公开(公告)号：US20180258535A1

公开(公告)日：2018-09-13

申请号：US15976468

申请日：2018-05-10

Applicant: Applied Materials, Inc.

Inventor： Nagarajan RAJAGOPALAN ,  Xinhai HAN ,  Michael Wenyoung TSIANG ,  Masaki OGATA ,  Zhijun JIANG ,  Juan Carlos ROCHA-ALVAREZ ,  Thomas NOWAK ,  Jianhua ZHOU ,  Ramprakash SANKARAKRISHNAN ,  Amit Kumar BANSAL ,  Jeongmin LEE ,  Todd EGAN ,  Edward BUDIARTO ,  Dmitriy PANASYUK ,  Terrance Y. LEE ,  Jian J. CHEN ,  Mohamad A. AYOUB ,  Heung Lak PARK ,  Patrick REILLY ,  Shahid SHAIKH ,  Bok Hoen KIM ,  Sergey STARIK ,  Ganesh BALASUBRAMANIAN

IPC: C23C16/52 ,  G01B11/06 ,  H01L21/687 ,  C23C16/509 ,  C23C16/455 ,  C23C16/505 ,  C23C16/50 ,  C23C16/46 ,  C23C16/458 ,  G01N21/65 ,  G01N21/55 ,  H01L21/67 ,  H01L21/00

Abstract: A method of processing a substrate according to a PECVD process is described. Temperature profile of the substrate is adjusted to change deposition rate profile across the substrate. Plasma density profile is adjusted to change deposition rate profile across the substrate. Chamber surfaces exposed to the plasma are heated to improve plasma density uniformity and reduce formation of low quality deposits on chamber surfaces. In situ metrology may be used to monitor progress of a deposition process and trigger control actions involving substrate temperature profile, plasma density profile, pressure, temperature, and flow of reactants.

公开(公告)号：US20230193466A1

公开(公告)日：2023-06-22

申请号：US18108989

申请日：2023-02-13

Applicant: Applied Materials, Inc.

Inventor： Nagarajan RAJAGOPALAN ,  Xinhai HAN ,  Michael Wenyoung TSIANG ,  Masaki OGATA ,  Zhijun JIANG ,  Juan Carlos ROCHA-ALVAREZ ,  Thomas NOWAK ,  Jianhua ZHOU ,  Ramprakash SANKARAKRISHNAN ,  Amit Kumar BANSAL ,  Jeongmin LEE ,  Todd EGAN ,  Edward W. BUDIARTO ,  Dmitriy PANASYUK ,  Terrance Y. LEE ,  Jian J. CHEN ,  Mohamad A. AYOUB ,  Heung Lak PARK ,  Patrick REILLY ,  Shahid SHAIKH ,  Bok Hoen KIM ,  Sergey STARIK ,  Ganesh BALASUBRAMANIAN

IPC: C23C16/52 ,  G01B11/06 ,  H01L21/687 ,  H01L21/67 ,  C23C16/509 ,  G01N21/55 ,  G01N21/65 ,  H01L21/00 ,  C23C16/458 ,  C23C16/46 ,  C23C16/50 ,  C23C16/505 ,  C23C16/455

CPC classification number: C23C16/52 ,  G01B11/0683 ,  H01L21/687 ,  H01L21/67248 ,  H01L21/67253 ,  C23C16/5096 ,  G01N21/55 ,  G01N21/658 ,  G01B11/0625 ,  H01L21/00 ,  C23C16/458 ,  C23C16/46 ,  C23C16/50 ,  C23C16/505 ,  C23C16/45565 ,  C23C16/4557 ,  C23C16/509 ,  G01N2201/1222

Abstract: A method of processing a substrate according to a PECVD process is described. Temperature profile of the substrate is adjusted to change deposition rate profile across the substrate. Plasma density profile is adjusted to change deposition rate profile across the substrate. Chamber surfaces exposed to the plasma are heated to improve plasma density uniformity and reduce formation of low quality deposits on chamber surfaces. In situ metrology may be used to monitor progress of a deposition process and trigger control actions involving substrate temperature profile, plasma density profile, pressure, temperature, and flow of reactants.

公开(公告)号：US20170016118A1

公开(公告)日：2017-01-19

申请号：US15278455

申请日：2016-09-28

Applicant: Applied Materials, Inc.

Inventor： Nagarajan RAJAGOPALAN ,  Xinhai HAN ,  Michael Wenyoung TSIANG ,  Masaki OGATA ,  Zhijun JIANG ,  Juan Carlos ROCHA-ALVAREZ ,  Thomas NOWAK ,  Jianhua ZHOU ,  Ramprakash SANKARAKRISHNAN ,  Amit Kumar BANSAL ,  Jeongmin LEE ,  Todd EGAN ,  Edward BUDIARTO ,  Dmitriy PANASYUK ,  Terrance Y. LEE ,  Jian J. CHEN ,  Mohamad A. AYOUB ,  Heung Lak PARK ,  Patrick REILLY ,  Shahid SHAIKH ,  Bok Hoen KIM ,  Sergey STARIK ,  Ganesh BALASUBRAMANIAN

IPC: C23C16/52 ,  C23C16/46 ,  H01L21/687 ,  C23C16/458 ,  G01B11/06 ,  H01L21/67 ,  C23C16/455 ,  C23C16/509

CPC classification number: C23C16/52 ,  C23C16/45565 ,  C23C16/4557 ,  C23C16/458 ,  C23C16/46 ,  C23C16/50 ,  C23C16/505 ,  C23C16/509 ,  C23C16/5096 ,  G01B11/0625 ,  G01B11/0683 ,  G01N21/55 ,  G01N21/658 ,  G01N2201/1222 ,  H01L21/00 ,  H01L21/67248 ,  H01L21/67253 ,  H01L21/687

Abstract: A method of processing a substrate according to a PECVD process is described. Temperature profile of the substrate is adjusted to change deposition rate profile across the substrate. Plasma density profile is adjusted to change deposition rate profile across the substrate. Chamber surfaces exposed to the plasma are heated to improve plasma density uniformity and reduce formation of low quality deposits on chamber surfaces. In situ metrology may be used to monitor progress of a deposition process and trigger control actions involving substrate temperature profile, plasma density profile, pressure, temperature, and flow of reactants.

Abstract translation: 描述了根据PECVD工艺处理衬底的方法。 调整衬底的温度分布以改变衬底上的沉积速率分布。 调整等离子体密度分布以改变跨衬底的沉积速率分布。 暴露于等离子体的室表面被加热以改善等离子体密度均匀性并减少在室表面上形成低质量的沉积物。 原位计量可用于监测沉积过程的进展并触发涉及衬底温度曲线，等离子体密度分布，压力，温度和反应物流动的控制动作。

公开(公告)号：US20180066364A1

公开(公告)日：2018-03-08

申请号：US15802496

申请日：2017-11-03

Applicant: Applied Materials, Inc.

Inventor： Nagarajan RAJAGOPALAN ,  Xinhai HAN ,  Michael Wenyoung TSIANG ,  Masaki OGATA ,  Zhijun JIANG ,  Juan Carlos ROCHA-ALVAREZ ,  Thomas NOWAK ,  Jianhua ZHOU ,  Ramprakash SANKARAKRISHNAN ,  Amit Kumar BANSAL ,  Jeongmin LEE ,  Todd EGAN ,  Edward BUDIARTO ,  Dmitriy PANASYUK ,  Terrance Y. LEE ,  Jian J. CHEN ,  Mohamad A. AYOUB ,  Heung Lak PARK ,  Patrick REILLY ,  Shahid SHAIKH ,  Bok Hoen KIM ,  Sergey STARIK ,  Ganesh BALASUBRAMANIAN

IPC: C23C16/52 ,  H01L21/687 ,  G01B11/06 ,  H01L21/67 ,  G01N21/55 ,  G01N21/65 ,  C23C16/458 ,  C23C16/46 ,  C23C16/50 ,  C23C16/505 ,  C23C16/455 ,  C23C16/509 ,  H01L21/00

CPC classification number: C23C16/52 ,  C23C16/45565 ,  C23C16/4557 ,  C23C16/458 ,  C23C16/46 ,  C23C16/50 ,  C23C16/505 ,  C23C16/509 ,  C23C16/5096 ,  G01B11/0625 ,  G01B11/0683 ,  G01N21/55 ,  G01N21/658 ,  G01N2201/1222 ,  H01L21/00 ,  H01L21/67248 ,  H01L21/67253 ,  H01L21/687

Abstract: A method of processing a substrate according to a PECVD process is described. Temperature profile of the substrate is adjusted to change deposition rate profile across the substrate. Plasma density profile is adjusted to change deposition rate profile across the substrate. Chamber surfaces exposed to the plasma are heated to improve plasma density uniformity and reduce formation of low quality deposits on chamber surfaces. In situ metrology may be used to monitor progress of a deposition process and trigger control actions involving substrate temperature profile, plasma density profile, pressure, temperature, and flow of reactants.

公开(公告)号：US20160017497A1

公开(公告)日：2016-01-21

申请号：US14869371

申请日：2015-09-29

Applicant: Applied Materials, Inc.

Inventor： NAGARAJAN RAJAGOPALAN ,  Xinhai HAN ,  Michael TSIANG ,  Masaki OGATA ,  Zhijun JIANG ,  Juan Carlos ROCHA-ALVAREZ ,  Thomas NOWAK ,  Jianhua ZHOU ,  Ramprakash SANKARAKRISHNAN ,  Amit Kumar BANSAL ,  Jeongmin LEE ,  Todd EGAN ,  Edward BUDIARTO ,  Dmitriy PANASYUK ,  Terrance Y. LEE ,  Jian J. CHEN ,  Mohamad A. AYOUB ,  Heung Lak PARK ,  Patrick REILLY ,  Shahid SHAIKH ,  Bok Hoen KIM ,  Sergey STARIK ,  Ganesh BALASUBRAMANIAN

IPC: C23C16/52 ,  C23C16/46 ,  C23C16/509 ,  C23C16/455

CPC classification number: C23C16/52 ,  C23C16/45565 ,  C23C16/4557 ,  C23C16/458 ,  C23C16/46 ,  C23C16/50 ,  C23C16/505 ,  C23C16/509 ,  C23C16/5096 ,  G01B11/0625 ,  G01B11/0683 ,  G01N21/55 ,  G01N21/658 ,  G01N2201/1222 ,  H01L21/00 ,  H01L21/67248 ,  H01L21/67253 ,  H01L21/687

Abstract: A method of processing a substrate according to a PECVD process is described. Temperature profile of the substrate is adjusted to change deposition rate profile across the substrate. Plasma density profile is adjusted to change deposition rate profile across the substrate. Chamber surfaces exposed to the plasma are heated to improve plasma density uniformity and reduce formation of low quality deposits on chamber surfaces. In situ metrology may be used to monitor progress of a deposition process and trigger control actions involving substrate temperature profile, plasma density profile, pressure, temperature, and flow of reactants.

Abstract translation: 描述了根据PECVD工艺处理衬底的方法。 调整衬底的温度分布以改变衬底上的沉积速率分布。 调整等离子体密度分布以改变跨衬底的沉积速率分布。 暴露于等离子体的室表面被加热以改善等离子体密度均匀性并减少在室表面上形成低质量的沉积物。 原位计量可用于监测沉积过程的进展并触发涉及衬底温度曲线，等离子体密度分布，压力，温度和反应物流动的控制动作。

公开(公告)号：US20150203966A1

公开(公告)日：2015-07-23

申请号：US14594446

申请日：2015-01-12

Applicant: Applied Materials, Inc.

Inventor： Edward BUDIARTO ,  Thomas NOWAK ,  Todd EGAN ,  Sergey STARIK

IPC: C23C16/52 ,  G01B11/06

CPC classification number: C23C16/52 ,  G01B11/0625 ,  G01B11/0683 ,  H01J37/32917 ,  H01J37/32972

Abstract: Embodiments of the present disclosure enable measurement of film properties, such as thickness, using reflectometry regardless of the underlying pattern on the substrate or base layer because the amount of phase shift resulting from the growing film at any wavelength is independent of the substrate or base layer. One embodiment of the method includes determining properties of the substrate from a time series data. Another embodiment of the method includes removing a plasma background for measuring data by making two consecutive measurement with a light source on and off respectively. Another embodiment includes determining a deposition start time by monitoring a plasma marker or a phase shift of optical properties.

Abstract translation: 本公开的实施例使得可以使用反射测量法来测量膜性质，例如厚度，而不管衬底或基底层上的底层图案如何，因为在任何波长处生长的膜产生的相移量与衬底或基底层无关 。 该方法的一个实施例包括从时间序列数据确定衬底的特性。 该方法的另一实施例包括通过分别用光源进行两次连续测量来移除用于测量数据的等离子体背景。 另一实施例包括通过监测等离子体标记或光学性质的相移来确定沉积开始时间。

公开(公告)号：US20140118751A1

公开(公告)日：2014-05-01

申请号：US14056203

申请日：2013-10-17

Applicant: Applied Materials, Inc.

Inventor： Nagarajan RAJAGOPALAN ,  Xinhai HAN ,  Michael TSIANG ,  Masaki OGATA ,  Zhijun JIANG ,  Juan Carlos ROCHA-ALVAREZ ,  Thomas NOWAK ,  Jianhua ZHOU ,  Ramprakash SANKARAKRISHNAN ,  Amit Kumar BANSAL ,  Jeongmin LEE ,  Todd EGAN ,  Edward BUDIARTO ,  Dmitriy PANASYUK ,  Terrance Y. LEE ,  Jian J. CHEN ,  Mohamad A. AYOUB ,  Heung Lak PARK ,  Patrick REILLY ,  Shahid SHAIKH ,  Bok Hoen KIM ,  Sergey STARIK ,  Ganesh BALASUBRAMANIAN

IPC: G01B11/06

CPC classification number: C23C16/52 ,  C23C16/45565 ,  C23C16/4557 ,  C23C16/458 ,  C23C16/46 ,  C23C16/50 ,  C23C16/505 ,  C23C16/509 ,  C23C16/5096 ,  G01B11/0625 ,  G01B11/0683 ,  G01N21/55 ,  G01N21/658 ,  G01N2201/1222 ,  H01L21/00 ,  H01L21/67248 ,  H01L21/67253 ,  H01L21/687

Abstract: A method of processing a substrate according to a PECVD process is described. Temperature profile of the substrate is adjusted to change deposition rate profile across the substrate. Plasma density profile is adjusted to change deposition rate profile across the substrate. Chamber surfaces exposed to the plasma are heated to improve plasma density uniformity and reduce formation of low quality deposits on chamber surfaces. In situ metrology may be used to monitor progress of a deposition process and trigger control actions involving substrate temperature profile, plasma density profile, pressure, temperature, and flow of reactants.

Abstract translation: 描述了根据PECVD工艺处理衬底的方法。 调整衬底的温度分布以改变衬底上的沉积速率分布。 调整等离子体密度分布以改变跨衬底的沉积速率分布。 暴露于等离子体的室表面被加热以改善等离子体密度均匀性并减少在室表面上形成低质量的沉积物。 原位计量可用于监测沉积过程的进展并触发涉及衬底温度曲线，等离子体密度分布，压力，温度和反应物流动的控制动作。