TW201430914A - Method for manufacturing crystalline semiconductor film - Google Patents

Abstract

The manufacturing method in this invention is emitting a pulsed laser which has a line-beam shape and a minor axis width of 100-500 μ m onto a non-monocrystalline semiconductor film. The cross-sectional shape of a beam of the pulsed laser in its minor axis direction has a flat portion, and the pulsed laser moves each pulse by relatively scanning the film. The pulsed laser has an emission number n of overlapped emission onto the film. The pulsed laser has an emission-pulse energy density E lower than an emission-pulse energy density at which microcrystallization occurs in the non-monocrystalline semiconductor film through emission of the pulsed laser, where a width of a channel region of a transistor is defined as b. The number n of emissions of the pulsed laser is more than or equal to (n0 - 1), where the number of emissions by which crystal grain diameter growth by emission of the pulsed laser with the emission-pulse energy density E is saturated is defined as n0. The pulsed laser scanning direction is in longitudinal direction of the said transistor's channel region, and each of the said pulses has a moving distance c less than b.

Description

Method for producing crystalline semiconductor film

The present invention relates to a method for producing a crystalline semiconductor film, which is characterized in that a pulse beam of a line beam shape is multi-illuminated while moving on a non-single-crystal semiconductor film (overlapped, overlapped) Irradiation).

In general, a thin film transistor for a television (TV) or personal computer (PC) display is constructed by amorphous 以下 (hereinafter referred to as a-Si), which is used in some ways. Crystallization (hereinafter referred to as p-Si) can significantly improve the performance as a TFT. Now, the excimer laser annealing technology, which is a process for crystallization of ruthenium at a low temperature, has been put into practical use, and is frequently used for small-sized displays such as mobile phones, and further for large-screen displays and the like. Practical.

This laser annealing method is a method in which a non-single-crystal semiconductor film is irradiated with a quasi-molecular laser having a high pulse energy, and a semiconductor that absorbs light energy is melted or semi-molten, and then rapidly cooled to be crystallized at the time of solidification. . At this time, in order to process a wide range, the pulse laser shaped into a linear beam shape is relatively in the short axis direction. Irradiate while scanning. Usually, scanning of a pulsed laser is performed by moving a mounting table provided with a single crystal semiconductor film.

In the scanning of the pulsed laser, the pulsed laser is moved in the scanning direction at a predetermined pitch in order to irradiate the pulsed laser at the same position of the non-single-crystal semiconductor film a plurality of times (see, for example, Patent Document 1). Thereby, laser annealing treatment for a large-sized semiconductor film can be performed. Further, in Patent Document 1, the problem is that the unevenness (deviation) of crystals caused by the sequential scanning of the laser is a cause of variation between elements.

Therefore, in order to solve this problem, in Patent Document 1, the size S of the channel region in the scanning direction of the pulse laser and the scanning pitch P of the pulse laser are approximately S=nP (n is 0 except for 0). In addition to the integer), the crystal distribution of the crystalline ruthenium film is periodically changed in the scanning direction of the pulsed laser light, and the crystallinity distribution of the crystalline ruthenium film in the channel region of each of the thin film transistors is made. The change in the period of the pattern becomes equal.

[First technical literature] [licensed literature]

[Patent Document 1] Japanese Patent Laid-Open No. Hei 10-163495

However, controlling the integer multiple of the scanning pitch size to conform to the size of the channel region is accompanied by difficulty in accuracy, and the device cost is greatly improved if high-precision scanning is to be performed.

If the width of the beam in the short-axis direction is sufficient, the scanning pitch can be increased, and It can prevent the situation that the channel area can only be scanned by the beam edge of each pulse. However, in this state, the transistor which is irradiated with the edge of the primary beam in the channel region coexists with the transistor (0 times) which is not irradiated by the edge of the beam in the channel region, and the characteristic is generated between the transistors. deviation.

Therefore, the scanning pitch is made small, and the beam edge of each pulse must be irradiated in a predetermined number of times in the channel region, and the variation in crystallinity can be reduced. Thereby, the above-mentioned transistor which is irradiated by the edge and the transistor which is not irradiated by the edge will not coexist. Further, since the difference in the number of times is controlled once, the variation in characteristics is remarkably reduced as compared with the presence or absence of the irradiation of the edge.

Thus, the linear region on the semiconductor illuminated by the edge portion is considered to affect the movement of the carrier in the channel, so that the linear edge is located orthogonal to the channel width. The direction of scanning (ie, the direction of movement of the carriers within the channel) is set to the scanning direction of the pulsed laser. Thereby, it is desirable to have a good carrier movement characteristic for the portion of the passage region where the irradiation to the edge of the beam is not performed.

However, in the above scanning direction, a transistor such as a channel having a channel width smaller than a channel length (channel width/channel length of 1 or less) is compared with a transistor having a channel width/channel length exceeding 1 due to a channel width. As a result, the linear region which is irradiated with the above-mentioned edge in the channel region and the region which is not irradiated with the edge coexist in the width direction. As a result, unevenness in resistance or the like in the channel width direction occurs, and unevenness in the width direction occurs in the movement of the carrier, and there is a problem that the transistor characteristics may be affected. And the edge is applied to the source or a part of the drain It also causes problems with unevenness in the width direction.

In view of the above, it is an object of the present invention to provide a method for producing a crystalline semiconductor film which can perform scanning without requiring high-precision pulsed laser, variation in characteristics of the transistor, and crystallization.

That is, the method for manufacturing a crystalline semiconductor film according to the present invention is a pulse laser beam of linear shape of the non-monocrystalline semiconductor film is a beam width of minor axis 100 ~ 500 μ m, having a flat portion in the cross-sectional shape of the beam short axis direction of the light beam A method of manufacturing a crystalline semiconductor film in which the pulse is n-aligned to irradiate the non-single-crystal semiconductor film with a number of times of irradiation, and the channel length of the transistor formed in the semiconductor film is b. (100 μm or less); the pulsed laser light has an irradiation pulse energy density lower than that of the non-single-crystallized semiconductor film by the irradiation of the pulsed laser, and is irradiated by multiple times The irradiation pulse energy density E for saturating the crystal grain size growth; and the irradiation of the pulsed laser having the irradiation pulse laser energy density E, the number of times of irradiation when the crystal grain size is saturated is n0, and the number of times of the pulse laser irradiation n is (n0-1) or more; the scanning direction of the pulse laser is the channel length direction of the transistor, and the movement amount c of each pulse is smaller than b.

In the second aspect of the invention, the method for producing a crystalline semiconductor film according to the second aspect of the invention is characterized in that the number n of pulsed laser irradiations is (n0-1) or more and 3. Below n0.

In the third or second aspect of the invention, the method for producing a crystalline semiconductor film according to the third aspect of the invention is characterized in that the amount of movement is less than b/2.

In the method of producing the crystalline semiconductor film of the present invention according to the fourth aspect of the present invention, the method of the present invention is characterized in that the amount of movement is 5 μm or more.

The method for producing a crystalline semiconductor film according to the fifth aspect of the present invention, wherein the ratio of the channel width to the channel length (channel width/channel length) of the transistor is 1 or less.

In the method of producing the crystalline semiconductor film of the present invention according to any one of the first to fifth aspects of the present invention, the non-single crystal semiconductor is germanium.

The method of producing a crystalline semiconductor film according to the seventh aspect of the present invention, wherein the pulsed laser is a excimer laser.

As described above, the pulsed laser has a flat portion (beam width a) in which the intensity of the cross-sectional shape of the beam in the short-axis direction is flat. On the other hand, the maximum energy intensity of the pulsed laser can be calculated by averaging the intensity of the flat portion. Further, there is usually a steepness on the both sides of the flat portion which is gradually decreased in strength toward the outside.

The minimum number of times of irradiation when the crystal grain size is saturated by the irradiation of the pulse laser of the irradiation pulse energy density E of the pulse laser is set to n0. Further, the irradiation pulse energy density E is set to a value lower than the irradiation pulse energy density at which the non-single-crystal semiconductor film is crystallized by the irradiation of the pulsed laser. Whether or not microcrystallization is generated can be judged by an electron microscope photograph or the like.

When the value of the irradiation pulse energy density is larger than the value of the microcrystallization, the crystal grain size becomes extremely small, and the electron mobility of the semiconductor becomes 1/10.

Further, the crystal grain size is saturated by the irradiation of the pulsed laser light having the pulse energy density E, that is, the individual particle diameters are all in a state in which the particle diameter does not increase even if the number of times of irradiation is increased.

Further, if the number of times of laser irradiation is not up to (n0-1), the growth of the crystal grain size is insufficient, and the crystals of the different particle diameters are mixed, and variations in electron mobility are caused. For the same reason, it is preferable to be above n0.

Moreover, the number of irradiations n of the laser is preferably set to 3. Below n0. If it exceeds 3. N0, the productivity will be significantly reduced. Furthermore, for the same reason, the laser irradiation number n is preferably set to 2. Below n0.

When the pulse laser is irradiated, if the channel length of the transistor on the semiconductor film is b, the scanning pitch of the pulse laser, that is, the amount of movement per pulse is c is smaller than b. Thereby, the number of seams of the laser pulses appearing in each channel region becomes one or two or more, and the performance variation of the transistor can be reduced. On the other hand, when the movement amount c is smaller than b/2, the seam in the channel region becomes n or (n+1) or more (but n is an integer of 2 or more). When the amount of movement c becomes larger than b, the seam in the passage region becomes zero or one, and the variation in the performance of the transistor in the passage region becomes large.

Alternatively, the transistor may be formed as a channel region upon irradiation of a pulsed laser. Alternatively, the transistor may be formed after that.

In addition, the channel length of the semiconductor film to which the present invention is applied is regarded as 100 μm or less. Further, the present invention is not particularly limited as long as it is in the above range, and is preferably represented by a channel length of 6 to 40 μm.

With the above-described number of laser irradiations n and the amount of movement c of each pulse, the beam width a of the pulsed laser is expressed as a = n‧c. The above beam width is preferably from 100 to 500 μm. If the beam width is too large, and the energy density is maintained constant, since the beam length in the long-axis direction of the pulse laser becomes small, the area that can be processed by one scan becomes small, and the processing efficiency is lowered. Further, when the beam width becomes less than 100 μm, the scanning pitch becomes small, and the production efficiency is lowered.

Further, as the present invention, the amount of movement per pulse is not limited to a specific amount, and for example, it is preferably 5 μm or more.

The semiconductor to be processed in the present invention is not limited to a specific material, but a preferred crucible can be cited. Further, as the pulse laser, a preferred excimer laser can be cited. Further, in the production method of the present invention, in addition to the crystallization of the non-single crystal semiconductor film, the crystal semiconductor film may be modified by single crystal or the like.

As described above, the method for producing a crystalline semiconductor film according to the present invention is such that the non-single-crystal semiconductor film has a linear beam shape having a short beam width of 100 to 500 μm and a beam cross-sectional shape in the short-axis direction of the beam having a flat portion. Pulsed laser, relative to scanning, moving each pulse to the above-mentioned non-single crystal half with the number of irradiations n A method for producing a crystalline semiconductor film in which a conductor film is superimposed and irradiated to crystallization includes: a channel length of a transistor formed in the semiconductor film is set to be b (100 μm) or less; and the pulsed laser has a lower laser beam than the pulsed laser beam Irradiation pulse energy density at which the microcrystallized irradiation pulse energy density is generated in the non-single-crystal semiconductor film, and the crystal grain size is saturated by a plurality of irradiations; pulse laser irradiation by irradiating the pulse energy density E In the irradiation, the number of times of irradiation when the crystal grain size is saturated is n0, and the number n of irradiations of the pulse laser is (n0-1) or more; and the scanning direction of the pulse laser is the long direction of the channel of the transistor, Further, since the amount of movement c of each of the above pulses is set to be smaller than b, the laser annealing treatment can be efficiently performed by the ideal number of pulsed laser irradiations and the amount of movement of each pulse. Further, variations in transistor characteristics can be reduced due to irradiation of the beam edge.

1‧‧‧Mobile Station

2‧‧‧Non-single crystalline semiconductor film

3‧‧‧pulse laser

3a‧‧‧beam seams

10‧‧‧Thin Semiconductor

11‧‧‧ source

12‧‧‧汲polar

13‧‧‧Channel Department

Fig. 1 is a view showing a state in which a non-single-crystal semiconductor film is irradiated with a pulsed laser in an embodiment of the present invention.

Fig. 2 is a view similarly showing the cross-sectional shape of the beam in the scanning direction of the pulse laser.

Fig. 3 similarly shows a relationship between the energy density of the irradiation pulse according to the pulse laser and the irradiation of the pulsed laser, and the size of the crystal grain size.

Fig. 4 is a view similarly showing the relationship between the number of times of irradiation and the crystal grain size in the case where the pulse laser has a specified irradiation pulse energy density.

5(a), 5(b), and 5(c) are similar views showing the state of occurrence of the beam joint in the relationship between the amount of movement of each pulse and the width of the channel region.

Fig. 6 shows a pictorial substitute photograph of a crystalline semiconductor in an embodiment of the present invention.

Fig. 7 similarly shows a graph showing the relationship between the change in particle diameter and the number of irradiations.

An embodiment of the present invention will be described below.

Fig. 1 shows a state in which a substrate placed on a mobile station 1 is irradiated with a pulsed laser 3 comprising a quasi-molecular laser having a linear beam shape. A non-single crystal semiconductor film 2 such as an amorphous germanium having a film thickness of 35 to 55 nm is formed on the substrate. Further, as the present invention, the film thickness is not limited to the above range.

The pulsed laser 3 has a linear beam length L and a beam width a, and by moving the mobile station 1 at a predetermined pitch, the pulsed laser 3 is scanned while irradiating the non-single-crystal semiconductor film 2 at a predetermined pitch and number of times of irradiation. on. Further, the scanning of the pulse laser 3 may be performed on the non-single crystal semiconductor film 2, or the non-single crystal semiconductor film 2 may be moved as described above, or the pulse laser 3 may be moved. . And it can also be a combination of both.

Fig. 2 shows the cross-sectional shape of the beam in the scanning direction of the pulsed laser 3. A high-strength range having an energy intensity of 96% or more with respect to the maximum energy intensity, and almost all of the above-described high-strength ranges form a flat portion. The width of the above flat portion is expressed as the beam width a.

Further, when the non-single-crystal semiconductor film 2 is irradiated, the pulse laser 3 is set to an irradiation pulse energy density E in which the non-single-crystal semiconductor film 2 is not crystallized. As the irradiation pulse energy density, for example, 320 to 420 mJ/cm ^{2 is} exemplified. However, as the present invention, the irradiation pulse energy density is not limited to a specific range.

Fig. 3 is a view showing the dimensional relationship of the crystal grain size in accordance with the irradiation pulse energy density and the irradiation of the pulsed laser. In the range where the irradiation pulse energy density is low, the irradiation pulse energy density is increased to increase the crystal grain size. For example, if the energy density of the irradiation pulse in the middle becomes larger than the irradiation pulse energy density E1, the crystal grain size rapidly increases. On the other hand, if the energy density of the irradiation pulse is increased to some extent, even if the energy density of the irradiation pulse is further increased, there is almost no increase in the crystal grain size, and if the energy density E2 of an irradiation pulse is exceeded, the crystal grain is obtained. The diameter will rapidly become smaller and cause microcrystallization. Thus, the above-mentioned irradiation pulse energy density E can be E E2 said.

When the irradiation pulse energy density is set to the above-described E value, when the non-single crystal semiconductor film 2 is irradiated, the number of times of irradiation is set to be more than a certain number of times, and the crystal grain size is grown to be saturated. The growth saturation of the crystal grain size is judged by the SEM photograph.

4 is a graph showing the relationship between the crystal grain size and the number of times of irradiation when the irradiation pulse energy density E is set to the above-described irradiation pulse energy density E1 or irradiation pulse energy density E2. In the case of any of the irradiation pulse energy densities, the increase in the number of irradiations will increase the crystal grain size until a certain number of irradiations. However, when a certain number of irradiations is reached, the growth of the crystal grain size cannot be performed and is saturated. . This number of irradiations is represented by the number of irradiations n0 in the present invention.

With respect to the above-described irradiation number n0, the actual number of irradiations n is set to be (n0-1) or more and 3‧n0 or less. Thereby, the non-single crystal semiconductor film 2 can be made effective and effective. Crystallize at a rate.

The crystalline semiconductor film crystallized by the irradiation of the above-described pulsed laser forms a thin film semiconductor at a predetermined pitch. The above spacing is preferably set to be 1 mm or less. Further, the thin film semiconductor has various specified channel lengths b, and the channel length b is 100 μm or less, and the ideal design is 6 to 40 μm .

The predetermined state of arrangement of the thin film semiconductors 10 on the non-single-crystal semiconductor film 2 is shown in FIG. Each of the thin film semiconductors 10 has a source 11 and a drain 12 in the channel portion 13 between the source 11 and the drain 12, and a channel length b is formed in the scanning direction of the pulsed laser of the channel portion 13. When the pulse laser 3 is irradiated and moved by the scanning pitch (the amount of movement per pulse) c of the non-single-crystal semiconductor film 2, it appears on the crystallized semiconductor film corresponding to the movement of each pulse. Beam joint 3a.

Fig. 5(a) shows the state of occurrence of the beam joint 3a in the case where the amount of movement c of each pulse is larger than the length b of the above-mentioned passage. In this example, when the beam seam 3a is not positioned in the channel portion 13 (0 strips), one characteristic occurs, and the characteristic deviation of the thin film semiconductor 10 is increased.

Fig. 5(b) shows the state of occurrence of the beam joint 3a when the amount of movement c of each pulse is 1/2 or more of the channel length b and smaller than the channel length b. In this example, when one or two of the beam seams 3a appear in the channel portion 13, the characteristic deviation of the thin film semiconductor 10 is greatly reduced as compared with Fig. 5(a).

Fig. 5(c) shows the state of occurrence of the beam joint 3a in the case where the amount of movement c of each pulse is smaller than 1/2 of the width b of the channel range. In this example, when the beam seam 3a appears n or (n+1) or more in the channel portion 13, (but n is an integer of 2 or more), the characteristic deviation of the thin film semiconductor 10 is remarkably reduced.

[Example 1]

An embodiment of the present invention will be described below.

A 50 nm-thick amorphous iridium was used as a non-single-crystal semiconductor film, and the number of times of irradiation was changed under the following conditions to perform pulsed laser irradiation.

Excimer laser: LSX315C / wavelength 308nm, frequency 300Hz

Beam size: beam length 500mm × beam width 0.16mm

The flat portion of the high-intensity region where the beam width is 96% or more of the maximum energy intensity

Scanning pitch: 40μm~8μm

Irradiation pulse energy density: 370 mJ/cm ²

Channel length: 20μm

In the above-described pulsed laser, the energy density of the irradiation pulse is below the energy density of the irradiation pulse of the crystallite, and it is considered that the crystal grain size is gradually grown from the number of times of irradiation to the number of times of irradiation 8 times, and the crystal is crystallized after 8 times of irradiation. The particle size is saturated.

The photograph of the portion irradiated with a pulsed laser at the designated number of irradiations was observed by SEM photograph, and the above photograph is shown in Fig. 6. As shown in Fig. 6, good crystallization was achieved 8 times in the number of irradiations, and even when the number of irradiations was increased by 12, 16, or 20 times, an increase in crystal grain size was hardly observed.

Fig. 7 is a graph showing changes in crystal grain size corresponding to the number of irradiations, and the crystal grain size increases in accordance with an increase in the number of irradiations before the number of times of irradiation reaches eight times. In the irradiation No increase in crystal grain size was observed after 8 times.

Therefore, the number of times of irradiation of eight or more irradiations can be determined by the amount of movement between pulses, and the amount of movement is smaller than the channel length in the number of irradiations of nine times, and the amount of movement is the number of irradiations in the seventeenth irradiation. Less than channel length / 2.

1‧‧‧Mobile Station

2‧‧‧Non-single crystalline semiconductor film

3‧‧‧pulse laser

Claims (7)

A method for producing a crystalline semiconductor film in which a non-single-crystal semiconductor film is relatively scanned with a pulse beam having a short beam width of 100 to 500 μm and a beam shape having a flat portion in a beam cross-sectional direction in a short-axis direction of the beam, Further, each pulse is moved, and the non-single-crystal semiconductor film is superimposed and irradiated with the number n of irradiations, wherein the channel length of the transistor formed in the semiconductor film is b (100 μm or less); the pulsed laser has a lower value. An irradiation pulse energy density at which the crystallized particle diameter is grown by the irradiation of the pulsed laser on the non-single-crystal semiconductor film, and the crystal grain size is saturated by a plurality of irradiations; In the pulse laser irradiation of the pulse energy density E, the number of times of irradiation when the crystal grain size is saturated is n0, the number n of irradiations of the pulse laser is (n0-1) or more; and the scanning direction of the pulse laser is the above The long direction of the channel of the transistor, and the amount of movement c of each of the above pulses is smaller than b. The method for producing a crystalline semiconductor film according to claim 1, wherein the number n of irradiations of the pulsed laser is (n0-1) or more and 3. Below n0. The method for producing a crystalline semiconductor film according to the above aspect, wherein the amount of movement is less than b/2. The method for producing a crystalline semiconductor film according to any one of claims 1 to 3, wherein the amount of movement is 5 μm or more. The method for producing a crystalline semiconductor film according to any one of claims 1 to 4, wherein a ratio of a channel width to a channel length (channel width/channel length) of the transistor is 1 or less. The method for producing a crystalline semiconductor film according to any one of the preceding claims, wherein the non-single-crystalline semiconductor is germanium. The method for producing a crystalline semiconductor film according to any one of claims 1 to 6, wherein the pulsed laser is a excimer laser.