PEEK vs PEK vs PTFE: Key Differences, Properties & Selection Guide
PPEK (polyphthalate ether ketone), PEK (polyether ketone), and PTFE (polytetrafluoroethylene) are three high-performance polymers that serve demanding applications requiring elevated temperature resistance, chemical inertness, or exceptional tribological properties. While all three operate at temperatures beyond most engineering plastics, they differ significantly in mechanical performance, processing characteristics, and cost. Understanding these differences enables informed material selection for the aerospace, semiconductor, chemical processing, and oil and gas industries. For companies seeking high-performance polymer testing at a US-based testing lab, Infinita Lab provides comprehensive polymer characterization through its accredited laboratory network.
Property Comparison
PEK (Polyether Ketone)
PEK has a higher melting point (373°C) and glass transition temperature (165°C) than PEEK (343°C, 143°C), providing approximately 20–30°C higher continuous use temperature. PEK offers superior creep resistance and mechanical properties at elevated temperatures, making it preferred for the most demanding aerospace and oil and gas applications.
PPEK (Polyphthalate Ether Ketone)
PPEK is an amorphous polyketone with excellent dimensional stability, transparency, and toughness. Its amorphous structure provides uniform properties in all directions (isotropy) and better dimensional control than semi-crystalline PEEK or PEK, advantageous for precision semiconductor and electronics applications.
PTFE (Polytetrafluoroethylene)
PTFE provides the lowest coefficient of friction (0.05–0.10) of any solid material, exceptional chemical resistance to virtually all chemicals, and continuous use temperature up to 260°C. However, PTFE has significantly lower mechanical strength and modulus than polyketones and cannot be melt-processed by conventional methods.
Testing Methods
All three polymers are characterized using ASTM D638 (tensile), ASTM D790 (flexural), ASTM D648 (HDT), ASTM D3418 (DSC thermal transitions), ASTM E1131 (TGA stability), and ASTM D1894 or ASTM G99 for friction and wear characterization.
Infinita Lab: Your Material Testing Partner
Contact Infinita Lab for Polymer Testing and enjoy major benefits like end-to-end testing management, faster turnaround, and reduced administrative burden. Gain confidence in accurate results and reduced stress in vendor coordination. Enhance your reputation for product reliability and innovation. Engineers and R&D managers can focus on core work rather than testing logistics.
Looking for a trusted partner to achieve your research goals? Schedule a meeting with us, send us a request, or call us at (888) 878-3090 to learn more about our services and how we can support you. Request a Quote
Frequently Asked Questions (FAQs)
What is the main difference between PEK and PEEK? PEK has a higher melting point (373°C vs 343°C) and higher Tg (165°C vs 143°C) than PEEK, providing superior high-temperature performance. PEK costs more and is less widely available than PEEK.
When should PTFE be chosen over polyketones? Choose PTFE when the lowest possible friction coefficient, universal chemical resistance, or non-stick properties are the primary requirements and mechanical load-bearing is secondary, such as seals, linings, and bearings in the chemical processing industry.
What makes PPEK different from PEEK? PPEK is amorphous (versus semi-crystalline PEEK), providing superior dimensional stability, optical clarity, and isotropic properties. PEEK offers higher mechanical strength and chemical resistance due to its crystalline structure.
Can these polymers replace metals? PEK and PEEK frequently replace steel, aluminum, and titanium in aerospace, medical, and oil and gas applications, offering 60–70% weight savings with adequate strength. PTFE replaces metals primarily in chemical processing for corrosion resistance.
What testing verifies high-performance polymer selection? Tensile testing (ASTM D638), HDT (ASTM D648), DSC (ASTM D3418), TGA (ASTM E1131), friction/wear testing, and chemical resistance immersion testing (ASTM D543) verify that the selected polymer meets application requirements.
