AISI 1045 Carbon Steel

Use abrasive cut-off wheel designed for steel (Al₂O₃ or SiC abrasive). Standard cut-off wheel (1.0-1.5 mm thickness) is appropriate. Use adequate coolant flow to prevent overheating - excessive heat can affect the microstructure. Cutting speed: 200-300 RPM for most cut-off saws. Apply steady, moderate pressure - the material allows for reasonable feed rates. Avoid forcing the cut which can cause wheel wear and sample damage. Leave adequate allowance (~2-3 mm) for grinding away the heat-affected zone from cutting.

Cold mounting with epoxy resin is preferred to avoid heat that could affect the microstructure. Use a low-shrinkage epoxy resin for best edge retention. Ensure complete cure before grinding to prevent edge rounding and maintain sample integrity.

Hot compression mounting is acceptable if the part tolerates ~150-180°C and moderate pressure (2000-3000 psi for phenolic). Use phenolic or epoxy-phenolic resins. Ensure proper cooling under pressure to minimize shrinkage.

The medium hardness (170 HB) of AISI 1045 Carbon Steel requires careful grinding. Use standard SiC grinding papers with adequate water lubrication. Disc speed: 200-300 RPM. Apply light to moderate pressure (25-35 N per 30 mm sample) - avoid excessive force that could cause work hardening. Use sharp, fresh grinding papers to minimize deformation.

Grinding sequence:

• 120 grit: Remove sectioning damage (30-60 seconds). Use moderate pressure to remove heat-affected zone.
• 240 grit: Remove previous scratches (30-60 seconds). Ensure complete scratch removal.
• 320 grit: Remove previous scratches (30-60 seconds). Ensure complete scratch removal.
• 400 grit: Remove previous scratches (30-60 seconds). Ensure complete scratch removal.
• 600 grit: Remove previous scratches (30-60 seconds). Ensure complete scratch removal.

Always rotate the specimen holder 90° between steps to ensure complete scratch removal. Use complementary rotation (platen and holder same direction, different speeds) rather than contra-rotation to minimize deformation. Adequate water lubrication is critical - avoid drying during grinding which can cause smearing.

The medium hardness requires careful polishing. Use diamond polishing with appropriate polishing pads for each stage. Apply light to moderate pressure throughout to prevent deformation.

Diamond polishing sequence:

• 9μm diamond: 2-4 minutes on a medium-hard synthetic pad (e.g., TEXPAN) with light to moderate pressure (25-35 N per 30 mm sample). Start with 9μm to minimize damage. ensure complete scratch removal at each step.
• 3μm diamond: 2-4 minutes on a medium-hard synthetic pad (e.g., TEXPAN) with light pressure (20-30 N). Continue removing scratches from previous step.
• 1μm diamond: 2-3 minutes on a medium-hard synthetic pad with lighter pressure (20-30 N). These pads provide gentle material removal.
• 0.05μm colloidal silica: 1-2 minutes on a high-napped final polishing pad (e.g., MICROPAD) with very light pressure. This removes any remaining fine scratches and prepares the surface for etching. Monitor for relief - reduce polishing time if excessive relief develops.

Use appropriate polishing lubricants. The medium material means polishing times should be sufficient but not excessive - avoid over-polishing which can cause relief and affect grain boundary revelation. Monitor the surface frequently under the microscope to check for smearing or excessive relief.

AISI 1045 Carbon Steel responds well to standard etchants for carbon steel materials. The ferrite and pearlite (annealed), martensite (quenched) will reveal clearly with appropriate etchants. 2% Nital (Chemical Etching) - Primary choice for carbon steels:

• Composition: 2ml HNO₃ (concentrated), 98ml ethanol
• Preparation: Add nitric acid to ethanol slowly with stirring. Prepare fresh for best results. Solution is stable for several days if stored properly.
• Application: Immerse sample or swab for 5-15 seconds. Standard etchant for carbon steels.
• Reveals: Ferrite grain boundaries and pearlite structure clearly. Excellent for general microstructure examination.
• Rinse: Immediately with water, then ethanol. Dry with compressed air or warm air to avoid staining.
• Note: Prepare fresh when needed. Shelf life: several days. Use in fume hood.

4% Picral (Chemical Etching) - For revealing pearlite structure:

• Composition: 4g picric acid, 100ml ethanol
• Preparation: Dissolve picric acid in ethanol with stirring. Prepare fresh for best results. Solution is stable for several weeks if stored properly.
• Application: Immerse sample or swab for 10-60 seconds. Excellent for revealing pearlite structure without attacking ferrite boundaries.
• Reveals: Pearlite structure clearly with excellent contrast. Less aggressive on ferrite grain boundaries than nital.
• Rinse: Immediately with water, then ethanol. Dry with compressed air.
• Note: Prepare fresh when needed. Shelf life: several weeks if stored properly. Use in fume hood. Picric acid is explosive when dry - keep moist and handle with care.

Etching Strategy:

• Start with 2% Nital for general microstructure examination
• Always clean and degrease before etching
• Use short initial etch times (a few seconds), check under the microscope, repeat if needed
• Check etching progress frequently - over-etching can obscure fine details

Safety: All etchants require proper PPE (gloves, safety glasses, lab coat), proper fume hood, and appropriate safety measures. Handle with care.