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301 Stainless Steel Temper Guide: Annealed vs 1/4 Hard vs 1/2 Hard vs Full Hard

301 stainless steel is unique among austenitic grades: through cold working alone, it can achieve tensile strengths from 515 MPa (annealed) to over 1,850 MPa (extra hard) — a 3.6× increase without any heat treatment. This extraordinary work-hardening capability makes 301 the material of choice for springs, automotive stampings, electronics contacts, and structural components where high strength-to-weight ratio is critical.

But selecting the wrong temper can be costly. Too hard, and the material cracks during forming. Too soft, and the finished part lacks the strength to perform. This guide explains every 301 stainless steel temper condition defined by ASTM A666, compares their mechanical properties, and provides a practical selection framework so you can specify the correct temper with confidence.

Need 301 temper coil for your project? Contact Huaxiao Metal — we supply all ASTM A666 tempers from 0.2mm to 3.0mm with EN 10204 3.1 MTC.

What Is 301 Stainless Steel Temper?

The Work-Hardening Mechanism

301 (UNS S30100 / EN 1.4310) is a metastable austenitic stainless steel. The term “metastable” is key: its austenite phase is not fully stable at room temperature and can transform to martensite (a harder, stronger phase) when subjected to mechanical deformation. This phenomenon is called Strain-Induced Martensitic Transformation (SIMT), and it is the reason 301 work-hardens far more dramatically than 304 or 316.

When 301 coil is cold rolled — passing through precision rolls under enormous pressure — three things happen simultaneously:

  • Grain elongation in the rolling direction increases dislocation density

  • Austenite transforms to martensite (alpha-prime martensite, which is magnetic and hard)

  • Strength increases while ductility decreases in a predictable, controllable manner

The percentage of cold reduction determines the temper designation. More cold reduction means more martensite, higher strength, lower elongation, and greater magnetism.

ASTM A666 vs ASTM A240 — Which Standard Applies?

A common source of confusion: 301 chemical composition is defined in both ASTM A240 and ASTM A666, but temper conditions are only defined in ASTM A666.

StandardScopeApplies to 301?
ASTM A240Plate, sheet, strip for pressure vesselsYes — chemistry + annealed properties
ASTM A666Annealed and cold-worked austenitic SSYes — defines ALL temper conditions
EN 10088-2Stainless steel flat products (Europe)Yes — European equivalent
JIS G4305Cold-rolled SS sheet and strip (Japan)Yes — Japanese equivalent
GB/T 3280Cold-rolled SS sheet and plate (China)Yes — Chinese equivalent

If your specification calls for a specific temper (1/4 hard, 1/2 hard, etc.), the governing standard is ASTM A666. ASTM A240 only covers annealed material.

Six 301 Temper Conditions Explained

ASTM A666 defines five standard temper conditions for 301, plus a sixth commercial designation used in the industry. Each represents a specific cold reduction range with corresponding minimum mechanical properties.

Annealed (Dead Soft)

Annealed 301 is the softest, most ductile condition. The coil is solution-annealed at 1,010–1,150°C and rapidly cooled (water quenched) to dissolve all carbides and produce a fully austenitic, stress-free microstructure.

  • Cold reduction: 0% (fully annealed after cold rolling)

  • Typical use: Deep drawing, severe forming, welding

  • Magnetism: Essentially non-magnetic (permeability < 1.02)

  • Key advantage: Can be formed into complex shapes without cracking

1/4 Hard Temper

1/4 Hard is the first cold-worked temper, produced by approximately 20% cold reduction from the annealed condition. It offers a balance of increased strength with retained formability.

  • Cold reduction: ~20%

  • Typical use: Automotive trim, brackets, clips

  • Magnetism: Slightly magnetic

  • Key advantage: 67% higher tensile than annealed, still formable

1/4 Hard is the most popular temper for automotive stamping because it can be formed into complex shapes while providing enough dent resistance and structural rigidity.

1/2 Hard Temper

1/2 Hard results from approximately 40% cold reduction. At this temper, significant martensitic transformation has occurred, doubling the tensile strength compared to annealed.

  • Cold reduction: ~40%

  • Typical use: Springs, spring clips, battery contacts, EMI shielding

  • Magnetism: Moderately magnetic

  • Key advantage: The “sweet spot” for spring manufacturing

1/2 Hard is the most widely specified temper for spring applications. The yield strength of ≥ 760 MPa ensures springs maintain their loaded position, while 15% minimum elongation allows stamping without edge cracking.

3/4 Hard Temper

3/4 Hard is produced by approximately 60% cold reduction. The material is approaching its formability limit — bending requires generous radii and specialized tooling.

  • Cold reduction: ~60%

  • Typical use: High-strength springs, structural reinforcements

  • Magnetism: Noticeably magnetic

  • Key advantage: Yield strength ≥ 930 MPa in compact geometries

Full Hard Temper

Full Hard represents approximately 70% cold reduction — the maximum standard temper defined in ASTM A666. The material is at its peak strength but has minimal remaining ductility.

  • Cold reduction: ~70%

  • Typical use: Maximum-strength springs, reinforcement plates

  • Magnetism: Strongly magnetic

  • Key advantage: Tensile ≥ 1,275 MPa — more than double annealed

Extra Hard (Commercial Designation)

Extra Hard is a commercial designation beyond ASTM A666, produced by cold reduction exceeding 70%. It is not a standard ASTM temper but is available from specialized mills.

  • Cold reduction: >70% (mill-specific)

  • Typical use: Ultra-high-strength flat parts — no bending

  • Magnetism: Very strongly magnetic

  • Key advantage: Tensile up to ~1,850 MPa

Note: Extra Hard values are not guaranteed by ASTM A666 and should be confirmed with the mill test report for each heat.

301 Temper Mechanical Properties Comparison

The table below summarizes minimum mechanical properties for each temper per ASTM A666. These are minimum values — actual properties on your mill test certificate will typically be higher.

TemperCold ReductionTensile (MPa)Yield (MPa)Elong. (%)HVHRC (approx.)
Annealed0%≥ 515≥ 205≥ 40≤ 218— (≤ 92 HRB)
1/4 Hard~20%≥ 860≥ 510≥ 25250–300~25
1/2 Hard~40%≥ 1,030≥ 760≥ 15310–370~32
3/4 Hard~60%≥ 1,210≥ 930≥ 10370–430~37
Full Hard~70%≥ 1,275≥ 1,000≥ 5430–490~43
Extra Hard*>70%up to 1,850up to 1,450< 3≥ 500~48+

*Extra Hard is a commercial designation, not a standard ASTM A666 temper. Values are typical, not guaranteed.

Key observations:

  • From annealed to full hard, tensile strength increases by 147% (515 → 1,275 MPa)

  • From annealed to full hard, elongation decreases by 87% (40% → 5%)

  • The strength-to-ductility trade-off is predictable and linear

  • 1/2 Hard provides the best balance: 2× strength of annealed with 37.5% of the ductility

How to Choose the Right 301 Temper

Selecting the correct temper requires evaluating three factors: required strengthforming complexity, and service conditions.

Spring Manufacturing — 1/2 Hard to Full Hard

Springs must maintain their loaded position without permanent deformation. The critical property is yield strength.

  • Light-duty springs (battery contacts, clips): 1/2 Hard (YS ≥ 760 MPa)

  • Medium-duty springs (compression/extension springs): 3/4 Hard (YS ≥ 930 MPa)

  • Heavy-duty springs (high-load flat springs): Full Hard (YS ≥ 1,000 MPa)

For spring applications, specify the minimum yield strength on your purchase order, not just the temper designation.

Automotive Stamping — 1/4 Hard to 1/2 Hard

  • Simple shapes (flat brackets, panels): 1/2 Hard

  • Moderate complexity (trim, molding, channels): 1/4 Hard

  • Complex shapes (deep-drawn): Annealed, then re-tempered

1/4 Hard is the automotive industry standard — allows 180° bends at 1× thickness radius with 67% higher tensile than annealed.

Electronics and Precision Stamping — 1/2 Hard to 3/4 Hard

  • Battery contacts: 1/2 Hard, 0.2–0.3mm

  • Connector terminals: 3/4 Hard, 0.15–0.3mm

  • EMI shielding strips: 1/2 Hard, 0.1–0.2mm

  • Precision stamped springs: 3/4 Hard to Full Hard, 0.2–0.5mm

Aerospace Components — Full Hard (with full certification)

Aerospace demands maximum strength-to-weight with complete traceability. Requires EN 10204 3.2 MTC, heat number traceability, and PMI verification.

Railway and Transportation — 1/2 Hard to Full Hard

  • Car body panels: 1/2 Hard

  • Structural reinforcement: 3/4 Hard to Full Hard

  • Crash-absorbing structures: Full Hard

301 Temper Selection Chart

ApplicationTensile (MPa)Max Bend RadiusRecommended TemperThickness
Deep drawn parts515–700Flat (0°)Annealed0.5–2.0mm
Automotive trim, channels860–1,0001× T1/4 Hard0.5–1.5mm
Clips, light brackets1,030–1,1502× T1/2 Hard0.3–1.0mm
Battery contacts, EMI shielding1,030–1,2002× T1/2 Hard0.1–0.3mm
Compression springs, flat springs1,210–1,3503× T3/4 Hard0.5–2.0mm
High-load springs, fasteners1,275–1,4504× TFull Hard1.0–3.0mm
Ultra-high strength flat parts1,450–1,850No bendingExtra Hard1.0–3.0mm
Structural reinforcement1,275+4× TFull Hard1.5–3.0mm
Precision electronic contacts1,210–1,3503× T3/4 Hard0.15–0.5mm
Aerospace brackets1,275+4× TFull Hard0.5–2.0mm

Formability and Bend Radius by Temper

TemperMin Bend Radius (ASTM A666)Practical RecommendationForming Notes
Annealed0× T (180° flat)Deep draw, stretch formMaximum formability
1/4 Hard1× T (90°)Safe for most stampingGood for trim, brackets
1/2 Hard2× T (90°)Proper tooling clearanceSuitable for spring shapes
3/4 Hard3× T (90°)Carbide toolingLimited forming; avoid sharp radii
Full Hard4× T (90°)Pre-cut when possibleMinimal forming; cracks if over-bent
Extra HardNot recommendedFlat strip onlyCracks at any bend

Bend direction matters: Bending perpendicular to the rolling direction provides better formability. For 1/2 Hard and harder, always specify grain direction on engineering drawings.

301 Temper and Magnetic Properties

TemperPermeability (μ)Martensite (approx.)Magnetic?
Annealed< 1.02< 5%Essentially non-magnetic
1/4 Hard1.02 – 3.010–25%Slightly magnetic
1/2 Hard3.0 – 1530–50%Moderately magnetic
3/4 Hard15 – 4050–70%Noticeably magnetic
Full Hard40 – 8070–85%Strongly magnetic
Extra Hard> 80> 85%Very strongly magnetic

Why this matters:

  • Quality verification: If 1/2 Hard 301 is not at least slightly magnetic, it may not have received adequate cold reduction

  • Application restrictions: Non-magnetic applications (MRI, sensors) require annealed 301 or 304/316L

  • Inspection: PMI guns can detect martensite content to verify correct temper

This magnetic transformation is normal and expected — it is not a quality defect. It is a direct result of the work-hardening mechanism that gives 301 its exceptional strength.

301 vs 304 vs 17-7 PH — High-Strength Alternatives

Property301 (Full Hard)304 (Cold Worked)17-7 PH (TH1050)
Max tensile strength~1,275 (1,850 Extra Hard)~1,100 MPa~1,450 MPa
Temper standardASTM A666ASTM A666AMS 5529
Hardening mechanismStrain-induced martensiteDislocation densityPrecipitation hardening
Formability at max strengthLimited (4× T bend)Very limitedGood (form annealed, then age)
Corrosion resistanceModerate (16–18% Cr)Good (18–20% Cr)Good (16–18% Cr)
CostLow (less Ni)MediumHigh

When to choose 301: High strength from cold rolling without heat treatment, cost-sensitive applications, wide strength range from single grade.

When to choose 304: Corrosion resistance more important than max strength, non-magnetic requirement. See our 304 cold rolled stainless steel coil page.

When to choose 17-7 PH: High strength AND complex formability, can accommodate heat treatment, aerospace springs. See our Precipitation Hardening Stainless Steel

Heat Treatment and Annealing of 301

Solution Annealing

  • Temperature: 1,010–1,150°C (1,850–2,100°F)

  • Atmosphere: Hydrogen or vacuum (bright anneal); air (standard)

  • Cooling: Rapid water quench or fast forced-air cool

  • Result: Fully austenitic, hardness ≤ 92 HRB

Critical: Cooling must be rapid through 900–500°C. Slow cooling causes carbide precipitation (sensitization). See our 316/316L stainless steel page for sensitization details.

Stress Relief

  • Temperature: 350–425°C (660–800°F) for 1–2 hours, air cool

  • Result: 5–15% residual stress reduction, minimal strength change

  • Use: Precision springs and dimensional-critical parts

Cannot Harden by Heat Treatment

301 cannot be hardened by heat treatment (quench and temper). Unlike martensitic grades (410, 420, 440C), 301’s strength comes exclusively from cold working. Heating above 425°C progressively softens it as martensite reverts to austenite.

301 Coil Specifications by Temper

ParameterSpecification
GradeAISI 301 / UNS S30100 / EN 1.4310 / JIS SUS301
StandardASTM A666
TemperAnnealed / 1/4 Hard / 1/2 Hard / 3/4 Hard / Full Hard / Extra Hard
Thickness0.2mm – 3.0mm
Width600mm – 1,500mm (standard: 1000, 1219, 1250, 1500mm)
Coil ID508mm (20″) or 610mm (24″)
Surface Finish2B (standard), 2D, BA (annealed only)
TolerancePer ASTM A480M
CertificationEN 10204 3.1 MTC (standard), 3.2 (third-party)

Quality Inspection for 301 Temper Material

InspectionStandardPurpose
Tensile TestASTM E8Verify TS, YS, elongation per A666
Hardness TestASTM E18 / E92Fastest temper verification
Chemical AnalysisASTM E1019 / E1086Verify 301 chemistry (Cr 16–18%, Ni 6–8%)
Bend TestASTM E290Verify formability per temper
PMIXRF verify grade (not 304/201)
Magnetic PermeabilityASTM A342Verify martensite content vs temper

Practical tip: A quick hardness test is the fastest way to verify temper on incoming material.

Standards and Equivalent Grades for 301

StandardDesignationTemper Standard
AISI (USA)301ASTM A666
UNS (USA)S30100ASTM A666
EN (Europe)1.4310EN 10088-2 (C700/C850/C1000/C1150)
DIN (Germany)X12CrNi17-7SEW 390
JIS (Japan)SUS 301JIS G4305
GB (China)06Cr17Ni7GB/T 3280
BS (UK)301S21BS 1449 Part 2
ISOX5CrNi17-7ISO 9444

European temper equivalents (EN 10088-2):

ASTM A666 TemperEN 10088-2Approx. Rp (MPa)
Annealed1.4310 annealed≥ 230
1/4 HardC700≥ 700
1/2 HardC850≥ 850
3/4 HardC1000≥ 1,000
Full HardC1150≥ 1,150

For detailed international standards comparison, see our blog: ASTM A240 vs EN 10088 vs JIS G4304 Standards Comparison

Buying 301 Temper Coil: MOQ, Lead Time, Certification

ParameterDetail
MOQ1 Ton (samples negotiable)
Lead Time (stock)7–15 days
Lead Time (production)25–35 days
PaymentT/T (30% deposit, 70% before shipment); L/C 
IncotermsFOB Shanghai / CIF / CFR / DAP / EXW
MTCEN 10204 3.1 (free), 3.2 (SGS/BV/TÜV)
REACH/RoHSAvailable for European buyers
C/OAvailable for preferential tariff
HS Code7219.34.00 (<1mm, ≥600mm); 7219.24.00 (1–3mm); 7220.20.00 (<600mm)
Response TimeWithin 12 hours
WhatsApp+86-13761906384

Frequently Asked Questions: 301 Stainless Steel Temper Guide

Conclusion

301 stainless steel’s temper range — from annealed (515 MPa) to full hard (1,275 MPa) and beyond — gives engineers and buyers an unmatched strength spectrum from a single grade. The key to successful 301 specification is matching the temper to your application:

  • Need maximum formability? Choose Annealed

  • Need formability + strength? Choose 1/4 Hard

  • Need spring performance? Choose 1/2 Hard

  • Need maximum strength? Choose 3/4 Hard or Full Hard

Always specify temper by ASTM A666 designation (not colloquial terms), require EN 10204 3.1 MTC with actual mechanical values, and verify incoming material with a hardness test.

Huaxiao Metal supplies 301 cold rolled coil in all ASTM A666 temper conditions from 0.2mm to 3.0mm, with full mill certification and 12-hour response time.

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