surface of the step 20 of the substrate holder slip ring 19 and the surface 44 of the substrate holder slip ring 19 shown in FIG. The thickness of the main body 36 is formed to be the same as the distance between the step surface and the back surface 45 of the substrate holder slip ring 19.

Therefore, when the substrate holder 14 is housed in the substrate holder slip ring 19 fixed to the opening 13 of the susceptor 12, the surface portion of the substrate mounting portion 37 is connected to the surface 44 of the substrate holder slip ring 19. The second engagement protrusions 38 are arranged on the same surface and protrude below the back surface 45 of the base holder slip ring 19 so that they can engage with the first engagement protrusions 33. It is configured.
Similar to the first engagement protrusion 33, the second engagement protrusion 38 is formed with a length dimension of 3.5 mm, a width dimension of 1 mm, and a height dimension of 1.3 mm. As a whole, 24 are arranged radially.

  In the present embodiment, the substrate holder 14 is made of SiC (silicon carbide), and the recess 39 is formed to have a size capable of fitting one 2-inch substrate.

  As shown in FIG. 1, the substrate holder 12 is arranged at three equal intervals along the circumferential direction of the susceptor 12, and the diameter dimension of the substrate holder 14 is the same as that of the peripheral protrusion 22 of the susceptor 12. It is formed substantially the same as the distance between the joint 21.

The distance between the first engaging protrusions 33 adjacent to each other is set to be larger than the width dimension of the second engaging protrusion 38 and the second engaging protrusions adjacent to each other. The distance between the projections 38 is formed to be larger than the width of the first engagement protrusion 33.
As a result, the first engagement protrusion 33 and the second engagement protrusion 38 are configured to engage with each other with a gap therebetween.

[Conveyor]
As shown in FIGS. 14 and 15, the susceptor transfer device 41 includes a pair of transfer arm portions 42 and 42 that hold the susceptor 12. The transfer arm portions 42 and 42 are configured to hold the peripheral protrusion 22 of the susceptor 12, and a support portion 43 having an approximately L-shaped inner cross section is provided to support the peripheral protrusion 22 from below. It has been.

In the present embodiment, the transfer arm portions 42 and 42 are configured to be arranged in a pair in the diameter direction of the susceptor 12 when the susceptor 12 is transferred.
The susceptor transfer device 41 is moved so that an actuator having an appropriate configuration not shown in the figure, transfer arm portions 42 and 42 driven by the actuator, and the transfer arm portions 42 and 42 grip the peripheral protrusion 22 of the susceptor. And a sensor having an appropriate configuration for sending a detection signal to the actuator so that it can be controlled. The susceptor 12 placed outside the reaction furnace is gripped and transported into the reaction furnace and joined to the rotary drive shaft 15. The susceptor 12 can be detached from the rotary drive shaft 15 and conveyed to the outside of the reactor while being engaged with the engaging portion 16.

[Action]
A case will be described below in which a film is formed on a semiconductor substrate in a vapor state by metal organic vapor phase epitaxy using the semiconductor substrate rotation holding device according to the present embodiment.
First, the substrate holder slip rings 19, 19, 19 shown in FIG. 3 are fitted into the three openings 13, 13, 13 of the susceptor 12. Thereafter, as shown in FIGS. 1 and 2, the substrate holder 14 is fixed on the substrate holder slip ring 19 in each of the openings 13, 13, 13.

  In this case, the lower peripheral edge 40 of the substrate mounting portion 37 of the substrate holder 14 is disposed so as to be able to engage with the step portion 20 of the substrate holder slip ring 19 and rotate. In addition, the 2-inch semiconductor substrate is fixed in a state of being engaged with a concave portion 39 of the substrate holder mounting portion 37 formed on the upper portion of the substrate holder 14.

  Thereafter, the susceptor 12 is transferred into the reaction furnace using the susceptor transfer device 41. As shown in FIG. 14, the susceptor transport device 41 drives the transport arm portions 42, 42 by an actuator (not shown) and holds the peripheral protrusion 22 of the susceptor 12 by the transport arm portions 42, 42. The joint portion 21 formed on the back surface portion of the steel plate is transported to a position reaching directly above the rotary drive shaft 15 disposed in the reaction furnace, and then the transport arm portions 42 and 42 are lowered by the actuator to receive the joint. The annular holding part 29 of the part 26 holds the bulging part 23 of the joint part 21, and the pair of protrusion parts 30, 30 of the rotary drive shaft 15 are in the pair of recesses 24, 24 of the joint part 21. Insert and arrange. Thereby, the susceptor 12 is joined to the rotational drive shaft 15 via the joint portion 21 and the joint receiving portion 26, and the rotational drive force of the rotational drive shaft 15 is transmitted to the susceptor 12.

The susceptor body 17 is placed on the engaging portion 16 via the susceptor slip ring 34, and the second engaging protrusions 38 of the substrate holder 14 are formed on the engaging portion 16, respectively. It arrange | positions between the made 1st engaging protrusion 33. FIG.
In this state, when the rotational drive shaft 15 starts to rotate at, for example, two rotations per minute by the rotational driving force from the rotation driving unit, the susceptor 12 rotates at two rotations per minute on the susceptor slip ring 34 of the engaging unit 16. Start spinning. In this case, since the second engagement protrusions 38 of the three substrate holders 17 are engaged with the first engagement protrusions 33 of the engagement portion 16, the rotation of the susceptor 12 causes the three The substrate holder 17 also starts to rotate within the opening 13.

When the joint portion 21 of the susceptor 12 is joined to the joint receiving portion 26, the second engaging projection 38 of any one of the substrate holders 17 of the three machines is connected to the first engagement member. In some cases, the protrusions 33 may be placed on the mating protrusions 33.
When the second engagement protrusion 38 is arranged so as to overlap the first engagement protrusion 33 in this way, as shown in FIG. 15, the end A on the side where the susceptor 12 is arranged is engaged. It is slightly higher on the joint 16 and the second engagement protrusion 38 is lower in the end B where the first engagement protrusion 33 is disposed and is slightly inclined along the radial direction. It will be arranged on the joint 16. In the present embodiment, the height at which the end A is lifted obliquely is 1.1 mm.

  In this state, when the rotation drive shaft 15 starts to rotate at two rotations per minute by the rotation driving force from the rotation driving unit, for example, the susceptor 12 rotates at two rotations per minute on the susceptor slip ring 34 of the engaging unit 16. Start spinning. In this case, since the second engaging protrusion 38 of any of the three substrate holders 17 is engaged with the first engaging protrusion 33 of the engaging portion 16, Even when 38 is disposed on the first engagement protrusion 33, the inertia and vibration due to the rotation of the susceptor 21 causes the second engagement protrusion 38 to be moved as shown in FIG. The first engaging protrusion 33 arranged in the position drops from the second engaging protrusion 38 and engages with the second engaging protrusion 38.

  In the present embodiment, the interval between the first engaging protrusions 33, 33 adjacent to each other is formed to be larger than the width of the second engaging protrusion 38, and Since the interval between the second engaging protrusions 38 adjacent to each other is formed to be larger than the width of the first engaging protrusion 33, Since any of the first engaging protrusions 38 is placed on the second engaging protrusion 33 as described above, the second engaging protrusion 38 is engaged with the second engaging protrusion 38 in a loosely fitted state. Even so, the engaged state can be easily ensured by the rotation of the susceptor 12.

Thereafter, the rotation of the rotary drive shaft 15 is increased to 10 rotations per minute, whereby each substrate holder 14 rotates at 10 rotations per minute, while rotating around the susceptor 12, and at the same time 25 rotations per minute in the opening 13 Rotate with.
Then, based on the metal organic chemical vapor deposition method, for example, a mixed gas of hydrogen gas, ammonia gas and trimethyl gallium (TMG) is supplied into a sealed reaction furnace, and the three machines under a temperature condition of 1100 ° C. A gallium nitride crystal is grown on a semiconductor substrate placed on the substrate holder 14.

  Thus, when the gallium nitrogen crystal is formed in a film shape on the semiconductor substrate, the rotation of the rotary drive shaft 15 is stopped, as shown in FIGS. According to the procedure, the transfer arm portions 42 and 42 are driven by the susceptor transfer device 41 to bring the transfer arm portions 42 and 42 closer from below the peripheral protrusion 22 of the susceptor 12, and the support arm 43 of the transfer arm portion 42 has a peripheral edge. The protrusion 22 is supported from below, and the susceptor 12 is lifted upward and carried out of the reactor.

[Effects of Examples]
Therefore, in the present embodiment, as described above, the susceptor 12 is detachably fixed to the rotary drive shaft 15 in the vertical direction, and a conventional planetary mechanism using a spur gear is used. A planetary mechanism in which the second engagement protrusion 38 formed on the lower surface portion of the substrate holder 14 and the first engagement protrusion 33 formed on the upper surface of the engagement portion 16 are engaged in the vertical direction. Since it is configured, the susceptor 12 can be easily detached and attached in the vertical direction with respect to the rotary drive shaft 15.

  As a result, a semiconductor substrate on which a gas phase substance is supplied and a film is formed in a reaction furnace as in the prior art is taken out manually by opening the reaction furnace, and a semiconductor substrate to be newly processed is placed in the reaction furnace. The susceptor 12 can be taken out of the reaction furnace using the susceptor transfer device 41 with the semiconductor substrate placed on the substrate holder 12 without having to be mounted on the substrate holder 12 on the susceptor 12. The substrate holder 14 on which the semiconductor substrate 11 to be newly subjected to the film formation process is placed on the susceptor 12 can be transferred and installed in the reaction furnace using the susceptor transfer device 41.

  Further, since the semiconductor substrate is mounted on the substrate holder 14 and rotates on the substrate holder 14 by the planetary mechanism and further rotates around the susceptor 12, each semiconductor substrate is placed in the reactor. The temperature distribution acting on the film can be made uniform, and the formed film pressure distribution can be made uniform.

  Further, in this embodiment, unlike the conventional planetary mechanism using a spur gear, the planetary mechanism is configured by the engagement of the engagement protrusions 33 and 38 in the thickness direction of the susceptor 12. Therefore, unlike the semiconductor substrate rotation holding device using a planetary mechanism using a spur gear, the diameter of the susceptor 12 can be reduced.

As a result, the opening 13 in which the substrate holder 14 is disposed has a diameter dimension substantially the same as the radial dimension of the susceptor 12, and three openings are provided at equal intervals, and the substrate holder 14 is formed in the opening 13. Therefore, unlike the conventional case where the planetary mechanism is configured by a spur gear, a large gap is not formed between the substrate holders at the center of the susceptor.
As a result, when a plurality of types of gas phase materials are supplied in the reaction furnace, it is possible to prevent a situation in which the gas phase materials stay in the voids and do not contribute effectively to the film formation of the substrate. The gas phase material is not wasted, and the supply efficiency of the gas phase material can be improved.

  The present invention can be widely applied to a semiconductor manufacturing apparatus for forming a film on a semiconductor substrate in a chemical vapor deposition method and a transfer apparatus for a semiconductor substrate rotation holding device.

DESCRIPTION OF SYMBOLS 10 Semiconductor substrate rotation holding device 12 Susceptor 13 Opening part 14 Substrate holder 15 Rotation drive shaft 16 Engagement part (support member)
17 Susceptor body 18 Susceptor ring 19 Substrate holder slip ring 20 Step part 21 Joint part 22 Peripheral protrusion 23 Bump part 24 Recess part 25 Step part 26 Joint receiving part 27 Rotation drive shaft main body part 28 Joint upper end surface part 29 Annular holding part 30 Protrusion part 31 Heater 32 Susceptor mounting part 33 First engagement protrusion 34 Susceptor slip ring 35 Upper surface part 36 Substrate holder main body part 37 Substrate mounting part 38 Second engagement protrusion 39 Recess 40 Peripheral lower part 41 Susceptor transport device 42 Transfer arm part 43 Support part 44 Front surface 45 Back surface 60 Semiconductor substrate rotation holding device 61 Susceptor 62 Opening part 63 Substrate holder 64 Ring-shaped frame part 65 Opening part 66 Rotary shaft part 67 Tooth part 68 Spur gear 69 Spur gear 71 Tooth part

Claims (8)

Used in a reactor to form a film in a vapor phase on a semiconductor substrate by metal organic vapor phase epitaxy,
A susceptor that is formed in a disk shape and rotates, and is formed in a disk shape and is detachably disposed in a plurality of openings provided in the susceptor, and is configured to rotate in the opening by rotation of the susceptor. A rotation holding device for a semiconductor substrate, comprising: a plurality of substrate holders on which the semiconductor substrate is placed; and a rotation drive shaft provided below the susceptor for rotating the susceptor.
The susceptor is detachably fixed in the vertical direction with respect to the rotational drive shaft, and the opening is formed to penetrate in the thickness direction of the susceptor,
A semiconductor substrate characterized in that an engagement portion is provided below the susceptor so that the substrate holder is releasably engaged in the vertical direction and the substrate holder is rotated in the opening by the rotation of the susceptor. Rotation holding device.   The engaging portion is formed in a ring shape as a whole, and a plurality of first engaging protrusions are radially arranged on the upper surface portion at regular intervals along the circumferential direction, and the lower surface portion of the substrate holder A plurality of second engagement protrusions that can be engaged with the first engagement protrusions are radially disposed along the peripheral edge, and when the substrate holder is disposed in the opening, 2. The rotation holding device for a semiconductor substrate according to claim 1, wherein the second engaging protrusion is disposed so as to protrude below the opening and engages with the first engaging protrusion.   The first engagement protrusion is formed by a plurality of elongated rectangular parallelepipeds protruding upward along the thickness direction of the engagement portion, and the second engagement protrusion is formed in the thickness direction of the substrate holder. 3. The semiconductor substrate rotation holding device according to claim 2, wherein the rotation holding device is formed by a plurality of elongated rectangular parallelepipeds projecting downward along the semiconductor substrate.   The interval between the first engaging protrusions adjacent to each other is formed to be larger than the width of the second engaging protrusion, and the interval between the second engaging protrusions adjacent to each other. Is formed with a gap dimension larger than the width dimension of the first engagement protrusion, and the first engagement protrusion and the second engagement protrusion are engaged with each other with a gap therebetween. A rotation holding apparatus for a semiconductor substrate according to claim 3.   The diameter of the opening is substantially the same as the radial dimension of the susceptor, and three openings are formed at equal intervals, and the substrate holder is disposed in each of the openings. 3. A semiconductor substrate rotation holding apparatus according to 2.   A plurality of protrusions are provided at the upper end of the rotary drive shaft, and a plurality of recesses are formed at the center of the susceptor so that the protrusions can be releasably inserted in the vertical direction. 6. A transport device for a rotation holding device for a semiconductor substrate according to claim 5. Used to form a film in a vapor state on a semiconductor substrate by metal organic vapor phase epitaxy,
It is formed in a disk shape and detachably engages with a rotary drive shaft disposed below, and a semiconductor substrate is placed on the upper surface, and is rotatably disposed in a plurality of opened openings. A transport apparatus for a semiconductor substrate rotation holding apparatus, comprising: a transfer device that detachably attaches or removes a susceptor having a substrate holder to and from the rotation drive shaft, the transfer arm section holding the susceptor.   8. The transfer apparatus for a semiconductor substrate rotation holding apparatus according to claim 7, wherein the transfer arm section is configured to hold a peripheral edge portion of the susceptor.