A High Sensitivity and Compact Real Time Gas Concentration Sensor for Semiconductor and Electronic Device Manufacturing Process

Ishii, Hiroki; Nagase, Masaaki; Ikeda, Nobukazu; Shiba, Yoshitaka; Shirai, Yoshihito; Kuroda, Rihito; Sugawa, Shigetoshi

doi:10.1149/08513.1399ecst

Cited by 6 publications

(6 citation statements)

References 5 publications

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“…6. 17,18) Differential signal voltages from switching two LEDs with different wavelengths with and without light absorption are amplified by a differential amplifier and sampled by a 16 bit analog/digital (A/D) converter. A 330 pF charge capacitor was used and the integration time was measured under the condition of 495 ms light irradiation at both 252 nm and 368 nm.…”

Section: Gas Concentration Sensor Unit With a Heating Functionmentioning

confidence: 99%

“…On the other hand, various MO gases have relatively high light absorbance in the UV waveband. [17][18][19][20][21] Focusing on this characteristic, we have been researching the development of a high-sensitivity MO gas concentration sensor using a timesharing dual-wavelength UV light absorption method. [17][18][19] The Lambert-Beer law (Eq.…”

Section: Introductionmentioning

confidence: 99%

“…[17][18][19][20][21] Focusing on this characteristic, we have been researching the development of a high-sensitivity MO gas concentration sensor using a timesharing dual-wavelength UV light absorption method. [17][18][19] The Lambert-Beer law (Eq. 1) relates attenuation and concentration when a target gas is irradiated with light:…”

Section: Introductionmentioning

confidence: 99%

“…By using a charge amplifier circuit to integrate photo charge for a higher SN ratio, a detection limit of the order of 10 ppm has been achieved for several MO gases. 17,18) Since the concentration of TMA gas in the bubbling method is generally about 1%, the detection accuracy of the gas concentration sensor needs be 100 ppm or better. The shortest wavelength LED we used was 252 nm, but even with this we could not obtain a detection limit of more than 100 ppm.…”

Section: Introductionmentioning

confidence: 99%

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A high-sensitivity compact gas concentration sensor using ultraviolet light absorption with a heating function for a high-precision trimethyl aluminum gas supply system

Ishii

Nagase

Ikeda

et al. 2019

Jpn. J. Appl. Phys.

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This work presents a high-sensitivity, real-time, compact gas concentration sensor using a time-sharing dual-wavelength UV light absorption method developed for a high-precision trimethyl aluminum (TMA) gas supply system. We analyzed the characteristics of TMA, examined a method to increase sensitivity by controlling the gas transition, and fabricated a highly reliable heatable gas cell. The detection circuit demonstrated that TMA can be measured stably using a charge amplifier method that can detect various metal organic gases with high sensitivity. By controlling the sensing temperature to increase the ratio of TMA monomers (which have a higher UV absorbance) to dimers, a detection limit of 62.7 ppm was achieved.

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Section: Gas Concentration Sensor Unit With a Heating Functionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A high-sensitivity compact gas concentration sensor using ultraviolet light absorption with a heating function for a high-precision trimethyl aluminum gas supply system

Ishii

Nagase

Ikeda

et al. 2019

Jpn. J. Appl. Phys.

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“…In some of the aforementioned production steps, such as Chemical Vapor Deposition (CVD), the step quality is assessed by measuring a set of, so-called, critical dimensions at several sites on the wafer surface, with consequent time-consuming procedures needed to allow the metrology tool to visit all the required sites. In fact, in the example case of CVD, a process widely employed for altering the chemical composition of wafers, the quality is assessed by measuring the height of the 'deposited' layer [10]. The challenge for CVD and similar spatial processes is measuring a sufficient number of sites to allow the complete wafer profile to be reconstructed.…”

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confidence: 99%

Induced Start Dynamic Sampling for Wafer Metrology Optimization

Susto

Maggipinto

Zocco

et al. 2020

IEEE Trans. Automat. Sci. Eng.

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Metrology, which plays an important role in ensuring production quality in modern manufacturing industries, incurs substantial costs, both in terms of the infrastructure required, and the time needed to perform measurements. In particular, in the semiconductor manufacturing industry, measuring fundamental quantities on different sites of a wafer surface is associated with increased production time. To increase metrology efficiency, a typical strategy is to limit the number of sites measured and to exploit statistical models (soft sensing) to reconstruct the wafer profile. Moreover, for quality reasons, spatial dynamic sampling strategies may be employed to ensure that all regions of a wafer surface are checked periodically during production. In this work, we propose a new sampling strategy, called Induced Start Dynamic Sampling (ISDS), that adapts greedy feature selection algorithms to the spatial dynamic sampling problem such that the number of measured sites at each process run is minimized while achieving good wafer profile reconstruction accuracy and process visibility. The superiority of the proposed strategy with respect to the state-of-the-art is demonstrated using both simulated data and an industrial chemical vapour deposition case study. Note To Practitioners-In this work we tackle a practical metrology problem encountered in semiconductor manufacturing, namely, the design of a dynamic wafer measurement plan to monitor the accuracy of a process across the whole wafer surface. The measurement plan is called 'dynamic', since, the measurement locations, which are drawn from a candidate set that provides coverage of the whole wafer, change at each process iteration. Our methodology addresses the challenge of finding an optimized trade-off between the number of measurements performed on each wafer and the reconstruction accuracy that can be achieved for the unmeasured areas on the wafer, while at the same time, for quality assurance purposes, ensuring that all locations on a wafer are visited in a finite number of process runs. The major benefit of the methodology is that it can significantly reduce the number of sites that need to be measured on each wafer enabling greater throughput on metrology tools without sacrificing process monitoring and anomaly detection capability.

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In Situ Measurement and Analysis of Low Pressure Gas Concentration Distribution Using 70-dB SNR 1,000 Frame-Per-Second Absorption Imaging System

Sakai

Shiba

Inada

et al. 2022

2022 International Symposium on Semiconductor Manufacturing (ISSM)

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A High Sensitivity and Compact Real Time Gas Concentration Sensor for Semiconductor and Electronic Device Manufacturing Process

Cited by 6 publications

References 5 publications

A high-sensitivity compact gas concentration sensor using ultraviolet light absorption with a heating function for a high-precision trimethyl aluminum gas supply system

A high-sensitivity compact gas concentration sensor using ultraviolet light absorption with a heating function for a high-precision trimethyl aluminum gas supply system

Induced Start Dynamic Sampling for Wafer Metrology Optimization

In Situ Measurement and Analysis of Low Pressure Gas Concentration Distribution Using 70-dB SNR 1,000 Frame-Per-Second Absorption Imaging System

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