Interferometry
Interferometric surface & thickness metrology with lasers
In semiconductor manufacturing, perfection is measured in nanometers - or often even less. Every wafer, mask, or thin film must meet extreme standards of flatness, smoothness, and uniformity to ensure reliable device performance and high production yield. Even the smallest topographical deviation or thickness variation can affect transistor performance, optical alignment, or pattern fidelity.
To measure such minute variations with speed and accuracy, the industry relies on laser-based interferometric metrology - a non-contact, non-destructive optical technique capable of resolving surface and layer thickness with sub-nanometer precision.
The importance of interferometric metrology in semiconductor manufacturing
Interferometry has become a cornerstone of process control in semiconductor fabrication. By analyzing how coherent light interferes after reflection from different surfaces or interfaces, it can detect height variations, layer thickness, and refractive index changes with atomic-scale sensitivity.
Applications span the entire process chain:
- Wafer flatness and bow measurement after polishing or deposition
- Thin-film thickness control during multilayer growth or coating steps
- Mask and pellicle inspection in lithography
- Overlay and alignment metrology for stepper calibration
- Stage position and vibration monitoring for motion control in exposure tools
Wherever geometry, uniformity, or optical quality defines performance, interferometry provides the most accurate feedback - and lasers are the key enabler.
The role of lasers in surface & thickness metrology
Interferometric measurements depend on light that is both coherent and stable. Lasers uniquely combine these properties, providing the temporal and spatial coherence, narrow linewidth, and polarization purity required to achieve reliable fringe contrast and reproducible phase information.
Why lasers are indispensable:
- High spatial coherence: Enables well-defined interference fringes across large wafer surfaces.
- Long coherence length: Allows large optical path differences in Fizeau or Michelson setups.
- Narrow linewidth (<1 MHz): Critical for phase accuracy and sub-nanometer height resolution.
- Stable wavelength (Δλ < 0.001 nm): Ensures repeatable and absolute measurement precision.
- Polarization control: Linear or circular polarization enhances fringe contrast and reduces artifacts.
- Excellent beam quality (M² ≈ 1): Produces clean, uniform illumination with minimal aberrations.
In short: without lasers, interferometric surface metrology would not reach the precision required for today’s - or tomorrow’s - semiconductor nodes.
Laser types and wavelength used
Different interferometric tasks call for different laser sources. The choice depends on the sample material, surface reflectivity, layer structure, and desired resolution.
| Laser Type | Wavelength Range | Typical Application | Key Characteristics | TOPTICA's recommendation |
|---|---|---|---|---|
| HeNe lasers and HeNe replacements | 632.8 nm | Reference standard for displacement, alignment and calibration | Ultra-stable, single-frequency output | iBeam smart WS, DFB Pro 633 |
| Single-frequency diode lasers | 405 - 1064 nm | Surface topography, thin-film thickness, inline metrology | Compact, tunable, low noise, flexible polarization | DL pro, TopMode, DFB pro, iBeam smart WS |
| Fiber lasers (Yb, Er, Tm) | 1030 - 2050 nm | Heterodyne interferometry, vibration sensing, buried interface analysis | High stability, long coherence, maintenance-free operation | ALS |
| Frequency-doubled / tripled solid-state lasers |
532 / 355 nm | High-resolution surface imaging, mask inspection, transparent film metrology | Short wavelength = higher spatial resolution | TopWave, NLO-SHG |
| Tunable / swept lasers or VCSEL arrays |
630–1650 nm | Spectroscopic & multilayer interferometry | Broadband coverage with monochromatic precision | TOPO, TOPO Smart, DFB pro |
Visible and DUV lasers
Shorter wavelengths (UV–visible) provide finer spatial resolution because the smallest detectable feature scales with λ/2. They are used for mask and surface inspection, optical coating verification, and surface roughness analysis.
Near- and mid-infrared lasers
NIR and mid-IR sources penetrate deeper into multi-layer stacks and are ideal for film thickness and buried-interface characterization.
Typical interferometric techniques in the semiconductor industry
Fizeau and Michelson Interferometers
Used for wafer flatness and optical component testing, operating with single-frequency HeNe or fiber lasers to achieve λ/1000 precision.
Phase-Shifting and Heterodyne Interferometry
By modulating the optical phase, these systems extract sub-fringe resolution and dynamic information such as vibration or overlay drift - essential for stage calibration and alignment control.
White-Light and Multi-Wavelength Interferometry
Although historically based on broadband lamps, modern instruments use multi-wavelength laser sources or tunable swept lasers to combine the high resolution of monochromatic light with an extended measurement range. This is key for multi-layer film thickness and topography mapping.
Emerging applications and requirements
1. Swept-Source & Frequency-Comb Interferometry
Next-generation systems use tunable lasers or optical frequency combs to provide absolute distance and film-thickness measurement with picometer accuracy. Frequency-comb lasers bring self-referenced wavelength calibration, eliminating drift.
2. In-line and In-situ Integration
Compact, fiber-coupled laser interferometers are being integrated directly into CMP, etch, and deposition tools, enabling real-time process feedback and adaptive control - a step toward fully autonomous fabs.
3. Multi-Wavelength and Dual-Color Metrology
Combining visible and infrared lasers allows simultaneous measurement of surface topography and buried layer thickness, improving process correlation and reducing measurement time.
4. 2 µm Region and THz Extension
Lasers in the 2 µm spectral region open new frontiers for dielectric and polymer metrology and act as drivers for THz time-domain interferometry, providing non-destructive inspection of packaging and encapsulation layers.
5. AI-Assisted Data Evaluation
Machine-learning algorithms applied to high-contrast laser interferograms improve defect classification, automate anomaly detection, and accelerate process optimization.
The future of laser-based interferometric metrology
As semiconductor technology advances toward ever smaller nodes, 3D architectures, and heterogeneous integration, dimensional metrology must evolve to match atomic-level precision. Lasers will continue to be the enablers - offering unmatched stability, coherence, tunability, and beam quality.
From visible to mid-infrared, from fixed single-frequency sources to frequency-comb systems, lasers make it possible to see and measure what no mechanical sensor can. Their reliability, compactness, and adaptability ensure they remain the light engines of next-generation interferometric metrology - securing the accuracy and yield the semiconductor industry demands.