WO2014069094A1 - 半導体装置の製造方法、イオンビームエッチング装置及び制御装置 - Google Patents
半導体装置の製造方法、イオンビームエッチング装置及び制御装置 Download PDFInfo
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- WO2014069094A1 WO2014069094A1 PCT/JP2013/073597 JP2013073597W WO2014069094A1 WO 2014069094 A1 WO2014069094 A1 WO 2014069094A1 JP 2013073597 W JP2013073597 W JP 2013073597W WO 2014069094 A1 WO2014069094 A1 WO 2014069094A1
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- H05H—PLASMA TECHNIQUE; PRODUCTION OF ACCELERATED ELECTRICALLY-CHARGED PARTICLES OR OF NEUTRONS; PRODUCTION OR ACCELERATION OF NEUTRAL MOLECULAR OR ATOMIC BEAMS
- H05H1/00—Generating plasma; Handling plasma
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Definitions
- the present invention relates to a method of manufacturing a semiconductor device, an ion beam etching apparatus used for the method, and a control device.
- Metal-insulator film (oxide film) -semiconductor field effect transistor Metal-insulator (oxide) -semiconductor field effect transistor: MISFET or MOSFET
- CMOS Complementary metal-oxide-semiconductor circuits to which MOSFETs are applied are widely used as devices constituting many LSIs because they consume less power, can be easily miniaturized and highly integrated, and can operate at high speed. It is done.
- a thermal oxide film (SiO 2 ) of silicon or a film (SiON) obtained by nitriding silicon oxide in heat or plasma has been widely used as a gate insulating film of MOSFET.
- an n-type polysilicon layer doped with phosphorus (P) or arsenic (As) and a p-type polysilicon layer doped with boron (B) have been widely used as gate electrodes.
- the high dielectric film material is, for example, a compound of hafnium series, etc., among which hafnium oxide (HfO 2 ) is a promising material in that deterioration of electron mobility and hole mobility can be suppressed while having high dielectric constant. .
- hafnium oxide HfO 2
- characteristic deterioration such as carrier mobility deterioration is caused by performing a high temperature treatment process such as activation annealing treatment of source and drain.
- the gate insulating film and gate electrode are formed after high-temperature processing.
- the transistor structure formed by the former manufacturing method is referred to as a gate first structure
- the transistor structure formed by the latter manufacturing method is referred to as a gate last structure.
- Patent Document 1 discloses a CMOS circuit in which an n-channel MOSFET has a gate-first structure and a p-channel MOSFET has a gate-last structure.
- CMOS circuit first, both an n-channel MOSFET and a p-channel MOSFET are formed in a gate-first structure, then only the p-channel MOSFET is removed to deposit a conductive layer newly to form a MOSFET in a gate-last structure. doing.
- WF work Function
- a stopper film for chemical mechanical polishing is formed, and the p-channel of the gate first structure formed previously is formed.
- the gate electrode of the MOSFET and the CMP stopper film on the gate electrode are removed to form an opening, and the opening is filled with titanium nitride and aluminum. After that, the excess titanium nitride and aluminum film up to the CMP stopper film are polished and removed in a CMP process.
- CMOS circuit of Patent Document 1 by forming silicon nitride films (stress liner films) of tensile stress and compressive stress on the source and drain, stress of the channel region of the transistor is modulated, and carrier mobility is I am improving.
- Patent Document 2 after the surface of a hard substrate such as SiC is planarized by CMP treatment, the surface of the substrate is subjected to gas cluster irradiation of argon and gas cluster irradiation of nitrogen to remove polishing flaws after CMP treatment and to make the surface flat. Methods are disclosed.
- a difference in polishing amount is likely to occur in the substrate surface.
- the amount of polishing is small at the central portion in the substrate plane, and the amount of polishing is large at the outer peripheral portion in the substrate surface. That is, the film thickness in the substrate surface after polishing tends to be thicker at the center and thinner at the periphery.
- the difference in polishing amount in such a CMP process degrades the yield of manufactured semiconductor devices.
- minute polishing flaws in the substrate surface generated by CMP processing are planarized by gas cluster ion beam etching, but in such a method, the central portion of the substrate generated by CMP processing and It is not possible to eliminate the difference in polishing amount with the peripheral portion.
- the present invention has been made to solve the above-described problems, and the film thickness distribution in the substrate surface generated by CMP in the manufacturing process of the semiconductor device can be simply corrected, and a semiconductor device uniform in the substrate surface can be obtained. Intended to be provided.
- the present invention is a method of manufacturing a semiconductor device, CMP step of polishing a substrate by chemical mechanical polishing; And IBE performing an ion beam etching process on the polished substrate.
- the ion beam etching process in the IBE step is a semiconductor device characterized in that an etching rate is different between a central portion and an outer peripheral portion in the substrate surface.
- the present invention provides a plasma generation chamber, A processing chamber for processing substrates, A grid provided between the processing chamber and the plasma generation chamber for extracting ions from the plasma generation chamber and forming an ion beam; A gas introduction unit for introducing a discharge gas into the plasma generation chamber; An exhaust means for exhausting the processing chamber; A substrate holder for mounting a substrate provided in the processing chamber, the ion beam etching apparatus comprising: An ion beam etching apparatus is characterized in that the ion passing holes of the grid have different opening densities at a position facing the central portion in the substrate surface and a position facing the outer peripheral portion in the substrate surface.
- the present invention relates to a control device used for an ion beam etching apparatus,
- the measurement result of film thickness distribution in the substrate surface is input, On the basis of the measurement result, an outer coil provided on the outer periphery of the ceiling part which is outside the plasma generation chamber and faces the grid of the plasma generation chamber, and an inner coil provided on the inner periphery of the ceiling part It is a control device characterized by controlling a current value.
- the present invention by performing ion beam etching processing with distribution of etching rate after the CMP process, it becomes possible to simply correct the film thickness distribution in the substrate surface generated by the CMP. Therefore, according to the present invention, it is possible to manufacture a semiconductor device that is uniform within the substrate surface, and it is possible to improve the manufacturing yield of semiconductor devices.
- FIG. 1 shows a schematic view of an ion beam etching (IBE) apparatus according to the present embodiment.
- the IBE apparatus includes a processing chamber 101 and an ion beam generator 100 provided to irradiate an ion beam into the processing chamber 101.
- the ion beam generator 100 and the processing chamber 101 are connected, and the ion beam generated from the ion beam generator 100 is introduced into the processing chamber 101.
- a substrate holder 110 capable of holding a substrate 111 is provided in the processing chamber 101 so that the ion beam emitted from the ion beam generator 100 is incident, and the substrate 111 is electrostatically attracted (ESC: ESC ) Mounted on the electrode 112. Further, an exhaust unit 103 is installed in the processing chamber 101.
- a neutralizer (not shown) is provided in the processing chamber 101, and the neutralizer can electrically neutralize the ion beam introduced from the ion beam generator 100. Accordingly, the substrate 111 can be irradiated with the electrically neutralized ion beam, and charge-up of the substrate 111 can be prevented.
- the substrate holder 110 can be optionally tilted relative to the ion beam. Further, the substrate holder 110 has a structure capable of rotating (rotating) the substrate 111 in the in-plane direction.
- the ion beam generator 100 includes a plasma generation chamber 102.
- the plasma generation chamber 102 as a discharge chamber has a bell jar 104 as a member having a hollow portion and an opening, and the internal space 102 a which is the hollow portion is a discharge space in which a plasma discharge is generated.
- the processing chamber 101 and the plasma generation chamber 102 are connected by attaching a bell jar 104 made of, for example, quartz to the processing chamber 101 made of, for example, stainless steel. That is, the bell jar 104 is provided in the processing chamber 101 so that the opening formed in the processing chamber 101 and the opening of the bell jar 104 (opening 102 b of the plasma generation chamber 102) overlap.
- the internal space 102a communicates with the outside through the opening 102b, and the ions generated in the internal space 102a are extracted from the opening 102b.
- a gas introduction unit 105 is provided in the plasma generation chamber 102, and the etching gas is introduced into the internal space in the plasma generation chamber 102 by the gas introduction unit 105.
- an RF antenna 108 connected to the matching unit 107 for generating a radio frequency (RF) field is arranged around the plasma generation chamber 102 so as to generate a plasma discharge in the internal space.
- An electromagnetic coil 106 is provided on the ceiling of the bell jar 104 (opposite the grid 109).
- the discharge gas can be generated in the plasma generation chamber 102 by introducing a discharge gas from the gas introduction unit 105 and applying a high frequency to the RF antenna 108.
- a permanent magnet 118 is further provided on the outer periphery of the RF antenna 108.
- the processing chamber 101 and the plasma generation chamber 102 are connected, but the ion beam generator 100 is provided at the boundary between the processing chamber 101 and the plasma generation chamber 102.
- the grid 109 is further provided as an extraction means for extracting ions from the plasma generated in the inner space 102a.
- a DC voltage is applied to the grid 109, ions in the plasma generation chamber 102 are extracted as a beam, and the extracted ion beam is irradiated to the substrate 111 to process the substrate 111.
- the grid 109 is attached to the device by a fastening member (not shown) in FIG. 1, and the electrodes are connected by a connecting portion (not shown).
- the grid 109 is provided in an opening 102 b formed on the ion emission side of the plasma generation chamber 102.
- the grid 109 includes at least three electrodes, and each electrode has a large number of ion passage holes for passing ions generated in the inner space 102a.
- At least three electrodes which are components of these grids 109 are formed in the opening 102b from the inner space 102a toward the outside of the opening 102b, that is, along the traveling direction of the ion beam extracted from the grid 109.
- each of the at least three electrodes is a plate-like electrode, and among the at least three electrodes, the electrode closest to the inner space 102a functions as a member that divides the discharge space in the opening 102b, and the ion of each electrode
- the surfaces on which the passage holes are formed face each other.
- a grid refers to an electrode assembly including a plurality of electrodes, a fixing member for fixing and connecting each of the plurality of electrodes, an insulating material between the electrodes, and the like.
- the grid 109 is a connection portion between the plasma generation chamber 102 and the processing chamber 101.
- the first electrode 115 plasma side grid
- the second electrode 116 the third electrode 117 (substrate side grid) is provided.
- Each of the ion passage holes formed in the first electrode 115, each of the ion passage holes formed in the second electrode 116, and each of the ion passage holes formed in the third electrode 117 are opposed to each other.
- the electrode 115, the second electrode 116, and the third electrode 117 are arranged in a direction P from the plasma generation chamber 102 toward the processing chamber 101.
- the ion passage holes at each point of the first electrode 115 to the third electrode 117 are equal in diameter, and the respective ion passage holes are disposed in an overlapping manner.
- the electrodes are connected by a fixing member 120 and fixed to the processing apparatus.
- the first electrode 115 and the second electrode 116 are connected to a power supply (not shown), and the potential of each electrode can be controlled.
- the third electrode 117 is grounded.
- a power supply may be connected to the third electrode 117 to control the potential.
- the first electrode 115 is provided on the inner space 102 a side (most on the plasma generation chamber 102 side) at the opening 102 b of the plasma generation chamber 102 and also functions as a member that divides the inner space 102 a at the opening 102 b.
- the second electrode 116 is provided outside the internal space 102 a (on the processing chamber 101 side than the first electrode 115) along the arrangement direction P from the first electrode 115 to the third electrode 117 than the first electrode 115. ing.
- the third electrode 117 is an electrode provided outside the internal space 102 a along the arrangement direction P from the first electrode 115 with respect to the second electrode 116, and among the electrodes as components of the grid 109, It is an electrode provided on the outermost side of the plasma generation chamber 102 along the arrangement direction P, that is, an electrode provided on the treatment chamber 101 side.
- the electromagnetic coil 106 provided outside the plasma generation chamber 102 and at the ceiling of the bell jar 104 comprises an annular inner coil 106a attached to the inner peripheral portion and an annular outer coil 106b attached to the outer peripheral portion. It consists of The inner coil 106a and the outer coil 106b are each connected to a power supply (not shown), and are configured to be able to control the current value flowing to each coil independently of each other.
- the ceiling of the bell jar 104 refers to a portion of the bell jar 104 constituting the plasma generation chamber 102 facing the grid 109.
- a process related to the manufacture of a semiconductor device having a field effect transistor (FET) of a gate last structure will be described with reference to FIG.
- FET field effect transistor
- Such a process is applied to, for example, a process of manufacturing a p-channel MOSFET of a CMOS circuit disclosed in Patent Document 1.
- 201 is an n-type well
- 202 is a p-type source and p-type drain fabricated by introducing conductive impurities into the substrate at both sides of the gate electrode
- 203 is a refractory metal consisting of a NiSi film.
- a silicide film 204 is a stress liner film made of SiN for applying a predetermined stress to the substrate, 205 is an insulating film made of SiO 2 or the like, and 206 is a CMP stopper film made of SiN.
- Reference numerals 207, 208 and 209 denote sidewall insulating films, and 207 is SiN, 208 is SiO 2 , and 209 is SiN.
- the gate insulating film 210 is formed on the inner wall of the trench 200 and the CMP stopper film 206.
- the gate insulating film 210 is preferably formed of an insulating material having a dielectric constant greater than at least 8.0.
- a diffusion preventing film 211 made of TiN and a conductive film 212 made of aluminum (Al) are formed on the gate insulating film 210. These films are formed by sputtering or the like.
- the conductive film 212 copper (Cu), tungsten (W) or the like can be preferably used in addition to Al.
- the conductive film 211, the diffusion preventing film 211 and the gate insulating film 201 formed on the CMP stopper film 206 are removed by a CMP process, and the trench is made conductive.
- a gate electrode consisting of the film 212 was formed.
- the polishing rate is generally faster in the outer peripheral portion than in the central portion in the substrate surface, and a difference in film thickness occurs after polishing in the central portion and the outer peripheral portion in the substrate surface.
- the gate insulating film 210 having a film thickness distribution remains on the CMP stopper film 206. This is considered to be due to the particle diameter of the slurry used for CMP, pressurization per unit area at each point in the substrate surface, operation of the polishing pad, and the like.
- the film thickness distribution in the substrate surface affects the gate threshold voltage (Vt) of the gate electrode, which causes the variation of the element characteristics of the FET.
- the present invention corrects the film thickness distribution in the substrate surface generated in such a CMP step, particularly the film thickness distribution generated in the diameter direction of the substrate by the IBE step, and in the process of manufacturing the FET shown in FIG.
- the gate insulating film 210 is exposed in the CMP process or polished until immediately before the exposure, and then the gate insulating film 210 is etched in the IBE process.
- this IBE step by changing the etching rate in the in-plane direction of the substrate, etching can be performed while correcting the film thickness distribution of the gate insulating film 210, and the film thickness distribution can be eliminated.
- “correcting the film thickness distribution” means that the film thickness distribution of the substrate is eliminated after the IBE process. Therefore, if the film thickness distribution is eliminated, it is not necessary to remove all the films having the film thickness distribution by the IBE step, but all the films having the film thickness distribution are removed, and further the lower film It does not matter if it removes it.
- the gate insulating film 210 in the IBE step, it is sufficient to eliminate at least the film thickness distribution of the gate insulating film 210 in the IBE step, and the gate is uniform even if the gate insulating film 210 is left by the IBE step.
- the insulating film 210 may be completely removed, or a part or all of the CMP stopper film 206 may be removed.
- the IBE device is provided on the outer periphery of an outer coil 106b provided outside the plasma generation chamber 102 and on the outer periphery of the ceiling facing the grid 109 of the plasma generation chamber 102, and on the inner periphery of the ceiling
- An inner coil 106a is provided, and the current value can be independently controlled. By controlling the current value of each of these two coils, it is possible to adjust the in-plane distribution of the plasma density in the plasma generation chamber 102.
- the plasma density in the plasma generation chamber 102 is changed, the amount of ion beam extracted from the grid 109 also changes according to the plasma density at each point. That is, when the plasma density is high, the amount of ion beam extracted is large, and when the plasma density is low, the amount of ion beam extracted is small.
- the plasma density distribution is increased at a position facing the central portion in the surface of the substrate 111 in the plasma generation chamber 102, and the plasma density distribution is detected at a position facing the outer peripheral portion in the surface of the substrate 111 in the plasma generation chamber 102.
- the etching rate by the ion beam at the central portion in the surface of the substrate 111 is made larger than that at the outer peripheral portion in the surface of the substrate 111, and the film thickness distribution in the surface of the substrate 111 generated in the CMP step is corrected to perform etching.
- the current flowing through the inner coil 106a and the outer coil 106b is made the same.
- the current value of the outer coil 106b is increased relative to the inner coil 106a in order to increase the etching rate at the central portion.
- FIG. 4 shows a change in etching rate at each point of the substrate 111 when the current supplied to the inner coil 106a and the outer coil 106b is changed.
- SiO 2 was used as an etching target.
- the vertical axis in FIG. 4 represents the etching rate, and the horizontal axis represents the distance in the radial direction from the central portion of the substrate 111 with the central portion as 0.
- the numerical values shown in the lines connecting the plots indicate the values of the current flowed to the inner coil 106a and the outer coil 106b, the left side of the numerical value indicates the current flowed to the inner coil 106a, and the right side of the numerical value indicates the current flowed to the outer coil 106b. ing. As can be seen from FIG.
- the other conditions at this time are as follows. Ar gas was used as the etching gas, and the flow rate of Ar gas flowed into the plasma generation chamber 2 was set to 20 sccm.
- the voltage applied to the first electrode 115 was set to 200 V, and the current flowing to the first electrode 115 was set to 400 mA.
- the ion beam extracted from the grid 109 was set to be incident perpendicularly to the sample surface. Electrons were emitted from the neutralizer toward the substrate 111 simultaneously with the ion beam irradiation. The neutralizer generates a plasma at the hollow cathode type cathode and draws electrons by the potential difference with the anode.
- the direction of the current supplied to the inner coil 106a and the outer coil 106b will be described with reference to FIG.
- the inner coil 106 a forms a magnetic field in the direction opposite to the direction from the plasma generation chamber 102 to the substrate 111 at the center of the plasma generation chamber 102, and the outer coil in the same direction as the direction from the plasma generation chamber 102 to the substrate 111 Form.
- the permanent magnet 118 is provided so that the plasma generation chamber 102 side becomes an N pole.
- a plasma density distribution is formed in the plasma generation chamber 102, an ion beam is extracted, and the substrate 111 is irradiated.
- the film thickness distribution in the surface of the substrate 111 can be corrected by etching the film on the substrate 111 after the CMP step to a thickness of several nm to several tens of nm by this IBE step, and as a result, the substrate 111 It is possible to reduce the variation of Vt of the formed FET.
- the film thickness distribution in the substrate surface after the CMP process is corrected by adjusting the plasma density in the plasma generation chamber 102.
- the film thickness distribution in the substrate surface is corrected by making the aperture density of the ion passage holes in the grid 109 different in the surface of the grid.
- the opening density of the ion passage holes of the grid 109 is large at the position facing the central portion of the substrate 111 and small at the position facing the outer peripheral portion in the surface of the substrate 111, thereby the central portion and outer periphery in the surface of the substrate 111
- the etching rate of the part can be made different.
- the ion passage hole of the grid 109 refers to the ion passage hole of the grid 109 which is an electrode assembly including the first electrode 115, the second electrode 116 and the third electrode 117.
- the ion passage holes of the first electrode 115 and the second electrode 116 are formed at the same position and at the same position, and the ion passage holes of the third electrode 117 are formed at the same position.
- the electrode is small.
- the ion passage holes of the grid 109 are substantially defined by the ion passage holes of the third electrode 117.
- the ion passage holes of the second electrode 116 and the third electrode 117 are formed at the same position and the same diameter, and the ion passage holes of the first electrode 115 are formed at the same position, but the diameter is different from that of the other electrodes.
- the ion passage holes of the grid 109 are substantially defined by the ion passage holes of the first electrode 115.
- the aperture density of the ion passage holes refers to the ratio of the area of the ion passage holes to the electrode portion at each point of the grid 109.
- the following is an example of an example in which the opening density of the ion passage holes is larger at the central portion than at the periphery.
- the first is the case where the diameter of the ion passage holes is equal at the central portion and the outer peripheral portion, and the number of ion passage holes per unit area at the central portion and the outer peripheral portion is larger in the central portion.
- the second is the case where the number of ion passing holes per unit area is equal in the central portion and the outer peripheral portion, and in the central portion and the outer peripheral portion, the diameter of the ion passing holes is larger in the central portion.
- the third is the case where both of these conditions are provided. Since the ion passage holes are usually circular, the size of the area is indicated by the diameter, but the ion passage holes are not limited to the circle in the present invention.
- the film thickness distribution in the substrate surface after the CMP process has a certain reproducibility, it is possible to adjust the ion passage holes of the grid 109 so as to correct the film thickness distribution as in the present embodiment.
- FIG. 6 shows the first electrode 115 and the ion passage holes formed in the first electrode 115. Similar ion passage holes are formed in the second electrode 116 and the third electrode 117, and the first electrode 115 to the third electrode 117 are assembled so that the ion passage holes at each point overlap.
- the number of ion passage holes 115a is different between the central portion and the outer peripheral portion. Specifically, although the diameter of the ion passage holes 115a is the same, the interval at which the ion passage holes 115a are formed is 1.5 times the central portion in the outer peripheral portion.
- the opening density of the ion passage holes may be changed stepwise from the central portion to the outer peripheral portion of the grid 109 without being limited to the form shown in FIG.
- the film thickness distribution in the plane of the substrate 111 is corrected by changing the opening density of the ion passage holes in the grid 109 in the plane of the grid.
- the aperture density of the ion passage holes in the grid 109 is made different in the plane of the grid 109 as in the second embodiment, but in addition, a mechanism for changing the aperture density of the ion passage holes in the grid 109 is provided. It is a summary.
- FIG. 7 is a view for explaining the IBE apparatus according to the present embodiment, and the periphery of the plasma generation chamber 102 is enlarged and illustrated to explain the gist of the present embodiment, and is similar to the configuration described in the above embodiment. Some of the items are omitted.
- the fixing member 123 connects the first electrode 115 and the second electrode 116 and fixes the inner wall of the processing chamber 101.
- the support member 121 supports the third electrode 117 independently from the first electrode 115 and the second electrode 116.
- the rotation drive unit 122 is a device for rotating the third electrode 117 in a plane, and is provided on the support member 121.
- a mechanism for rotating the third electrode 117 for example, a saw groove is formed on the outer edge of the third electrode 117, and it engages with the gear of the rotational drive unit 122, and the gear is driven by the motor of the rotational drive unit 122 It is configured to be rotatable.
- the positional deviation of the ion passage holes between the first electrode 115 and the second electrode 116 is not large at the central portion but becomes larger toward the outer peripheral portion. That is, the opening density of the ion passage holes of the grid 109 is lowered toward the outer peripheral portion. Therefore, the ion beam extracted from the grid 109 also has a larger number of positions facing the central portion in the surface of the substrate 111 than the position facing the outer peripheral portion in the surface of the substrate 111, and the center is larger than the peripheral portion in the surface of the substrate 111 The etching rate is increased in parts.
- the third electrode 117 by rotating the third electrode 117 according to a desired process, it is possible to appropriately change the ratio of the etching rate between the outer peripheral portion and the central portion in the surface of the substrate 111. Moreover, more uniform processing becomes possible by control based on the film thickness measurement result after the CMP process described later.
- the third electrode 117 is desirable as the electrode to be rotated from the viewpoint of film thickness distribution in the surface of the substrate 111 after the IBE step and ion beam characteristics, but the substrate can also be rotated by rotating the first electrode 115 and the second electrode 116. It is possible to correct the film thickness distribution in the 111 plane.
- the gist of the present invention is to correct the film thickness distribution in the surface of the substrate 111 present after the CMP process by the IBE process, but the IBE has different etching rates depending on the target substance.
- the SiO 2 The film made of a Si-based compound such as the gate insulating film 210 and the CMP stopper film 206 made of SiN has a larger etching rate than the diffusion preventing film 211 made of a Ti-based compound such as TiN.
- the diffusion preventing film 211 in the trench (200 in FIG. 3A) may protrude beyond the gate insulating film 210 and the CMP stopper film 206 after the IBE process.
- a conductive protrusion forms a cap film made of, for example, SiN thereafter and forms a contact plug to the high melting point metal silicide film, the positional deviation of the contact plug formation point occurs. This can cause problems such as contact with adjacent contact plugs.
- FIG. 8 shows the relationship between the ion beam incident angle and the etching rate in the IBE process of each material.
- the incident angle when the ion beam is incident in the vertical direction to the material to be etched is 0 degree.
- SiO 2 is about 145 ⁇ / min at an incident angle of 45 °
- TiN is about 60 ⁇ / min.
- SiO 2 which is the gate insulating film 210 is easily scraped.
- the IBE step in addition to the film thickness distribution within the surface of the substrate 111 generated in the CMP step, it is desirable to make the ion beam incident on the substrate 111 with a certain degree of inclination to correct the surface roughness.
- the angle is 45 degrees or more which is preferable for planarization, the difference between the etching rates of SiO 2 and TiN also becomes large.
- the inert gas is introduced into the plasma generation chamber 102 and discharged to extract ions of the inert gas.
- a chlorine (Cl 2 ) -containing gas is introduced into the plasma generation chamber 102 in addition to the inert gas.
- SiO 2 and TiN for who TiN is higher reactivity with Cl 2 gas, an ion beam containing chlorine ions using a mixed gas of an inert gas and Cl 2 gas by irradiating the substrate 111 The etching rate of TiN can be improved, and the protrusion of the diffusion preventing film 211 in the trench can be prevented.
- the IBE step may be performed using a mixed gas of Ar and O 2 or a mixed gas of Ar and N 2 .
- a control device 301 for operating the IBE device according to the present invention includes a main control unit (not shown) and a storage device (not shown), and stores control programs for executing various substrate processing processes according to the present invention.
- the control program is implemented as a mask ROM.
- the control program can be installed in a storage device configured by a hard disk drive (HDD) or the like via an external recording medium or a network.
- HDD hard disk drive
- the main control unit of the controller 301 includes power supplies 302 and 303 connected to the inner coil 106a and the outer coil 106b, a power supply 304 for applying discharge power, and a power supply 305 connected to the first electrode 115 and the second electrode 116. And 306, the substrate holder 110, the exhaust means, the drive mechanisms 307, 308, and 309 of the gas introduction system, the gate valve 310, and the like.
- the hard mask 213 is inserted under the CMP stopper film 206 as shown in FIG. 10 (a).
- the diffusion preventing film made of TiN formed in the trench The etching rate by the ion beam is largely different between 211 and the gate insulating film 210 made of Si compound outside the substrate, specifically SiO 2, and the CMP stopper film 206 made of SiN, and the diffusion preventing film 211 protrudes after the IBE step. There is a fear.
- the hard mask 213 made of a material having a smaller etching rate than the Ti-based compound is provided in the lower layer of the CMP stopper film 206.
- the hard mask 213 is made of, for example, Al 2 O 3 or a carbon film, and a material whose etching rate at the time of ion beam irradiation is smaller than that of the Ti-based compound is used.
- the diffusion preventing film 211 made of TiN left in the trench is selectively etched.
- FIG. 10B the protrusion beyond the gate insulating film 210 and the insulating film 205 in the adjacent trenches is prevented. Therefore, even when the cap film 214 made of SiN is formed, as shown in FIG. 10C, a flat surface is obtained without the diffusion preventing film 211 protruding, and between the adjacent contact plugs described above. Problems such as contact are avoided.
- the hard mask 213 is preferably made of an insulating material in order to obtain insulation between contact plugs, but it is made of a conductive film such as a carbon film, and is removed during or after film thickness distribution correction in the IBE process. You may do so.
- the IBE step may be performed using a mixed gas of Ar and O 2 or a mixed gas of Ar and N 2 .
- the present embodiment is characterized in that the film thickness distribution in the substrate surface is measured after the CMP process, and the strength of the film thickness distribution correction in the subsequent IBE process is adjusted. That is, in the present embodiment, the film thickness distribution of the gate insulating film 210 is measured after the CMP process in the first embodiment, the third embodiment or the fourth embodiment, and the IBE is measured according to the measurement result. It is characterized by controlling a process.
- the film thickness measurement after the CMP process is performed by using the optical measurement apparatus shown in FIG. 11 for the film thickness of the gate insulating film 210.
- the film thickness measurement apparatus is configured of a detection optical system 400, an optical system moving unit 500, a stage unit 600, and a film thickness measurement processing unit (not shown).
- the stage unit 600 includes a rotary stage 601 on which the substrate 604 is mounted, a photoelectric sensor 602 for detecting the passage of a specific position of the rotary stage 601, and a drive motor 603 for rotating the rotary stage 601.
- the detection optical system 400 for detecting the spectral waveform of the surface of the substrate 604 after the CMP process includes an objective lens 401, a half mirror 402, an imaging lens 403, a relay lens 404, a spatial filter 405, a field stop 406, an illumination light source 407, and a spectroscope 408. It consists of
- the illumination light source 407 is a white illumination light source such as a xenon lamp or a halogen lamp, and irradiates white illumination light onto the substrate 604 through the half mirror 402 and the objective lens 401. Reflected light from the substrate 604 is guided to the spectroscope 408 through the objective lens 401, the half mirror 402, the imaging lens 403, the relay lens 404, the spatial filter 405, and the field stop 406.
- a white illumination light source such as a xenon lamp or a halogen lamp
- the spectral waveform separated by the spectroscope 408 is input as an electrical signal to a film thickness measurement processing unit (not shown), and the film thickness is calculated to obtain the film thickness distribution in the surface of the substrate 604.
- the optical system moving unit 500 includes an optical system moving guide 501 and a drive motor 502, and detects the spectral waveform of the entire surface of the substrate 604 by moving the detection optical system 400 in the radial direction of the rotary stage 601.
- the frequency / phase analysis processing unit in the film thickness measurement processing unit converts the horizontal axis of the waveform corrected spectral waveform into the reciprocal of the wavelength, and performs frequency / phase analysis of the spectral waveform.
- the film thickness is calculated based on the analysis result.
- the film thickness distribution in the substrate surface after the CMP process is determined by the film thickness measurement apparatus described above, the measurement result is input to the control device 301 of FIG. 9, and the IBE process is controlled according to the measurement result. It becomes possible to correct the film thickness distribution in the substrate surface accurately.
- Examples of parameters in the IBE step of performing control according to the measurement result include the following embodiments.
- the voltage applied to each electrode constituting the grid 109 may be controlled.
- the film thickness distribution in the substrate surface after the CMP process is a case where the film thickness in the central portion in the substrate surface is thicker than the outer peripheral portion.
- the present invention is not limited to this, and is applicable to the case where the film thickness at the central portion in the substrate plane is thinner than the outer peripheral portion.
- the pad pressure at the central portion may be increased and polishing may be performed, or the entire substrate may be polished after only the central portion is polished in advance.
- the IBE process is performed so that the etching rate at the outer peripheral portion in the surface of the substrate 111 is higher than the central portion in the surface of the substrate 111.
- this can be achieved by setting the plasma density in the plasma generation chamber 102 at a position facing the outer peripheral portion in the surface of the substrate 111 to be larger than the position facing the central portion in the surface of the substrate 111. It is.
- the opening density of the ion passage holes of the grid 109 at a position facing the outer peripheral portion in the surface of the substrate 111 can be achieved by making the opening density of the ion passage holes larger than the position facing the central portion in the surface is there.
- the embodiment of the present invention has been described by taking the case where the film thickness distribution is generated in the gate insulating film by the CMP process in the manufacture of the FET of the gate last structure as an example, but the present invention is limited to the embodiment However, as long as the film thickness distribution is generated by the CMP process, the present invention is preferably applied to any semiconductor device manufacturing method.
- ion beam generator 101 processing chamber 102: plasma generation chamber 102a: internal space of plasma generation chamber 102b: opening of plasma generation chamber 103: exhaust means 104: bell jar 105: gas introduction part 106: electromagnetic coil 106a: inner coil 106b: outer coil 107: matching device 108: RF antenna 109: grid 110: substrate holder 111: substrate 112: ESC electrode 115: first electrode 115a: ion passage hole 116: second electrode 117: third electrode 118: permanent magnet 120: Fixing member 121: Support member 122: Rotational drive unit 123: Fixing member 200: Trench 201: n-type well 202: p-type source region or p-type drain region 203: refractory metal silicide film 204: stress liner film 205: Insulating film 206: CM Stopper film 207: SiN film 208: SiO 2 film 209: SiN film 210: gate insulating film 211: a diffusion preventing film 212: conductive
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Abstract
Description
基板を化学的機械研磨により研磨するCMP工程と、
研磨された前記基板に対してイオンビームエッチング処理を行うIBE工程と、を有し、
前記IBE工程における前記イオンビームエッチング処理は、前記基板面内の中心部と外周部とでエッチングレートが異なることを特徴とする半導体装置である。
基板を処理する処理室と、
前記処理室と前記プラズマ発生室との間に設けられ、前記プラズマ発生室からイオンを引き出しイオンビームを形成するためのグリッドと、
前記プラズマ発生室に放電用ガスを導入するためのガス導入部と、
前記処理室内を排気するための排気手段と、
前記処理室内に設けられた基板を載置するための基板ホルダと、を備えたイオンビームエッチング装置であって、
前記グリッドのイオン通過孔は、前記基板面内の中心部に対向する位置と、前記基板面内の外周部に対向する位置とで開口密度が異なることを特徴とするイオンビームエッチング装置である。
基板面内の膜厚分布の測定結果が入力され、
該測定結果に基づき、プラズマ発生室の外部であり前記プラズマ発生室のグリッドと対向する天井部の外周に設けられた外側コイルと、前記天井部の内周に設けられた内側コイルとの各々の電流値を制御することを特徴とする制御装置である。
図1に本実施形態に係るイオンビームエッチング(IBE)装置の概略図を示す。IBE装置は、処理室101と、該処理室101内にイオンビームを照射するように設けられたイオンビーム発生装置100とを備える。イオンビーム発生装置100と処理室101とは連結されており、イオンビーム発生装置100から発生されたイオンビームは処理室101内に導入される。
第1の実施形態では、CMP工程後の基板面内の膜厚分布をプラズマ発生室102内のプラズマ密度を調整することで補正した。これに対して本実施形態では、グリッド109におけるイオン通過孔の開口密度をグリッドの面内で異ならせることで基板面内の膜厚分布の補正を行う。
上述した第2の実施形態では、グリッド109におけるイオン通過孔の開口密度をグリッドの面内で変化させることで基板111面内の膜厚分布の補正を行った。本実施形態も第2実施形態と同様にグリッド109におけるイオン通過孔の開口密度をグリッド109の面内で異ならせるが、加えてグリッド109におけるイオン通過孔の開口密度を変化させる機構を備えることを要旨とする。
本発明の要旨はCMP工程後に存在する基板111面内の膜厚分布をIBE工程により補正することであるが、IBEは対象とする物質によってエッチングレートが異なる。上述したとおり、図3に示したFETの製造プロセスにおいては、CMP工程によりゲート絶縁膜210が露出するまで加工した後にIBE工程を行ってゲート絶縁膜210をエッチングするが、この時、SiO2からなるゲート絶縁膜210やSiNからなるCMPストッパ膜206といった構成材料がSi系化合物からなる膜は、TiNなどのTi系化合物からなる拡散防止膜211よりもエッチングレートが大きい。そのため、IBE工程後にトレンチ(図3(a)中の200)内の拡散防止膜211がゲート絶縁膜210やCMPストッパ膜206よりも突出する恐れがある。このような導電性の突起部は、その後に例えばSiNからなるキャップ膜を成膜し、高融点金属シリサイド膜へのコンタクトプラグを形成する際に、コンタクトプラグ形成ポイントの位置ズレが生じた際の隣接するコンタクトプラグとの接触等の問題を引き起こす可能性がある。
本実施形態について図10を用いて説明する。本実施形態では、図3に示したFETの製造プロセスにおいて、図10(a)に示すようにCMPストッパ膜206の下にハードマスク213が挿入されている。
本実施形態では、CMP工程後に基板面内の膜厚分布を測定し、その後のIBE工程における膜厚分布補正の強度を調整することを特徴とする。即ち、本実施形態は、第1の実施形態、第3の実施形態もしくは第4の実施形態において、CMP工程後にゲート絶縁膜210の膜厚分布の測定を行い、その測定結果に応じて、IBE工程を制御することを特徴とする。
101:処理室
102:プラズマ発生室
102a:プラズマ発生室の内部空間
102b:プラズマ発生室の開口
103:排気手段
104:ベルジャ
105:ガス導入部
106:電磁コイル
106a:内側コイル
106b:外側コイル
107:整合器
108:RFアンテナ
109:グリッド
110:基板ホルダ
111:基板
112:ESC電極
115:第1電極
115a:イオン通過孔
116:第2電極
117:第3電極
118:永久磁石
120:固定部材
121:支持部材
122:回転駆動部
123:固定部材
200:トレンチ
201:n型ウェル
202:p型ソース領域又はp型ドレイン領域
203:高融点金属シリサイド膜
204:ストレスライナー膜
205:絶縁膜
206:CMPストッパ膜
207:SiN膜
208:SiO2膜
209:SiN膜
210:ゲート絶縁膜
211:拡散防止膜
212:導電膜
213:ハードマスク
214:キャップ膜
301:制御装置
302:外側コイル接続電源
303:内側コイル接続電源
304:放電用電源
305:第1電極接続電源
306:第2電極接続電源
307:基板ホルダ駆動機構
308:排気手段
309:ガス導入系
310:ゲートバルブ
400:検出光学系
401:対物レンズ
402:ハーフミラー
403:結像レンズ
404:リレーレンズ
405:空間フィルタ
406:視野絞り
407:照明光源
408:分光器
500:光学系移動部
501:光学系移動ガイド
502:駆動モータ
600:ステージ部
601:回転ステージ
602:光電センサ
603:駆動モータ
604:基板
Claims (20)
- 半導体装置の製造方法であって、
基板を化学的機械研磨により研磨するCMP工程と、
研磨された前記基板に対してイオンビームエッチング処理を行うIBE工程と、を有し、
前記IBE工程における前記イオンビームエッチング処理は、前記基板面内の中心部と外周部とでエッチングレートが異なることを特徴とする半導体装置の製造方法。 - 前記イオンビームのイオンが引き出されるプラズマ発生室内のプラズマ密度が、前記プラズマ発生室内において前記基板面内の中心部に対向する位置よりも、外周部に対向する位置において小さいことを特徴とする請求項1に記載の半導体装置の製造方法。
- 前記プラズマ発生室はイオンビームが引き出される側と対向する側に複数の環状の電磁コイルを備え、前記複数の電磁コイルは各々が独立して電流を制御可能であり、前記複数の電磁コイルの電流を制御することで前記プラズマ発生室内のプラズマ密度を、前記基板面内の中心部に対向する位置よりも、外周部に対向する位置において小さくすることを特徴とする請求項2に記載の半導体装置の製造方法。
- 前記CMP工程と前記IBE工程との間に、前記基板の膜厚分布を測定する測定工程を有し、
前記IBE工程において、前記複数の電磁コイルに流れる電流値を、前記測定工程において求めた測定結果に応じて制御することを特徴とする請求項3に記載の半導体装置の製造方法。 - 前記基板に対して照射されるイオンビームを引き出すためのグリッドに形成された複数のイオン通過孔の単位面積当たりの開口密度が、前記基板面内の中心部に対向する位置よりも、外周部に対向する位置において小さいことを特徴とする請求項1に記載の半導体装置の製造方法。
- 前記イオン通過孔の単位面積当たりの個数が、前記基板面内の中心部に対向する位置よりも、外周部に対向する位置において少ないことを特徴とする請求項5に記載の半導体装置の製造方法。
- 前記グリッドは複数の電極板から構成され、前記複数の電極板に互いに重なり合う複数のイオン通過孔が設けられており、
前記複数の電極板の少なくとも1枚が、他の電極板とイオン通過孔が対向する位置から該電極板の面内方向に回転した位置に在り、重なり合ったイオン通過孔の単位面積当たりの開口密度が、前記基板面内の中心部に対向する位置よりも、外周部に対向する位置において小さいことを特徴とする請求項5に記載の半導体装置の製造方法。 - 前記CMP工程と前記IBE工程との間に、前記基板の膜厚分布を測定する測定工程を有し、
前記測定結果に応じて前記回転駆動部による前記電極板の回転量を制御することを特徴とする請求項7に記載の半導体装置の製造方法。 - 回転させる電極板は、前記複数の電極板のうち、最も前記基板側に近い電極であることを特徴とする請求項7に記載の半導体装置の製造方法。
- 前記イオンビームのイオンが引き出されるプラズマ発生室内のプラズマ密度が、前記プラズマ発生室内において、前記基板面内の中心部に対向する位置よりも外周部に対向する位置において大きいことを特徴とする請求項1に記載の半導体装置の製造方法。
- 前記プラズマ発生室はイオンビームが引き出される側と対向する側に複数の環状の電磁コイルを備え、前記複数の電磁コイルは各々が独立して電流を制御可能であり、前記複数の電磁コイルの電流を制御することで、前記プラズマ発生室内のプラズマ密度を、前記基板面内の中心部に対向する位置よりも外周部に対向する位置において大きくすることを特徴とする請求項10に記載の半導体装置の製造方法。
- 前記研磨工程と前記IBE工程との間に、前記基板の膜厚分布を測定する測定工程を有し、
前記IBE工程において、前記複数の電磁コイルに流れる電流値を、前記測定工程において求めた測定結果に応じて制御することを特徴とする請求項11に記載の半導体装置の製造方法。 - 前記基板に対して照射されるイオンビームを引き出すためのグリッドに形成されたイオン通過孔の単位面積当たりの開口密度が、前記基板面内の中心部に対向する位置よりも、外周部に対向する位置において大きいことを特徴とする請求項1に記載の半導体装置の製造方法。
- 前記IBE工程においてエッチングされる膜が、シリコン系化合物からなる膜とチタン系化合物からなる膜であり、
前記IBE工程において用いられる放電用ガスは不活性ガスと塩素含有ガスの混合ガスであることを特徴とする請求項1乃至13のいずれか1項に記載の半導体装置の製造方法。 - 前記IBE工程においてエッチングされる膜が、シリコン系化合物からなる膜とチタン系化合物からなる膜とであり、
前記シリコン系化合物からなる膜の下層に、前記チタン系化合物よりもエッチングレートの小さい材料からなるハードマスクが形成されていることを特徴とする請求項1乃至13のいずれか1項に記載の半導体装置の製造方法。 - プラズマ発生室と、
基板を処理する処理室と、
前記処理室と前記プラズマ発生室との間に設けられ、前記プラズマ発生室からイオンを引き出しイオンビームを形成するためのグリッドと、
前記プラズマ発生室に放電用ガスを導入するためのガス導入部と、
前記処理室内を排気するための排気手段と、
前記処理室内に設けられた基板を載置するための基板ホルダと、を備えたイオンビームエッチング装置であって、
前記グリッドのイオン通過孔は、前記基板面内の中心部に対向する位置と、前記基板面内の外周部に対向する位置とで開口密度が異なることを特徴とするイオンビームエッチング装置。 - 前記グリッドのイオン通過孔は、前記基板面内の中心部に対向する位置の開口密度が、前記基板面内の外周部に対向する位置の開口密度よりも大きいことを特徴とする請求項16に記載のイオンビームエッチング装置。
- 前記グリッドのイオン通過孔は、前記基板面内の中心部に対向する位置の開口密度が、前記基板面内の外周部に対向する位置の開口密度よりも小さいことを特徴とする請求項16に記載のイオンビームエッチング装置。
- 前記プラズマ発生室の外部であって、前記プラズマ発生室の前記グリッドと対向する天井部に設けられた電磁コイルと、
前記基板の処理が行われる前の面内膜厚分布の測定結果が入力される制御部と、を備え、
前記電磁コイルは前記天井部の外周に設けられた外側コイルと、前記天井部の内周に設けられた内側コイルとを有し、前記外側コイル及び前記内側コイルは互いに独立して電流値が制御可能であり、
前記制御部は、前記制御部に入力された前記測定結果に応じて前記外側コイル及び前記内側コイルに流す電流を制御することを特徴とする請求項16に記載のイオンビームエッチング装置。 - イオンビームエッチング装置に用いられる制御装置であって、
基板の面内膜厚分布の測定結果が入力され、
該測定結果に基づき、プラズマ発生室の外部であり前記プラズマ発生室のグリッドと対向する天井部の外周に設けられた外側コイルと、前記天井部の内周に設けられた内側コイルとの各々の電流値を制御することを特徴とする制御装置。
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US20150318185A1 (en) | 2015-11-05 |
US20170316918A1 (en) | 2017-11-02 |
US10026591B2 (en) | 2018-07-17 |
JP6371884B2 (ja) | 2018-08-08 |
TW201436031A (zh) | 2014-09-16 |
JPWO2014069094A1 (ja) | 2016-09-08 |
TWI506693B (zh) | 2015-11-01 |
KR101742556B1 (ko) | 2017-06-01 |
KR20150053777A (ko) | 2015-05-18 |
KR101661638B1 (ko) | 2016-09-30 |
US9734989B2 (en) | 2017-08-15 |
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