1995
DOI: 10.1117/12.221303
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<title>In-situ process monitoring in metal deposition processes</title>

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Cited by 3 publications
(3 citation statements)
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“…Some recent real-time applications of QMS include: in situ feedback control of a plasma enhanced chemical-vapor deposition (PECVD) process (Knight [3] and Greve et al [4]), sidewall spacer etching (Min [5]), endpoint uniformity sensing and analysis during silicon dioxide plasma etching (Chambers et al, [6], [7]), monitoring of a tungsten metal CVD process (Kobayashi et al [8]), process sensing and metrology in amorphous and selective area silicon plasma deposition (Chowdhury et al [9]), process sensing during rapid thermal chemical-vapor deposition (RTCVD) of polysilicon (Rying et al [10], Tedder [11], [12], Smith [13], Lu [14], [15], and Rubloff et al [16]), and more recently in situ monitoring and characterization of RTCVD thin oxide (SiO ), nitride (Si N ), and tungsten (W) films (Lu et al [17], Rying et al [18], and Gougousi et al [19], [20]). …”
Section: In Situ Selectivity and Thickness Monitoring Duringmentioning
confidence: 99%
“…Some recent real-time applications of QMS include: in situ feedback control of a plasma enhanced chemical-vapor deposition (PECVD) process (Knight [3] and Greve et al [4]), sidewall spacer etching (Min [5]), endpoint uniformity sensing and analysis during silicon dioxide plasma etching (Chambers et al, [6], [7]), monitoring of a tungsten metal CVD process (Kobayashi et al [8]), process sensing and metrology in amorphous and selective area silicon plasma deposition (Chowdhury et al [9]), process sensing during rapid thermal chemical-vapor deposition (RTCVD) of polysilicon (Rying et al [10], Tedder [11], [12], Smith [13], Lu [14], [15], and Rubloff et al [16]), and more recently in situ monitoring and characterization of RTCVD thin oxide (SiO ), nitride (Si N ), and tungsten (W) films (Lu et al [17], Rying et al [18], and Gougousi et al [19], [20]). …”
Section: In Situ Selectivity and Thickness Monitoring Duringmentioning
confidence: 99%
“…Examples may be drawn from the metals industry, where on-line monitoring of steel blast furnace off-gases and reagent gas-mixing stations 60 or aluminum potline smelter emissions 70 can be used to optimize plant efficiency. Monitoring the composition and purity of reagent gases is particularly critical in the electronics industry, where PMS has been used to control various chemical vapor deposition, [71][72][73] molecular beam epitaxy, 74 and plasma etching 73 processes. The complex processing associated with electronics devices and their relative intolerance of flaws suggests a high value added.…”
Section: Applications Of Process Mass Spectrometrymentioning
confidence: 99%
“…In this environment, the electronics industry was one of the first to embrace PMS for on-line control . A wide range of reagents can be monitored, including simple gases (like H 2 and NH 3 73 ) and more complex and/or corrosive reagents (like SiH 4 , SiF 4 , and HCl) and intermediates. , The mass spectrometer can also sense leaks in the reagent lines, a critical function in systems where sub-ppm contamination by components of air can compromise product quality. Besides true process monitoring and control, PMS has played a crucial role in elucidating the mechanisms of important deposition and etching reactions (e.g., refs and ), thereby facilitating modeling and “off-line” optimization of these processes.…”
Section: Applications Of Process Mass Spectrometrymentioning
confidence: 99%