PEEK (Polyetheretherketone) for FDM

2026年4月29日

Material Profile: PEEK (Polyetheretherketone) for FDM

FDM Engineering Material Technical Report Series

Compiled from manufacturer technical datasheets and peer-reviewed literature

Abstract—PEEK is the canonical ultra-high-performance thermoplastic for additive manufacturing — a semi-crystalline polyaryletherketone with continuous service to 240 °C, intrinsic UL 94 V-0 flammability, exceptional resistance to virtually all chemicals, and mechanical properties comparable to aluminum on a stiffness-to-weight basis. PEEK is used in aerospace, medical implants, oil-and-gas downhole tools, and semiconductor processing. Stratasys VICTREX AM™ 200 is AS9100 aerospace-certified.

Index Terms—additive manufacturing, FDM, PEEK, PAEK, ultra-high-performance polymer, aerospace, medical.

I. MATERIAL IDENTIFICATION

This section establishes the canonical names and commercial designations under which the material is supplied.

A. Designation

Trade name: PEEK (generic). Examples: Stratasys VICTREX AM™ 200, 3DXTech ThermaX™ PEEK, 3D4Makers PEEK (Victrex 151G base), 3DGence PEEK.

B. Full Chemical Name

Poly(oxy-1,4-phenyleneoxy-1,4-phenylenecarbonyl-1,4-phenylene), CAS 31694-16-3 — a member of the polyaryletherketone (PAEK) family with two ether and one ketone linkage per repeat unit.

C. Aliases and Alternative Designations

Alias	Origin / Usage
PEEK	Standard generic name
VICTREX AM™ 200	Stratasys / Victrex grade for additive manufacturing
ThermaX™ PEEK	3DXTech grade
PolyEtherEtherKetone	Full chemical name

II. COMPOSITION AND MOLECULAR STRUCTURE

A. Empirical Chemical Formula

[-O-C₆H₄-O-C₆H₄-CO-C₆H₄-]ₙ; empirical (C₁₉H₁₂O₃)ₙ.

Fig. 1. Repeating unit / structural schematic of the polymer matrix.

Fig. 2. Schematic of the single-phase polymer (no reinforcement).

B. Composition Breakdown

TABLE I
COMPOSITIONAL BREAKDOWN OF PEEK (TYPICAL / PER SUPPLIER DATASHEET)

Constituent	Mass fraction	Function
Poly(ether-ether-ketone)	≈ 99 wt%	Single-phase semi-crystalline thermoplastic
Process additives, crystal modifiers	< 1 wt%	AM-grade PEEK is optimised at the molecular level for printability
Total	100 wt%	—

III. MECHANICAL PROPERTIES — XZ PRINT DIRECTION

In the XZ orientation the tensile load is applied parallel to the deposited rasters; for fibre-reinforced grades this is the strongest orientation because the fibres align preferentially along the extrusion direction.

TABLE II
MECHANICAL PROPERTIES — XZ ORIENTATION (PEEK)

Property	Value (XZ)	Test method / source
Tensile strength, ultimate	≈ 95 – 105 MPa (post-anneal)	ASTM D638; literature (Victrex AM 200 ≈ 100 MPa)
Tensile strength, yield	≈ 90 MPa (estimate)	Engineering estimate
Elastic limit	~ 3 % strain (estimate)	Engineering estimate
Young's modulus	≈ 3.5 – 4.0 GPa	ASTM D638
Elongation at break	≈ 20 – 30 % (post-anneal)	ASTM D638
Izod impact, notched (23 °C)	≈ 60 J/m	ASTM D256

IV. MECHANICAL PROPERTIES — ZX PRINT DIRECTION

In the ZX orientation the tensile load is applied perpendicular to the print layers, so failure occurs through inter-layer (Z) bonds. Properties are markedly lower than in XZ — this anisotropy is intrinsic to FDM.

TABLE III
MECHANICAL PROPERTIES — ZX ORIENTATION (PEEK)

Property	Value (ZX)	Test method / source
Tensile strength, ultimate	≈ 60 MPa (estimate, post-anneal)	Engineering estimate
Tensile strength, yield	≈ 55 MPa (estimate)	Engineering estimate
Elastic limit	~ 2.5 % strain (estimate)	Engineering estimate
Young's modulus	≈ 3.0 GPa (estimate)	Engineering estimate
Elongation at break	≈ 5 – 10 % (estimate)	Engineering estimate
Izod impact, notched (23 °C)	≈ 25 J/m (estimate)	Engineering estimate

Estimated XZ:ZX UTS ratio ≈ 1.7:1 — among the lowest of FDM polymers, because PEEK's high inherent strength and post-anneal fusion of layer interfaces partially heal print-line discontinuities. Annealing is essential to achieve the property values quoted above.

V. RECOMMENDED PRINT PARAMETERS

Values summarised below give consensus operating windows from public datasheets. Specific suppliers may differ within ±10 °C; the supplier datasheet always supersedes this table.

TABLE IV
RECOMMENDED PRINT TEMPERATURE RANGES FOR PEEK

Parameter	Range	Notes
Nozzle temperature	350 – 440 °C	All-metal hardened nozzle; high-temperature hot-end required
Build plate temperature	120 – 160 °C	PEI; PEEK-coated bed preferred
Chamber temperature	Active 90 – 160 °C (mandatory)	Critical to control crystallisation and prevent layer cracking
Pre-print drying	120 – 150 °C × 6 – 12 h	Mandatory; moisture causes severe extrusion defects

VI. GLASS TRANSITION TEMPERATURE (TG)

Reported / typical Tg: ≈ 143 – 145 °C.

Above Tg, PEEK's amorphous regions are rubbery, but the crystalline phase (typically 30–35% after anneal) maintains mechanical integrity to near the melting point (~343 °C). Annealing 200 °C × 1–2 h followed by slow cooling is essential.

VII. HEAT DEFLECTION TEMPERATURE (HDT)

Heat deflection temperature is the temperature at which a standard bar deflects 0.25 mm under a specified flexural load (ASTM D648 / ISO 75).

TABLE V
HEAT DEFLECTION TEMPERATURE OF PEEK UNDER STANDARD TEST LOADS

Test load	HDT	Standard / source
0.45 MPa	≈ 305 °C (post-anneal, Victrex literature)	ASTM D648
1.82 MPa	≈ 152 °C (un-annealed) / 320 °C (semi-crystalline post-anneal)	ASTM D648; demonstrates the criticality of annealing

VIII. DISTINGUISHING CHARACTERISTICS AND STANDARDS

A. Multi-domain certifications

Stratasys VICTREX AM™ 200 carries AS9100 (Aerospace Quality Management System) certification. Standard PEEK is biocompatible per ISO 10993, accepting USP Class VI use; sterilisable by autoclave (134 °C × 30 min), gamma irradiation, and ethylene oxide; and is listed in ASTM F2026 (PEEK for surgical implants). UL 94 V-0 is intrinsic.

B. Universal chemical and thermal resistance

PEEK is essentially insoluble in any common solvent and resistant to all hydrocarbon fuels, hydraulic fluids, and de-icers; acids; alkalis. Continuous service to 240 °C; short-term excursions to 310 °C; melting point 343 °C.

C. Mechanical and fatigue resistance

Among the most fatigue-resistant thermoplastics — used for high-cycle parts in jet engines, oil-and-gas downhole tools, and orthopaedic implants. Wear and creep resistance are exceptional.

D. Print difficulty

PEEK is the most difficult conventional FDM polymer to print successfully. Active heated chamber (90–160 °C), nozzle temperatures > 350 °C, post-print annealing, and meticulous moisture control are all mandatory. Capital cost is high (typical industrial PEEK printer > USD 50k).

IX. REPRESENTATIVE APPLICATIONS

PEEK is typically deployed in the following applications:

1) Aerospace flight-rated brackets: Lightweight cabin and engine-bay structural fittings; FST + chemical compliance.

(Source : Stratasys)

2) Medical implants and surgical instruments: Spinal cages (FDA-cleared as ISO 10993 / USP Class VI), trauma fixation, sterilisable instrument handles.

3) Oil-and-gas downhole tools: Seals, bearings, instrumentation parts in 200 °C / 70 MPa downhole environments.

4) Semiconductor manufacturing equipment: Wafer carriers, end-effectors that must not contaminate or out-gas at process temperatures.

5) Automotive racing / motorsport: High-temperature engine and brake-system components.

Photographs of representative parts in these applications are not reproduced here for copyright reasons; the table below provides direct manufacturer / case-study URLs where original imagery and project descriptions can be viewed.

TABLE VI
SUGGESTED IMAGE / CASE-STUDY SOURCES

Application area	Source URL
PEEK aerospace cabin bracket	https://www.stratasys.com/en/materials/materials-catalog/fdm-materials/victrex-am-200-peek/
PEEK medical / orthopaedic implant	https://www.3dxtech.com/collections/peek