Transmission Electron Microscopy in Semiconductors: Generating Ground Truth Insights

What is the current state of TEM in semiconductor analysis?

Transmission electron microscopy (TEM) has become a crucial tool in semiconductor manufacturing. Modern semiconductor fabrication requires atomic-scale imaging and analysis capabilities, particularly for complex three-dimensional (3D) structures, such as gate-all-around (GAA) logic transistors and 3D NAND memory channels.

How does TEM technology work?

TEM operates by directing an electron beam through an ultra-thin sample. The transmitted electrons interact with various filters, detectors, and cameras below the sample. Key operational aspects include:

• Acceleration voltages—60 kV to 300 kV range for semiconductor applications
• Resolution capability—down to individual atom visualization
• Analysis modes—TEM and STEM (scanning TEM)

Fig 1: Comparison diagram of optical microscope and TEM configurations.

What are the key differences between TEM and STEM modes?

TEM mode:

• Uses a focused beam on the sample
• Captures transmitted electrons in a single snapshot
• Employs high-speed, high-resolution cameras
• Offers faster, simpler operation

Fig 2: Schematic illustration of TEM mode operation.

STEM mode:

• Utilizes electromagnetic scan coils
• Scans a focused beam across the sample
• Multiple detector configurations available
• Provides flexible, high-contrast imaging

Fig 3: Schematic illustration of STEM mode operation.

How has automation enhanced TEM analysis?

Modern semiconductor TEM systems feature significant automation improvements:

• Simplified parameter selection
• Automated alignment and calibration
• Reduced data distortion risk
• Atomic-scale image calibration
• Streamlined operation for various sample types

Why is TEM critical for semiconductor manufacturing?

TEM serves as the primary source for reference data in semiconductor design and fabrication due to:

• Increased 3D device complexity
• Shrinking critical dimensions
• EUV lithography requirements
• Need for atomic interface analysis
• Strain and magnetic field measurements

What are the key applications and the industry impact?

Leading semiconductor manufacturers now generate tens of thousands of TEM datasets monthly for:

• Process variation analysis
• Wafer fab tool calibration
• Defect mechanism investigation
• Quality control

Fig 4: Graph showing growth trend in semiconductor TEM analysis usage.

Summary

• TEM technology provides atomic-level imaging and analysis capabilities
• Dual-mode operation (TEM/STEM) offers flexible analysis options
• Automation advances have simplified operation and improved reliability
• Critical role in semiconductor manufacturing quality control
• Essential for next-generation device development

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Paul Kirby is a Senior Marketing Manager at Thermo Fisher Scientific

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