PET vs PEN, LCP, PTFE/fluoropolymers, and specialty films like PEI/PEEK: when each wins, where each struggles, and what it means for manufacturing
Polyimide is the baseline substrate for most flex circuits because it offers a strong mix of heat tolerance, mechanical durability, and manufacturability. But some flex designs have requirements that push beyond what “standard PI” optimizes for, such as tighter thermal budgets, higher-frequency performance targets, very low moisture sensitivity, unusual chemical exposure, or aggressive cost constraints.
This guide is a substrate-focused deep dive into four families that commonly come up when engineers evaluate alternatives to polyimide:
• PET vs PEN for cost-driven and moderate-temperature designs
• LCP for moisture stability and RF/mmWave suitability
• PTFE / fluoropolymer constructions for low-loss electrical performance (with important manufacturing tradeoffs)
• Specialty films (PEI, PEEK, and others) when extreme requirements justify higher cost and tighter constraints
The goal is not to “pick a winner,” but to clarify the tradeoffs so substrate selection supports reliability, signal performance, and buildability.
PET and PEN are often discussed together because they canenable cost-effective flex designs when the use case does not require the higher temperature capability typically associated with polyimide. They are most often evaluated in applications that are static or lightly flexed and where process temperature limits are well understood.
• PET (Polyethylene Terephthalate): widely used film known for cost efficiency and availability in high-volume applications.
• PEN (Polyethylene Naphthalate): similar class of polymer film with generally improved thermal behavior and dimensional stability
compared with PET, often at higher cost.
PET is typically considered when:
• The primary driver is cost and high-volume scalability
• The design is static flex (minimal bending cycles) or very light motion
• Thermal Exposure is moderate and controlled across assembly and field use
• The Design benefits from broad availability and simpler sourcing
• Electrical performance requirements are basic (low frequency, low voltage, no high-impedance control)
Common application patterns:
• Consumer electronics interconnects (e.g.,TV remote controls, basic wearable bands), simple flex jumpers in white goods, disposable medical device electronics, and designs where the electrical demands are moderate and the environment is well characterized
PEN is often evaluated when PET is close to acceptable, but risk remains:
• Higher Thermal headroom needed than PET can comfortably support (e.g., reflow soldering up to 180°C, continuous operating temperature up to 120°C)
• Better dimensional stability needed for improved registration and feature consistency (critical for fine-pitch flex circuits with line/space <50μm)
• A modest cost increase is acceptable to reduce thermal or process risk
• Light dynamic flex cycles are required, with minimal bending radius
Common application patterns:
• Higher-performance consumer electronics, designs with slightly higher thermal exposure, and projects where PET has caused yield or stability issues.
• If assembly or operating temperature pushes limits, PEN is often a safer step-up from PET.
• If registration stability impacts yield, PEN may offer better behavior.
• If the application is static and cost-driven with conservative thermal conditions, PET can be appropriate.
• For designs with light dynamic flex requirements, PEN is preferred over PET, as its improved mechanical rigidity reduces fatigue and extends flex cycle life.
• Always validate thermal performance with the substrate supplier: PET and PEN grades vary by manufacturer, with some high-performance PET grades offering near-PEN thermal behavior and some low-cost PEN grades underperforming relative to premium PET.
LCP (Liquid Crystal Polymer) is frequently evaluated when designs become sensitive to moisture-driven drift or when high-frequency performance is part of the requirement set. Its appeal is often tied to a combination of stable electrical behavior and strong moisture performance.
LCP is often discussed in the context of RF designs because it can support high-frequency use cases where stable electrical characteristics and low loss are priorities. LCP has a low, stable Dk (2.8-3.2 at 10GHz) and an ultra-low Df (<0.003 at 10GHz), which minimizes signal loss and attenuation at high frequencies—critical for 5G/6G communication, radar systems, and satellite communications. Unlike PI (Df ~0.008 at 10GHz) or fluoropolymers (which offer low loss but poor flexibility), LCP delivers low-loss performance without sacrificing the mechanical flexibility that defines flex circuits. It also supports tight impedance control (±5% or better) for high-frequency transmission lines onlines, a requirement for RF/mmWave designs that PI struggles to meet consistently.
Moisture can shift dielectric behavior and reduce insulation stability over time. LCP is commonly considered when moisture sensitivity must be minimized to protect electrical performance and long-term reliability. LCP has ultra-low moisture absorption (<0.03% by weight), a level that is an order of magnitude lower than PI (~0.3%) and PET/PEN (~0.4%). This near-zero moisture sensitivity eliminates moisture-driven electrical drift and significantly improves long-term reliability in humid environments (e.g., outdoorIoT sensors, marine electronics, medical implants) or hermetic enclosures where trapped moisture can cause corrosion. For designs that require hermetic sealing or operate in 85% RH+ environments, LCP is the only flex substrate material that can eliminate moisture-related performance degradation without additional coating or encapsulation.
Stable geometry supports consistent impedance and repeatable performance, especially when feature tolerances tighten. LCP has exceptional dimensional stability (CTE <10 ppm/°C in the in-plane direction), far superior to PI(CTE ~20-30 ppm/°C) and PET/PEN (CTE ~60-80 ppm/°C). This ultra-low CTE minimizes thermal warpage during fabrication and field use, ensuring consistent geometry for flex circuits with fine-pitch features (line/space <25μm) and tight tolerance requirements. Stable geometry directly supports consistent impedance and repeatable high-frequency performance—especially critical when feature tolerances tighten for miniaturized RF/mmWave designs. LCP’s dimensional stability also improves manufacturing yield for multi-layer flex circuits, as it reduces misalignment between layers during lamination.
• RF interconnects, antenna structures, and electronics where humidity stability and high-frequency behavior are important selection drivers
LCP is rarely a simple “swap” for polyimide constructions.When evaluating it, plan for:
• Different Handling and lamination behavior than standard PI builds.
• Stack-up and bonding approaches that can affect yield at yield and reliability.
• Cost and lead-time differences compared with more common materials.
• Early DFM alignment on process capability for the full construction.
Practical checkpoint: If LCP is selected for RF performance, confirm that the entire construction (geometry control, copper behavior, bondlayers, and thickness tolerances) supports the electrical targets. A substrate choice cannot compensate for inconsistent build control.
PTFE and related fluoropolymer constructions are strongly associated with low-loss electrical performance in RF applications. In flex,they can be technically compelling, but the decision is often shaped by manufacturing constraints and DFM limits as much as electrical performance.
They are typically evaluated when:
• Low loss at high frequency is a primary requirement
• Electrical performance is mission-critical and justifies added complexity
• Alternative materials cannot meet the signal budget
• The design is a low-volume, high-value application (e.g., aerospace prototypes, defense systems) where cost and lead time are secondary to performance
• The flex circuit has minimal flexibility requirements: fluoropolymers are stiffer than PI and LCP, making them unsuitable for tight bending radius or dynamic flex cycles
• Strong low-loss potential for demanding RF and high-frequency interconnect needs
• Chemical inert (resistant to virtually all acids, bases, and solvents) and high continuous operating temperatures for harsh chemical and high-temperature environments
• Ultra-low moisture absorption
• Excellent dielectric strength for high-voltage flex circuit designs
• Manufacturing complexity: fluoropolymer processing can be less forgiving than common PI-based builds
• Cost: material and fabrication costs are typically higher
• Tighter design rules: routing density and stack-up options may be constrained
• Supply chain limitations: fewer sourcing options and longer lead times can be common
• Limited mechanical flexibility: suited for semi-rigid or static flex circuits with minimal motion requirements
Practical checkpoint: PTFE can be the right technical answer, but it usually demands earlier DFM work, tighter process control, and realistic planning for iteration during prototype builds.
Specialty films enter the selection conversation when requirements move into territories like higher temperature exposure, chemical resistance, unusual mechanical constraints, or high consequence-of-failure environments where materials are chosen for margin, not just adequacy.
Typical drivers include:
• Elevated operating temperatures or frequent thermal cycling
• Chemical exposure or aggressive cleaning environments
• Mechanical durability beyond common constructions
• Reliability requirements where failure cost is high
• Biocompatibility requirements
Specialty films can offer advantages depending on the specific polymer and construction:
• Better tolerance to harsher environments
• Stronger long-term stability under demanding thermal or chemical conditions
• Unique mechanical behavior that better suits the application constraints
• Certifiable performance
• Combined performance benefits
Specialty films often carry higher total program cost because of:
• Higher raw material cost compared with PET/PEN/PI
• More complex processing and tighter manufacturing windows
• Limited sourcing options and longer lead times
• Increased qualification and validation burden to prove performance
Practical checkpoint: Specialty films are best justified by a clear requirement. If the benefit is “nice to have,” the lead-time and cost penalties often outweigh the value.
Use this to narrow the field before deeper stack-up work:
• Cost-driven, moderate thermal exposure, static/light-flex designs: start with PET; consider PEN when thermal or stability risk appears.
• Better dimensional stability and more thermal headroom than PET: consider PEN.
• RF/mmWave performance + moisture stability priorities: evaluate LCP early.
• Low-loss electrical performance with higher build complexity accepted: evaluate PTFE/fluoropolymer constructions and align DFM immediately.
• Extreme temperature or chemical environment, high consequence-of-failure: explore PEI/PEEK or specialty films with a defined validation plan.
Moving beyond polyimide is rarely about novelty. It is about matching the substrate family to the real constraints of the design: thermal exposure, frequency performance, moisture sensitivity, manufacturability, and supply-chain risk.
A strong selection process starts with requirements and ends with a realistic plan for DFM and qualification. If the substrate choice improves electrical or environmental performance but introduces unmanageable manufacturing constraints, the program cost often rises more than expected.