Recommended Procedures
Class 4

Soft, Brittle Non-metals

Hardness 300–1200 HV Typical Si · GaAs · PZT · AlN Key challenge Fracture & delamination

Class 4 encompasses semiconductors, functional ceramics, and multilayer electronic components that share a defining combination: moderate hardness with extremely low fracture toughness. Silicon, gallium arsenide, piezoelectric ceramics (PZT), ferrites, aluminum nitride substrates, and multilayer devices (MLCCs, MEMS) are all brittle enough to fracture, cleave, or delaminate under the forces used in standard metallographic preparation. Many contain layered structures with micron-scale features that require very flat, relief-free surfaces to analyze. Preparation must balance material removal against fracture and delamination risk at every step.

Computer chip microstructure showing typical Class 4 electronic material structure
Computer chip: typical Class 4 multilayer electronic material

Overview

Semiconductors, functional ceramics, and multilayer electronic devices: moderately hard but extremely brittle. Layered structures and micron-scale features demand a flat, relief-free finish achieved with light pressure and vacuum-impregnated mounts.

Preparation Challenges

Seven properties drive the prep procedure. Tap a card for full detail.

Extreme Brittleness Si cleaves, GaAs shatters, ceramics develop deep subsurface crack networks.

All Class 4 materials fracture rather than deform under mechanical stress. Silicon cleaves along crystallographic planes, GaAs shatters unpredictably, and ceramics (PZT, ferrites, AlN) develop subsurface cracks that propagate during subsequent preparation steps. Coarse grinding is the most damaging step: subsurface crack networks from aggressive material removal can extend 50-100 µm below the surface and require extensive polishing to remove. Use the finest practical starting grit and very light force throughout.

Layer Delamination MLCC and MEMS layer interfaces separate rapidly under uneven force.

MLCCs contain hundreds of alternating ceramic and electrode layers, each a few microns thick. MEMS devices combine silicon, metals, and thin-film materials in complex three-dimensional structures. Excessive grinding or polishing force separates these layers, and once delamination starts it propagates rapidly. Vacuum impregnation with low-viscosity epoxy before grinding stabilizes layer interfaces. Use light, consistent pressure and avoid sudden force changes during preparation.

Relief Between Dissimilar Materials Soft electrodes recess below hard ceramic, obscuring the layer features.

Layered structures contain materials with very different hardness and polishing rates. Metal electrodes in MLCCs are softer than the surrounding barium titanate ceramic, creating depressions at every layer. Silicon polishes faster than nickel or gold in MEMS devices. Relief obscures the fine features that are usually the reason for preparing these specimens. Use napless cloths exclusively, keep polishing times short, and apply uniform pressure across the specimen to minimize differential removal.

Subsurface Damage Propagation Grinding cracks extend far below the surface; never skip a grit.

Unlike metals, where grinding damage is limited to a thin deformed layer, brittle materials develop crack networks that extend far below the grinding surface. Each subsequent preparation step must remove the full depth of damage from the previous step, or residual cracks will be visible in the final specimen. Progress through grit sizes without skipping steps, and verify at each stage that previous damage has been fully removed before continuing.

Micron-Scale Feature Preservation Sub-micron features demand an exceptionally flat, scratch-free finish.

The features of interest in Class 4 materials are often at the micron or sub-micron scale: thin-film metallization layers, wire bonds, solder joints in MLCCs, electrode patterns in MEMS, domain boundaries in PZT. These features require an extremely flat, scratch-free surface to be visible under the microscope. Even minor surface relief or residual scratching can obscure the analysis target. Final polish quality is paramount.

Target Plane Preparation Reaching an internal plane needs lapping films and frequent inspection.

Many Class 4 specimens require grinding to a specific internal plane (a particular layer, a wire bond cross-section, or a defect location). This target grinding demands precise control of material removal rate and frequent optical verification of progress. Overshoot by even a few microns and the feature of interest is lost. Use controlled-removal grinding equipment or lapping films with frequent inspection under a stereo microscope as the target plane is approached.

Chemical Sensitivity GaAs and thin films react with common acids and cleaners; verify first.

GaAs is attacked by many common polishing and cleaning chemicals. PZT can be affected by acidic solutions. Some thin-film metallizations dissolve in standard etchants. Verify chemical compatibility before using any new preparation product on Class 4 specimens. Water-based diamond suspensions and pH-neutral colloidal silica are generally safe. Avoid alkaline or acidic cleaning solutions unless confirmed compatible with all materials in the specimen.

Class 4 Materials

Seven materials across semiconductors, functional ceramics, and multilayer electronic components.

Semiconductors 2
  • Gallium Arsenide (GaAs)
  • Silicon Substrate
Functional Ceramics 3
  • Aluminum Nitride Substrate
  • Nickel-Zinc Ferrite
  • PZT Piezoelectric Ceramic
Multilayer Electronic Components 2
  • MEMS Device
  • Multilayer Ceramic Capacitor (MLCC)

Recommended Procedure

Five-stage workflow optimized to minimize fracture, delamination, and relief.

  1. 1

    Sectioning

    Low-speed diamond wafering with gravity or very light feed; approach target planes slowly with optical checks.

    More detail

    Use a low-speed precision diamond wafering saw with a thin resin-bonded or electroplated diamond blade and continuous coolant. Feed force must be minimal (gravity feed or very light spring loading) to prevent fracture and edge chipping. For silicon and GaAs wafers, orient the cut to avoid cleavage planes where possible. MLCCs and MEMS devices are often too small for clamping and should be potted in epoxy first, then sectioned through the mount. For target cross-sections, approach the plane of interest slowly with frequent optical checks under a stereo microscope.

  2. 2

    Mounting

    Castable epoxy with vacuum impregnation only. Compression mounting will fracture or delaminate the specimen.

    More detail

    Castable (cold) epoxy with vacuum impregnation is essential for all Class 4 materials. Vacuum impregnation fills internal voids in porous ceramics, stabilizes the interfaces between layers in MLCCs and MEMS, and provides mechanical support to prevent fracture during grinding. Use low-viscosity, low-shrinkage epoxy to minimize stress on the specimen during cure. Compression mounting must never be used; the heat and pressure will fracture, delaminate, or permanently alter these materials. For cross-sectional analysis of small components, pot multiple specimens in a single mount for efficiency.

  3. 3

    Grinding

    Start at 600 grit (or 30 µm lapping film) and progress through 800 / 1200 / 2400 with very light pressure and frequent cleaning.

    More detail

    Start at 600 grit SiC or finer to minimize subsurface fracture depth. For multilayer components and target plane preparations, diamond lapping films (30 µm, then 15 µm, then 9 µm) provide better control of material removal than SiC papers. Progress through 800, 1200, and 2400 grit with very light pressure (5-10 N per 30 mm mount). Use contra-rotation at low speed (100-150 RPM). Check progress frequently under the microscope, especially when grinding toward a target plane. Thoroughly clean between every grit change to prevent coarse particles from causing fracture on finer steps.

  4. 4

    Polishing

    Napless cloths only: 3 → 1 µm diamond, finish with 0.05 µm colloidal silica; vibratory polish for maximum flatness.

    More detail

    Use napless cloths exclusively to maintain flatness and minimize relief between dissimilar materials. Polish with 3 µm diamond suspension, then 1 µm diamond, followed by 0.05 µm colloidal silica on a napless or chemically resistant pad. Use very light pressure (5-10 N) and short polishing times (30-60 seconds per step) to prevent differential material removal. Contra-rotation reduces directional artifacts. For specimens where maximum flatness is critical (MLCC electrode analysis, MEMS layer measurements), vibratory polishing with colloidal silica for 1-4 hours produces the best results with minimal relief.

  5. 5

    Etching

    Examine as-polished with DIC or polarized light first; use chemical etching only for defect decoration on specific elements.

    More detail

    Most Class 4 materials are examined as-polished or with optical contrast techniques (DIC, polarized light, darkfield) rather than chemical etching. Layer structures, voids, cracks, and electrode patterns are typically visible without etching. When etching is needed, use material-specific solutions with caution: Wright etch (HF + HNO₃ + CrO₃) or Secco/Schimmel for silicon defect decoration, since straight HF will not reveal Si grain boundaries without an oxidizer; molten KOH or bromine-methanol for GaAs defect decoration. PZT and ferrites are rarely etched chemically; thermal etching (brief heating in air) can reveal grain boundaries without chemical attack. Always verify etchant compatibility with all materials present in multilayer specimens before proceeding.

    Common etchants by material

    Most Class 4 materials are evaluated as-polished under polarized light or DIC. Chemical etching is reserved for defect studies.

    Silicon
    Wright etch (HF + HNO₃ + acetic + CrO₃); Secco etch; Schimmel etch (all reveal defects)
    GaAs / III-V semiconductors
    H₂SO₄ + H₂O₂ + H₂O; HBr + Br₂ for dislocations
    PZT / piezoelectric ceramics
    HF + HCl or HF + HNO₃; brief immersion tints domain structure
    Ferrites
    HCl + HNO₃; nital for metallic phases
    Aluminum nitride (AlN)
    Hot H₃PO₄ (250°C); molten KOH
    MLCC / MEMS
    Typically not etched; cross-section evaluation uses polarized light or SEM

    Learn about etchants → Shop etchants →

Quality Checks

  • No delamination between layers in multilayer components (MLCCs, MEMS)
  • Minimal relief between dissimilar materials at layer interfaces
  • No subsurface fractures or cleavage cracks visible at 200×
  • Micron-scale features (electrodes, thin films, wire bonds) clearly resolved
  • Target cross-section plane reached without overshooting the feature of interest