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Detecting defects that reduce breakdown voltage using machine learning and optical profilometry.

James C Gallagher1, Michael A Mastro2, Alan G Jacobs2

  • 1U.S. Naval Research Laboratory, 4555 Overlook Ave SW, Washington, DC, 20375, USA. james.gallagher@nrl.navy.mil.

Scientific Reports
|March 29, 2024
PubMed
Summary
This summary is machine-generated.

Machine learning predicts semiconductor wafer performance using optical profilometry data. This approach identifies gallium nitride (GaN) devices likely to fail, improving integrated circuit quality.

Keywords:
GaNIII–V semiconductorsMachine learningOptical profilometryVertical diodes

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Area of Science:

  • Materials Science and Engineering: Focus on semiconductor wafer manufacturing and characterization.
  • Electrical Engineering: Application in high-voltage and high-frequency power devices.

Background:

  • Semiconductor wafer manufacturing requires precise control of performance metrics for integrated circuit (IC) quality.
  • Gallium Nitride (GaN) offers advantages for high-voltage/high-frequency power devices, but substrate defects limit performance.
  • Optimizing vertical GaN devices is crucial for next-generation power electronics.

Purpose of the Study:

  • To apply machine learning (ML) to predict wafer performance metrics, specifically breakdown voltage (Vbk).
  • To utilize optical profilometry data as input for ML models.
  • To identify wafers with a high probability of meeting critical performance standards.

Main Methods:

  • Data acquisition using optical profilometry to capture wafer surface characteristics.
  • Implementation of machine learning algorithms to analyze profilometry data.
  • Correlation of predicted performance metrics with actual device breakdown voltage (Vbk).

Main Results:

  • ML models successfully predicted the probability of wafers meeting performance metrics.
  • The approach reliably identified devices prone to premature failure (low breakdown voltage).
  • Optical profilometry data proved effective for predicting critical performance parameters.

Conclusions:

  • Machine learning, combined with optical profilometry, offers a powerful tool for semiconductor wafer quality control.
  • This predictive capability can reduce the number of failing devices and improve manufacturing yields.
  • Further investigation with alternative methods may be needed for devices failing at intermediate breakdown voltages.