美国专利US20010003670A1 Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and prod

专利PDF首页>>美国专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
A method for depositing a rough polysilicon film on a substrate is disclosed. The method includes introducing the reactant gases argon and silane into a deposition chamber and enabling and disabling a plasma at various times during the deposition process.
公开号:US20010003670A1
申请号:US09/732,624
申请日:2000-12-08
公开日:2001-06-14
发明作者:Gurtej Sandhu；Trung Doan
申请人:Sandhu Gurtej S.；Doan Trung T.；
IPC主号:H01L28-82

专利说明:
[0001] 1. Field of the Invention [0001]
[0002] This invention relates generally to the field of integrated circuit manufacturing and, more particularly, to a method for forming a rough polysilicon film. [0002]
[0003] 2. Description of the Related Art [0003]
[0004] In semiconductor manufacturing, it is sometimes desirable to deposit polysilicon film on a substrate in such a way that rough polysilicon results. In dynamic random access memory (DRAM) technologies, for instance, it may be desirable to manufacture a memory cell capacitor using rough polysilicon. [0004]
[0005] A capacitor having a given lateral area manufactured with a rough polysilicon plate will have a higher capacitance than a capacitor of having the same lateral area manufactured with a smooth plate. The rough polysilicon capacitor has a larger effective dielectric surface area due to the folding of the capacitor dielectric over the rough film. When used in a DRAM memory cell, the larger dielectric surface area increases the memory cell's capacitance and improves the cell's charge storage characteristics, thereby improving product performance. [0005]
[0006] Unfortunately, the use of traditional manufacturing methods to produce rough polysilicon have been generally unsatisfactory because of the widely varying roughness they produce. The instant process results in a more reliable rough polysilicon film that is more easily controlled. Moreover, because the instant process uses etchants and techniques common to the semiconductor industry, this improved process can be readily integrated into modern day manufacturing flows. [0006] SUMMARY OF THE INVENTION
[0007] In accordance with one aspect of the present invention, there is provided a method for depositing a rough polysilicon film on a substrate. The method includes the steps of introducing reactant gas into a deposition chamber containing the substrate, and enabling and disabling a plasma within the deposition chamber. [0007]
[0008] In accordance with another aspect of the present invention, there is provided a method for manufacturing a capacitor having a plate formed of rough polysilicon. The plate is formed by introducing reactant gas into a deposition chamber containing the substrate and selectively and repeatedly enabling and disabling a plasma to deposit the rough polysilicon on the substrate. A dielectric layer is formed on the rough polysilicon, and a conductive plate is formed on the dielectric layer. [0008]
[0009] In accordance with a further aspect of the present invention, there is provided a capacitor that includes a polysilicon plate formed by introducing reactant gases into a deposition chamber and selectively and repeatedly enabling and disabling a plasma at various times during the deposition process. A dielectric film is disposed on the polysilicon plate, and a top plate is disposed on the dielectric film. [0009]
[0010] In accordance with yet another aspect of the present invention, there is provided a memory circuit that includes a plurality of memory cells. Each of the memory cells has a capacitor. Each capacitor has a plate of rough polysilicon formed by introducing reactant gas into a deposition chamber and selectively and repeatedly enabling and disabling a plasma at various times during the deposition process. [0010]
[0011] In accordance with a still further aspect of the present invention, there is provided a method for depositing a rough polysilicon film on a substrate. The method includes the steps of: (a) placing a substrate in a deposition chamber; (b)introducing reactant gas into said deposition chamber; (c) creating a plasma; (d) disabling said plasma; (e) pumping a portion of reactive by-products out of said deposition chamber; and (f) repeating steps (c), (d), and (e) until a roughened polysilicon film has been deposited on said substrate. [0011] BRIEF DESCRIPTION OF THE DRAWINGS
[0012] The foregoing and other advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings in which: [0012]
[0013] FIG. 1A is a cross-section of a bottom plate of a capacitor comprised of rough polysilicon. [0013]
[0014] FIG. 1B shows the addition of a capacitor dielectric over the rough polysilicon film. [0014]
[0015] FIG. 1C shows the addition of a top plate of a capacitor over the capacitor dielectric. [0015]
[0016] FIG. 2 is a stylized representation of a polysilicon deposition chamber. [0016]
[0017] While the invention is susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and will be described in detail herein. However, it should be understood that the invention is not intended to be limited to the particular forms disclosed. Rather, the invention is to cover all modifications, equivalents and alternatives falling within the spirit and scope of the invention as defined by the appended claims. [0017] DESCRIPTION OF SPECIFIC EMBODIMENTS
[0018] Turning now to the drawings, the formation of a capacitor, generally designated by a reference numeral [0018] 10, using a rough polysilicon is shown in cross-section in FIGS. 1A through 1C. In FIG. 1A, a rough polysilicon film 12 is formed over a substrate 14. The rough polysilicon film 12 constitutes the bottom plate of the capacitor 10. In FIG. 1B, a dielectric 16 is grown or deposited on top of the rough polysilicon film 2. In FIG. 1C, a layer of conductive material 16 (e.g., polysilicon) is deposited over the dielectric 16. The conductive material 18 constitutes the top plate of the capacitor 10. In one embodiment, pulsed plasma chemical vapor deposition (CVD), using a mixture of silane gas (SiH₄) and argon (Ar), is used to deposit the rough polysilicon film 12 on the underlying substrate 14.
[0019] A stylized representation of a deposition chamber [0019] 20, which can be used to practice the disclosed process, is shown in FIG. 2. The substrate 14 is shown positioned in the deposition chamber 20 atop a wafer chuck 22. A heating element 24 runs through the wafer chuck 22. The temperature of the heating element 24 may be varied by a temperature controller 26. An RF power source 20 sends an oscillating voltage at a controlled frequency to a plate 30 placed above the wafer chuck 22. The plate 30 is usually grounded to create a radio-frequency (RF) controlled plasma. The voltage that builds up between the plate 30 and the wafer chuck 22 creates an electric field inside of the deposition chamber 20. When this happens, gases that have been introduced into the chamber via a port 32 and a port 34 can become ionized so that the reactants are deposited onto the substrate 14. This is commonly referred to as “striking” or “enabling” a plasma.
[0020] More than just two gases can be introduced into the deposition chamber [0020] 20 at one time if the reaction chemistry so dictates, as one of ordinary skill will realize. A suitable deposition chamber 20 for practicing the disclosed embodiment is an Applied Materials™ model 5000D deposition chamber. This model is advantageous because it contains plasma generation capabilities. Other more standard CVD chambers, such as the Applied Materials™ Centura™ model 5200 or the AG Associates™ model 8000, may also be used if modified to generate a sufficient electric field to enable a plasma.
[0021] In the disclosed embodiment, the plasma is “pulsed,” meaning that the plasma is selectively enabled and disabled at various times during deposition. Pulsing of the plasma can be achieved by several means. One such method involves connecting a pulse generator [0021] 36 to the RF power source 28, as shown schematically in FIG. 2. The pulse generator 36 sends a square wave to the RF power source 28. The square wave is connected to the RF power source 28 in such a manner that the RF power source 28 is enabled during the high portions of the square wave 28 and is disabled during the low portions of the square wave. When the RF power source 28 is enabled, it sends an oscillating voltage to the plate 30 as described above, thus facilitating formation of plasma in the deposition chamber 20. When the RF power source 28 is disabled, the oscillating voltage is not sent to the plate 30. Thus, no plasma is formed during that period. It is also possible that the RF power source 28 can be enabled and disabled by the use of a computer or by the use of another appropriate switch.
[0022] For sufficient production of a rough polysilicon film, the RF power source [0022] 28, in this embodiment, is capable of producing a power in the range of 10 to 1,000 Watts and oscillates (when enabled) with a frequency of 400,000 to 15,000,000 Hertz (Hz), with 13,600,000 Hz being typical. The pulse generator 36 is capable of producing a square wave with a frequency of 25 to 1,000 Hz. The duty cycle, i.e., the percentage of the time that the square wave is high, may vary between 10% and 90%. Assuming a six-liter volume for deposition chamber 20, the following other deposition parameters are suitable for the production of a rough polysilicon film: deposition temperature of 300 to 600 degrees Centigrade; silane gas flow rate of 5 to 500 cubic centimeters per minute; argon gas flow rate of 10 to 1000 cubic centimeters per minute; and deposition chamber pressure of 0.1 to 100 Torr.
[0023] The pulsing of the plasma has distinct advantages. First, pulsing the plasma allows for stringent control of the plasma chemistry. During the disabled portion of the plasma cycle, the reactive by-products are pumped out of the deposition chamber [0023] 20 by the pump 40, and the reaction is started anew on the next enabled cycle. If the plasma is not pulsed, the silane ions produced in the plasma will combine to form silicon which, when situated on the wafer surface, may produce a smooth film.
[0024] Another advantage of pulsing the plasma is that gas phase nucleation is generally not conducive to precise control, because nucleation size and density vary as a function of deposition time in an active plasma. By keeping the enabled time relatively short, these effects, which tend to cause the polysilicon film to grow in a random and unrepeatable fashion, are reduced. With a pulsed plasma, a constant desired concentration of reactive silane can be maintained because during the disabled state, the silane ions become neutral through recombination. [0024]
[0025] The disclosed process has other advantages as well. First, because the mean free path of the reactive species is kept to a maximum by curtailing the duration of the “enabled” portion, better polysilicon step coverage can result. This makes the disclosed process beneficial for depositing a rough polysilicon film on a three-dimensional surface, such as a contact hole, a trench, or a stack for a DRAM capacitor. In addition, rough polysilicon films using the disclosed technique can be deposited at relatively low temperatures, such as 500 degrees Centigrade. Deposition at low temperatures is beneficial because the growth of the polysilicon film on the surface of the wafer will not be dictated by the thermal mobility of the silicon atoms which dissociate from the silane ions at the wafer surface. By the use of lower deposition temperatures, a rough polysilicon film can be achieved that is largely independent of temperature. By contrast, conventional non-pulsed CVD rough polysilicon films cannot typically be deposited at such low temperatures, because the resulting film will be amorphous and, therefore, smooth. [0025]
[0026] The use of the disclosed method produces a film in which the vertical “peak-to-valley” roughness of the polysilicon film is approximately 500 Angstroms, and the lateral “peak-to-valley” roughness of the polysilicon film is approximately 500 Angstroms. However, the resulting film is a function of the various processing conditions that are discussed herein, and the process is susceptible to optimization before a film of a suitable rugosity is realized for a given application. [0026]

权利要求:
Claims (15)
[1" id="US-20010003670-A1-CLM-00001] 1. A method for depositing a rough polysilicon film on a substrate, said method comprising the steps of:
(a) introducing reactant gas into a deposition chamber containing said substrate; and
(b) enabling and disabling a plasma within the deposition chamber.
[2" id="US-20010003670-A1-CLM-00002] 2. The method of
claim 1 , wherein step (a) comprises the step of introducing argon and silane into said deposition chamber.
[3" id="US-20010003670-A1-CLM-00003] 3. The method of
claim 1 , wherein step (b) is performed at a temperature below 500 degrees Centigrade.
[4" id="US-20010003670-A1-CLM-00004] 4. The method of
claim 1 , wherein step (b) comprises the step of selectively enabling and disabling said plasma using a function generator.
[5" id="US-20010003670-A1-CLM-00005] 5. A method for manufacturing a capacitor having a plate formed of rough polysilicon, said method comprising the steps of:
(a) forming the plate by introducing reactant gas into a deposition chamber containing said substrate and selectively and repeatedly enabling and disabling a plasma to deposit said rough polysilicon on said substrate;
(b) forming a dielectric layer on said rough polysilicon; and
(c) forming a conductive plate on said dielectric layer.
[6" id="US-20010003670-A1-CLM-00006] 6. The method of
claim 5 , wherein step (a) comprises the step of introducing argon and silane into said deposition chamber.
[7" id="US-20010003670-A1-CLM-00007] 7. The method of
claim 5 , wherein step (b) is performed at a temperature below 500 degrees Centigrade.
[8" id="US-20010003670-A1-CLM-00008] 8. The method of
claim 5 , wherein step (b) comprises the step of selectively enabling and disabling said plasma using a function generator.
[9" id="US-20010003670-A1-CLM-00009] 9. A capacitor, comprising:
(a) a bottom polysilicon plate which is formed by introducing reactant gases into a deposition chamber and selectively and repeatedly enabling and disabling a plasma at various times during the deposition process;
(b) a dielectric film disposed on the bottom polysilicon plate; and
(c) a top plate disposed on the dielectric film.
[10" id="US-20010003670-A1-CLM-00010] 10. The capacitor of
claim 9 , wherein the introduction of reactant gases includes the introduction of argon and silane.
[11" id="US-20010003670-A1-CLM-00011] 11. The capacitor of
claim 9 , wherein the bottom polysilicon plate is formed at a temperature below 500 degrees Centigrade.
[12" id="US-20010003670-A1-CLM-00012] 12. The capacitor of
claim 9 , wherein the selective and repeated enabling and disabling of the plasma is accomplished by a function generator.
[13" id="US-20010003670-A1-CLM-00013] 13. A memory circuit comprising:
a plurality of memory cells, each of said plurality of memory cells having a capacitor, each capacitor having a plate of rough polysilicon formed by introducing reactant gas into a deposition chamber and selectively and repeatedly enabling and disabling a plasma at various times during the deposition process.
[14" id="US-20010003670-A1-CLM-00014] 14. The memory circuit of
claim 13 , wherein the majority of plates of rough polysilicon have a vertical roughness of about 500 Angstroms and a lateral roughness of about 500 Angstroms.
[15" id="US-20010003670-A1-CLM-00015] 15. A method for depositing a rough polysilicon film a substrate, said method comprising the steps of:
(a) placing a substrate in a deposition chamber;
(b) introducing reactant gas into said deposition chamber;
(c) creating a plasma;
(d) disabling said plasma;
(e) pumping a portion of reactive by-products out of said deposition chamber; and
(f) repeating steps (c), (d), and (e) until a roughened polysilicon film has been deposited on said substrate.

类似技术:

公开号 | 公开日 | 专利标题

US7220670B2|2007-05-22|Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and products produced by same

US5320880A|1994-06-14|Method of providing a silicon film having a roughened outer surface

US6489199B2|2002-12-03|Multiple step methods for forming conformal layers

US7378129B2|2008-05-27|Atomic layer deposition methods of forming conductive metal nitride comprising layers

KR930011413B1|1993-12-06|Plasma cvd method for using pulsed waveform

US7484513B2|2009-02-03|Method of forming titanium film by CVD

US20010028922A1|2001-10-11|High throughput ILD fill process for high aspect ratio gap fill

US20030153181A1|2003-08-14|Deposition of tungsten films

US20070262307A1|2007-11-15|Method of forming an oxygen- or nitrogen-terminated silicon nanocrystalline structure and an oxygen- or nitrogen-terminated silicon nanocrystalline structure formed by the method

KR100299784B1|2001-10-19|A method for forming a textured polysilicon layer, a substrate processing apparatus used to implement this method, and a semiconductor memory device

JPH08236513A|1996-09-13|Method of etching substrate in plasma

KR100536534B1|2005-12-14|A method for manufacturing a thin film device

JP4088912B2|2008-05-21|Capacitor manufacturing method for semiconductor device

JPH09312297A|1997-12-02|Plasma annealing of thin film

JPH0982666A|1997-03-28|Formation of thin film, semiconductor device and manufacture thereof

US6090455A|2000-07-18|Method for forming SBT ferroelectric thin film

KR20040096380A|2004-11-16|Method for cleaning of chamber for depositing metal oxide and apparatus for depositing to performing the same

JP4470227B2|2010-06-02|Film forming method and thin film transistor manufacturing method

US20210140045A1|2021-05-13|Methods to reduce material surface roughness

JP2002134436A|2002-05-10|Plasma processing apparatus, method thereof and plasma product

JP3123203B2|2001-01-09|Plasma device and method of using the device

KR100448718B1|2004-09-13|Plasma enhanced chemical vapor deposition apparatus

JPH1050680A|1998-02-20|Dry etching platinum thin film

JP2895981B2|1999-05-31|Silicon oxide film forming method

JPH09331042A|1997-12-22|Method for growing hemispherical granular silicon

同族专利:

公开号 | 公开日

US20050029570A1|2005-02-10|

US6472320B2|2002-10-29|

US6831324B2|2004-12-14|

US20050029571A1|2005-02-10|

US6214726B1|2001-04-10|

US20030020113A1|2003-01-30|

US5849628A|1998-12-15|

US7220670B2|2007-05-22|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US20050029570A1|1996-12-09|2005-02-10|Sandhu Gurtej S.|Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and products produced by same|AT49023T|1984-03-03|1990-01-15|Stc Plc|PULSATING PLASMA PROCESS.|

GB8516537D0|1985-06-29|1985-07-31|Standard Telephones Cables Ltd|Pulsed plasma apparatus|

US5192717A|1989-04-28|1993-03-09|Canon Kabushiki Kaisha|Process for the formation of a polycrystalline semiconductor film by microwave plasma chemical vapor deposition method|

US5502315A|1989-09-07|1996-03-26|Quicklogic Corporation|Electrically programmable interconnect structure having a PECVD amorphous silicon element|

US5367139A|1989-10-23|1994-11-22|International Business Machines Corporation|Methods and apparatus for contamination control in plasma processing|

US5037773A|1990-11-08|1991-08-06|Micron Technology, Inc.|Stacked capacitor doping technique making use of rugged polysilicon|

US5102832A|1991-02-11|1992-04-07|Micron Technology, Inc.|Methods for texturizing polysilicon|

US5112773A|1991-04-10|1992-05-12|Micron Technology, Inc.|Methods for texturizing polysilicon utilizing gas phase nucleation|

US5242530A|1991-08-05|1993-09-07|International Business Machines Corporation|Pulsed gas plasma-enhanced chemical vapor deposition of silicon|

EP0533044B1|1991-09-20|1999-12-29|Balzers Aktiengesellschaft|Process and apparatus for the protective coating of substrates|

KR950009740B1|1991-11-12|1995-08-26|금성일렉트론주식회사|Method of fabricating a memory capacitor and structure thereof|

EP0553791A1|1992-01-31|1993-08-04|Nec Corporation|Capacitor electrode for dram and process of fabrication thereof|

US5245206A|1992-05-12|1993-09-14|International Business Machines Corporation|Capacitors with roughened single crystal plates|

US5208479A|1992-05-15|1993-05-04|Micron Technology, Inc.|Method of increasing capacitance of polycrystalline silicon devices by surface roughening and polycrystalline silicon devices|

US5320880A|1992-10-20|1994-06-14|Micron Technology, Inc.|Method of providing a silicon film having a roughened outer surface|

US5344792A|1993-03-04|1994-09-06|Micron Technology, Inc.|Pulsed plasma enhanced CVD of metal silicide conductive films such as TiSi2|

US5696014A|1994-03-11|1997-12-09|Micron Semiconductor, Inc.|Method for increasing capacitance of an HSG rugged capacitor using a phosphine rich oxidation and subsequent wet etch|

US5502312A|1994-04-05|1996-03-26|Pitney Bowes Inc.|Double document detection system having dectector calibration|

JP2636755B2|1994-11-09|1997-07-30|日本電気株式会社|Semiconductor device and method of manufacturing semiconductor device|

US5677236A|1995-02-24|1997-10-14|Mitsui Toatsu Chemicals, Inc.|Process for forming a thin microcrystalline silicon semiconductor film|

US5639685A|1995-10-06|1997-06-17|Micron Technology, Inc.|Semiconductor processing method of providing a conductively doped layer of hemispherical grain polysilicon|

US5801104A|1995-10-24|1998-09-01|Micron Technology, Inc.|Uniform dielectric film deposition on textured surfaces|

US5612560A|1995-10-31|1997-03-18|Northern Telecom Limited|Electrode structure for ferroelectric capacitors for integrated circuits|

US5688550A|1995-12-15|1997-11-18|Micron Technology, Inc.|Method of forming polysilicon having a desired surface roughness|

US5830793A|1995-12-28|1998-11-03|Micron Technology, Inc.|Method of selective texfturing for patterned polysilicon electrodes|

US5753559A|1996-01-16|1998-05-19|United Microelectronics Corporation|Method for growing hemispherical grain silicon|

US5754390A|1996-01-23|1998-05-19|Micron Technology, Inc.|Integrated capacitor bottom electrode for use with conformal dielectric|

US5888591A|1996-05-06|1999-03-30|Massachusetts Institute Of Technology|Chemical vapor deposition of fluorocarbon polymer thin films|

US5618747A|1996-06-03|1997-04-08|Industrial Technology Research Institute|Process for producing a stacked capacitor having polysilicon with optimum hemispherical grains|

US5837579A|1996-08-21|1998-11-17|United Microelectronics Corporation|Rugged polysilicon process for DRAM capacitors|

US5849628A|1996-12-09|1998-12-15|Micron Technology, Inc.|Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and products produced by same|

US5851878A|1997-04-01|1998-12-22|United Microelectronics Corporation|Method of forming a rugged polysilicon fin structure in DRAM|

US6399983B1|1999-09-02|2002-06-04|Micron Technology, Inc.|Reduction of shorts among electrical cells formed on a semiconductor substrate|

US6242356B1|1999-12-17|2001-06-05|Taiwan Semiconductor Manufacturing Company|Etchback method for forming microelectronic layer with enhanced surface smoothness|

US6429127B1|2000-06-08|2002-08-06|Micron Technology, Inc.|Methods for forming rough ruthenium-containing layers and structures/methods using same|

US6521515B1|2000-09-15|2003-02-18|Advanced Micro Devices, Inc.|Deeply doped source/drains for reduction of silicide/silicon interface roughness|US5753962A|1996-09-16|1998-05-19|Micron Technology, Inc.|Texturized polycrystalline silicon to aid field oxide formation|

US6291363B1|1999-03-01|2001-09-18|Micron Technology, Inc.|Surface treatment of DARC films to reduce defects in subsequent cap layers|

US6207483B1|2000-03-17|2001-03-27|Taiwan Semiconductor Manufacturing Company|Method for smoothing polysilicon gate structures in CMOS devices|

JP2005259773A|2004-03-09|2005-09-22|Matsushita Electric Ind Co Ltd|Method of manufacturing semiconductor device|

US7375946B2|2004-08-16|2008-05-20|Applied Materials, Inc.|Method and apparatus for dechucking a substrate|

KR100636022B1|2005-04-08|2006-10-18|삼성전자주식회사|Method for forming a thin film in semiconductor device and manufacturing a non-volatile memory device using the same|

US7927948B2|2005-07-20|2011-04-19|Micron Technology, Inc.|Devices with nanocrystals and methods of formation|

US8110493B1|2005-12-23|2012-02-07|Novellus Systems, Inc.|Pulsed PECVD method for modulating hydrogen content in hard mask|

US7745346B2|2008-10-17|2010-06-29|Novellus Systems, Inc.|Method for improving process control and film conformality of PECVD film|

CN103898613B|2012-12-24|2017-07-07|中微半导体设备有限公司|Method for etching plasma|

法律状态:
2006-04-07| FPAY| Fee payment|Year of fee payment: 4 |

2010-04-21| FPAY| Fee payment|Year of fee payment: 8 |

2014-06-06| REMI| Maintenance fee reminder mailed|

2014-10-29| LAPS| Lapse for failure to pay maintenance fees|

2014-11-24| STCH| Information on status: patent discontinuation|Free format text: PATENT EXPIRED DUE TO NONPAYMENT OF MAINTENANCE FEES UNDER 37 CFR 1.362 |

2014-12-16| FP| Expired due to failure to pay maintenance fee|Effective date: 20141029 |

优先权:

申请号 | 申请日 | 专利标题

US08/762,544|US5849628A|1996-12-09|1996-12-09|Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and products produced by same|

US09/127,159|US6214726B1|1996-12-09|1998-07-31|Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and products produced by same|

US09/732,624|US6472320B2|1996-12-09|2000-12-08|Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and products produced by the same|US09/732,624| US6472320B2|1996-12-09|2000-12-08|Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and products produced by the same|

US10/246,213| US6831324B2|1996-12-09|2002-09-18|Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and products produced by the same|

US10/930,443| US7220670B2|1996-12-09|2004-08-31|Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and products produced by same|

US10/930,521| US20050029571A1|1996-12-09|2004-08-31|Method of producing rough polysilicon by the use of pulsed plasma chemical vapor deposition and products produced by same|

[返回顶部]