Technical GuideTechnical reference – RF & microwave interconnect21 June 2026

RF Cables for Vacuum Applications

Low-outgassing, vented, and high-stability RF cable assemblies for vacuum chambers, TVAC systems, semiconductor tools, space simulation, particle accelerators, and high-frequency research environments.

In vacuum, RF cable selection is no longer only about frequency, insertion loss, and connector type. Outgassing, trapped volumes, bake-out, thermal cycling, radiation, magnetic compatibility, and RF discharge risk can all affect system reliability.

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For TVAC, UHV, semiconductor, space simulation, particle accelerator, detector, and microwave research systems.

Low Outgassing

Material selection must consider ASTM E595, TML, CVCM, WVR, contamination risk, and clean handling.

Vacuum-Compatible Connectors

Vented connectors, hermetic feedthroughs, low-outgassing insulators, and trapped-volume control are critical.

RF Stability

Insertion loss, return loss, shielding, and phase stability must remain reliable under vacuum and temperature cycling.

Special Environments

High RF power, multipaction, radiation exposure, and magnetic compatibility may influence cable and connector selection.

Why Vacuum Applications Are Special

Vacuum is not simply air removed from the environment. It changes how materials behave, how heat is managed, how gases are released from cable materials, and how RF connectors perform over time. A cable assembly that works perfectly on a bench can become a contamination source, a thermal problem, or a reliability risk once it is placed under vacuum.

Outgassing and contamination

No convection cooling

Trapped air in connectors

Bake-out and thermal cycling

RF discharge risk

Material documentation required

Vacuum Level Definitions

Vacuum requirements are not all the same. A cable that is acceptable for one vacuum level may not be suitable for another.

Vacuum Type	Approximate Range	Why It Matters for Cables
Low / Rough Vacuum	Atmosphere to approx. 1 mTorr	Basic material compatibility and pump-down behavior
High Vacuum (HV)	Approx. 10⁻³ to 10⁻⁶ Torr	Outgassing, cleanliness, and trapped-volume control become critical
Ultra-High Vacuum (UHV)	Typically below 10⁻⁹ Torr	Strict material selection, bake-out compatibility, and contamination control
Thermal Vacuum (TVAC)	High vacuum with temperature cycling	RF stability must be verified under pressure and temperature stress

ASTM E595 Low-Outgassing Criteria

For vacuum and space-related applications, ASTM E595 is one of the most widely referenced outgassing test methods. It measures how much mass a material loses in vacuum and how much of that released material condenses on a collector surface.

Parameter	Meaning	Typical Limit
TML	Total Mass Loss	≤ 1.0%
CVCM	Collected Volatile Condensable Material	≤ 0.10%
WVR	Water Vapor Regained	≤ 0.10% where required

Passing ASTM E595 does not automatically qualify a full cable assembly for every vacuum system, but it is an important starting point for screening cable dielectrics, jackets, heat shrink, adhesives, labels, connector materials, and other assembly components.

What Makes a Vacuum-Compatible RF Cable Different?

Dielectric

PTFE, FEP, PFA, ETFE, PEEK, and polyimide-based materials may be considered depending on RF performance, temperature, radiation, and outgassing requirements.

Jacket and Heat Shrink

Standard PVC, rubber, labels, and unqualified heat shrink should usually be avoided inside vacuum unless tested and approved.

Inner Conductor

Silver-plated copper is common. For demanding UHV, space, radiation, or high-reliability environments, conductor material and plating should be reviewed.

Shielding

Shielding must provide stable RF performance, low leakage, mechanical reliability, and compatibility with cleaning and handling requirements.

Cleanliness

Vacuum cable assemblies may require controlled cleaning, cleanroom handling, double-bag packaging, and material documentation.

Documentation

Material declarations, ASTM E595 data, bake-out records, and customer-approved materials lists may be required.

Cable Materials to Consider

PTFE

PTFE is widely used as a microwave cable dielectric because of its excellent electrical properties, low dielectric constant, low loss, and high temperature resistance. It is a strong candidate for many RF and microwave vacuum applications. However, in particle accelerators, space systems, nuclear environments, and applications with significant ionizing radiation, PTFE can degrade over time and become more brittle. For radiation-heavy applications, the cable material must be selected for vacuum and RF performance as well as radiation resistance.

FEP and PFA

FEP and PFA are often used for jackets, outer insulation, or heat shrink in vacuum-compatible cable assemblies. They provide good chemical resistance and thermal performance while helping reduce outgassing compared with many standard plastics.

ETFE

ETFE can be useful where mechanical toughness, abrasion resistance, lower weight, and improved radiation performance are important. It may be considered for certain space, aerospace, accelerator, and industrial vacuum applications.

PEEK

PEEK is often used in high-performance connector and mechanical components where strength, temperature resistance, and vacuum compatibility are needed. It can also be attractive in applications where radiation resistance is important.

Polyimide

Polyimide materials may be considered in some high-temperature, vacuum, aerospace, and radiation-sensitive environments. Suitability depends on the exact construction, outgassing performance, dielectric requirements, and mechanical design.

Inner Conductor Material

The inner conductor is also important in vacuum RF cable design. Many RF coaxial cables use silver-plated copper conductors because they offer good conductivity and stable RF performance. For demanding vacuum, UHV, space, or radiation-sensitive environments, silver-plated OFHC copper or gold-plated conductors may be considered. At elevated bake-out temperatures or in very sensitive UHV systems, conductor plating, diffusion, oxidation behavior, and material compatibility should be checked with the cable manufacturer.

Connector Selection Is Critical in Vacuum RF Systems

Vented RF connector — the small vent hole (arrow) allows trapped gas to escape during pump-down, preventing trapped-volume problems inside the vacuum chamber

Vented RF Connectors

Vented connectors allow trapped gas to escape during pump-down and reduce trapped-volume risks.

Low-Outgassing Insulators

Connector dielectrics and support materials should be vacuum-compatible. PTFE, PEEK, and other qualified materials are common choices.

Hermetic Feedthroughs

When an RF signal must pass through a chamber wall, a hermetic coaxial feedthrough helps maintain chamber integrity.

Non-Magnetic Connectors

For particle accelerators, detectors, MRI-adjacent systems, quantum systems, and sensitive instruments, non-magnetic or low-magnetic-permeability connectors may be required.

Correct Frequency Interface

Type-N, SMA, 3.5 mm, 2.92 mm, 2.4 mm, 1.85 mm, or 1.0 mm connectors should be selected based on frequency, power, and measurement requirements.

Torque and Repeatability

High-frequency connectors require correct mating torque to avoid damage, poor return loss, and reduced repeatability.

Special Risks in Vacuum RF Applications

Multipaction and RF Discharge

At higher RF power levels in vacuum, multipaction can occur when RF fields accelerate electrons between closely spaced conductive surfaces. This is especially relevant for satellite payloads, radar systems, high-power microwave feedthroughs, and TVAC testing.

Radiation Effects

For particle accelerators, space systems, and nuclear research, ionizing radiation can degrade polymers. PTFE can become brittle under high radiation dose, so ETFE, PEEK, or polyimide may be considered.

Magnetic Compatibility

Standard stainless steel, spring contacts, clips, and plated materials may be weakly magnetic. Non-magnetic connectors may be required near sensitive magnets, detectors, or magnetic-field sensors.

Bake-Out Exposure

Typical vacuum assembly bake-out may be in the range of 80 to 150 degrees C for 24 to 48 hours, depending on the system and the weakest material in the assembly.

When Do You Need to Test RF Cables in Vacuum?

Not every RF cable used near a vacuum system must be tested inside vacuum. If the cable remains outside the chamber and only connects to an external feedthrough, standard RF testing may be enough. But when the cable assembly is installed inside the vacuum chamber, vacuum testing becomes highly recommended.

1
The cable is installed inside the vacuum chamber
2
The application is high vacuum, ultra-high vacuum, or TVAC
3
Bake-out is required
4
Contamination can damage wafers, optics, sensors, mirrors, detectors, or chamber surfaces
5
RF insertion loss, return loss, shielding, or phase stability must remain stable under operating conditions
6
The cable will be used in TVAC or space simulation testing
7
Connectors or feedthroughs contain possible trapped volumes
8
RF power is high enough to create discharge or multipaction concerns
9
Radiation exposure is part of the environment
10
Magnetic compatibility is required
11
Customer approval, material data, or formal documentation is required

Common Mistakes in Vacuum RF Cable Selection

Using a standard RF cable inside a vacuum chamber because it works well on the bench

Ignoring heat shrink, labels, adhesives, boots, ink marking, potting, or other small accessories

Forgetting bake-out and thermal cycling requirements

Assuming that good vacuum performance also means good radiation performance

Ignoring magnetic compatibility near sensitive instruments

Ignoring connector venting and trapped-volume risk

Ignoring multipaction and discharge risk in high-power RF vacuum systems

Recommended Specification Checklist

Low-outgassing cable construction

ASTM E595 data where required

TML ≤ 1.0%, CVCM ≤ 0.10%, WVR ≤ 0.10% material screening targets where applicable

Fluoropolymer, PEEK, ETFE, or polyimide materials as appropriate

Radiation-compatible material selection when required

Suitable inner conductor material and plating

Conductor plating review for bake-out, UHV, corrosion, and radiation environments

Vacuum-compatible heat shrink or no heat shrink where possible

Vented RF connectors for the vacuum side

Hermetic RF feedthroughs for chamber-wall transitions

Non-magnetic or low-magnetic-permeability connectors where required

Defined frequency and return-loss requirements

Defined insertion-loss limits

Defined RF power limits

Multipaction or discharge review for high-power vacuum RF applications

Temperature and bake-out compatibility

Cleaning and packaging requirements

Material compliance documentation when needed

Phase stability requirements for precision RF measurement or TVAC testing

Need Help Selecting a Vacuum-Compatible RF Cable?

Choosing the right RF cable for vacuum applications requires more than frequency and connector matching. Material selection, outgassing, vented connectors, hermetic feedthroughs, bake-out, radiation, magnetic compatibility, RF power, and phase stability should all be reviewed before integration.

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Full Technical Article

Introduction: Why RF Cable Selection Changes in Vacuum

When an RF cable assembly is placed inside a vacuum chamber, it enters an environment that is fundamentally different from anything it was likely designed for when its RF and mechanical specifications were established. Vacuum changes the behavior of materials, the dissipation of heat, the risk of contamination, and the long-term reliability of connector interfaces. A cable that performs perfectly in ambient air can create real problems inside a vacuum system.

This guide covers the key factors that must be considered when selecting RF cables for vacuum applications: outgassing and contamination control, material selection, connector design, bake-out compatibility, RF discharge risk, radiation effects, magnetic compatibility, and documentation requirements.

What Is Outgassing and Why Does It Matter?

Outgassing refers to the release of gases trapped or dissolved in solid materials when those materials are exposed to vacuum. Every solid material outgasses to some degree. Metals, ceramics, and most fluoropolymers outgas at rates low enough that they are acceptable even in demanding vacuum systems. However, standard cable jacket materials — including many grades of PVC, polyethylene, polyurethane, rubber, and foam — can release significant amounts of gas in vacuum. Labels, adhesives, inks, heat shrink materials, potting compounds, and boot adhesives are also potential sources of outgassing.

In high and ultra-high vacuum systems, outgassing from cable materials can degrade vacuum quality, increase pump-down time, and potentially contaminate nearby optical surfaces, wafers, mirror coatings, sensor windows, detector elements, or precision instrument surfaces. For space simulation and TVAC testing, outgassing materials can deposit residue on the spacecraft hardware being tested, which may affect measurements or cause real contamination of optical and sensitive surfaces.

ASTM E595 and Other Outgassing Test Methods

The ASTM E595 test method measures the outgassing of solid materials in vacuum using three parameters: Total Mass Loss (TML), Collected Volatile Condensable Material (CVCM), and Water Vapor Regained (WVR). A material that passes ASTM E595 screening — typically TML no more than 1.0 percent and CVCM no more than 0.10 percent — is considered acceptable for many space and vacuum applications as a starting point.

However, ASTM E595 data for a dielectric or jacket material does not automatically qualify the complete cable assembly. Heat shrink tubing, adhesives, labels, ink marking, boots, and assembly process residues must all be evaluated. For strict vacuum or space applications, a full assembly outgassing evaluation may be required.

Fluoropolymers in Vacuum RF Cables

Fluoropolymer materials — including PTFE, FEP, PFA, and ETFE — are widely used in vacuum-compatible RF cable assemblies because of their combination of low outgassing, chemical inertness, temperature stability, and, in the case of PTFE, excellent RF dielectric properties. PTFE in particular has a very low dielectric constant and very low dielectric loss, making it the most common choice for precision microwave cable dielectrics. FEP and PFA are often preferred for jackets because they can be extruded over cable constructions more easily than PTFE while still providing low outgassing and chemical resistance.

ETFE (ethylene tetrafluoroethylene) offers better mechanical toughness than PTFE or FEP and better radiation resistance. This makes it useful for environments that combine vacuum with radiation exposure, such as particle accelerators and some space systems. PEEK (polyether ether ketone) is not a fluoropolymer but is used in vacuum-compatible connector insulators and mechanical components because of its strength, temperature resistance, and vacuum compatibility.

Connector Design for Vacuum Applications

In vacuum systems, the connector is often the most important component to review after the cable dielectric. Standard RF connectors were not designed specifically for vacuum use. Several issues can arise:

Trapped volumes inside connector bodies can slow pump-down and require careful venting. Connector insulators made from materials with higher outgassing rates can contaminate the chamber. Non-magnetic requirements may not be met by standard connectors. Bake-out requirements may exceed the rated temperature of standard connector bodies or insulators.

Vented RF connectors address the trapped-volume problem by providing a design pathway for gas to escape. Hermetic feedthroughs are used when an RF signal must enter or exit a vacuum chamber through the chamber wall: a hermetic coaxial feedthrough maintains the vacuum boundary while passing the RF signal at the required frequency and power level.

Bake-Out Compatibility

Most high-vacuum and ultra-high vacuum systems require bake-out — a controlled heating of the vacuum chamber and all internal components to elevated temperature — to drive off surface-adsorbed gases and achieve low base pressure. Cable assemblies installed inside the chamber must be able to withstand the bake-out cycle without damage, without significant additional outgassing at the bake-out temperature, and without degradation of RF performance after cooling back to operating temperature.

Typical bake-out conditions range from approximately 80 degrees C to 150 degrees C for periods of 24 to 48 hours, depending on the vacuum system type, the cleanliness requirements, and the materials involved. The weakest material in any cable assembly sets the maximum allowable bake-out temperature for the assembly as a whole. A cable assembly where the cable body is rated to 200 degrees C but the heat shrink or boot adhesive is only rated to 80 degrees C may fail or outgas heavily if baked above 80 degrees C.

RF Discharge and Multipaction in Vacuum

At higher RF power levels in vacuum, a phenomenon called multipaction (sometimes spelled multipactor) can occur. Multipaction is an RF discharge caused by resonant electron multiplication between closely spaced conductive surfaces in a vacuum. As the RF field accelerates electrons across a gap, secondary electrons are emitted from the conductor surfaces, and if the geometry and frequency are in the right range, these secondary electrons can be re-accelerated in phase with the RF field, leading to an exponential increase in electron current that can cause signal distortion, heating, and even arc damage.

Multipaction is especially relevant in satellite payloads, high-power radar systems, and high-power microwave feedthroughs for plasma or accelerator applications. For TVAC testing of satellite hardware, the RF power levels used in testing can bring multipaction into play. The risk depends on frequency, gap dimensions, conductor material, and surface condition — factors that are usually analyzed by RF simulation for critical designs. Cable assemblies used in high-power vacuum RF applications should be reviewed for multipaction risk as part of the system design.

Radiation Effects on Cable Materials

In particle accelerators, space environments, nuclear research facilities, and radiological measurement applications, the cable materials must also be evaluated for radiation resistance. Ionizing radiation — including gamma, X-ray, neutron, and charged-particle radiation — can degrade polymer materials over time. PTFE is particularly susceptible to radiation-induced embrittlement. Under sufficient accumulated radiation dose, PTFE can lose mechanical flexibility, crack, and fail. This makes PTFE a poor choice for cables that will be located in high-radiation zones in accelerators or nuclear research environments, even if its RF and vacuum properties are otherwise excellent.

ETFE has significantly better radiation resistance than PTFE and is often preferred for cables in radiation environments. PEEK also has better radiation resistance than PTFE. Polyimide can be suitable for very high-temperature or very high-radiation environments.

Magnetic Compatibility

In particle physics detectors, MRI-adjacent test systems, magnetometer calibration facilities, and some quantum computing experimental setups, the magnetic properties of cable and connector materials can affect measurements. Standard RF connectors often contain stainless steel components, spring contacts, or ferromagnetic plating materials that can disturb sensitive magnetic field environments. Non-magnetic connector variants, typically using beryllium-copper or brass body materials with non-magnetic plating, may be required for these applications.

When magnetic compatibility is a requirement, the entire cable assembly — including the cable braid material, the inner conductor material, any shield termination clips, and all connector components — should be reviewed for magnetic permeability.

Junkosha RF Cable Assemblies for Vacuum Applications

Junkosha manufactures precision RF and microwave cable assemblies using PTFE-based and fluoropolymer dielectric constructions that are suitable starting points for vacuum applications. The EMF series phase-stable cable assemblies use expanded PTFE (ePTFE) tape-wrapped dielectric constructions, which provide excellent RF phase stability under temperature cycling — a critical requirement for TVAC testing where the cable assembly must maintain consistent RF transmission characteristics as the temperature cycles between hot and cold conditions.

For specific TVAC, space simulation, UHV, or particle accelerator applications, the cable assembly materials, cleaning procedures, heat shrink selection, connector choice, and documentation requirements should be discussed with Koto Electronics technical support to ensure the selected assembly meets the full system requirements.

Summary

RF cables for vacuum applications require a significantly more detailed review than RF cables selected only for frequency, power, and connector type. The key parameters to evaluate include: cable dielectric and jacket material outgassing, ASTM E595 or equivalent data for critical applications, connector design for vacuum including vented or hermetic types, bake-out compatibility of the full assembly, RF performance stability under temperature cycling, RF discharge and multipaction review for high-power applications, radiation resistance for particle accelerator and space environments, magnetic compatibility for magnetically sensitive systems, cleanliness and handling requirements, and material documentation appropriate for the application.

Sources and Technical References

Frequently Asked Questions

What makes an RF cable vacuum-compatible?

A vacuum-compatible RF cable must use suitable low-outgassing materials, compatible dielectrics and jackets, appropriate connector materials, vented connector designs where needed, clean handling, and documentation such as ASTM E595 data when required.

Do all RF cables inside a vacuum chamber need ASTM E595 data?

Not always, but for space, TVAC, UHV, semiconductor, and contamination-sensitive applications, ASTM E595 data is often requested as part of material screening.

What is the difference between a vented RF connector and a standard RF connector?

A vented RF connector includes a design path that allows trapped gas to escape during pump-down. This helps reduce trapped-volume risk and can improve reliability in vacuum environments.

When should I use a hermetic RF feedthrough?

A hermetic RF feedthrough should be used when an RF signal must pass through a vacuum chamber wall while maintaining the pressure boundary between atmosphere and vacuum.

Can standard SMA or Type-N connectors be used in vacuum?

Sometimes, but the connector must be evaluated for material compatibility, venting, insulator material, plating, bake-out, power level, and vacuum conditions. A standard connector selected only by frequency may not be suitable.

Why is multipaction important in vacuum RF systems?

Multipaction is an RF discharge effect that can occur in vacuum at higher RF power levels. It is especially important in satellite payloads, high-power RF systems, radar, and TVAC testing.

Why is magnetic compatibility important for RF vacuum cables?

In accelerators, detector physics, MRI-adjacent systems, quantum systems, and other magnetically sensitive environments, weakly magnetic connector materials may disturb measurements or interact with nearby magnetic fields.

Do RF cables behave differently in vacuum than in air?

Yes. Vacuum changes heat dissipation, outgassing behavior, contamination risk, and sometimes RF performance under temperature cycling. RF cables used inside vacuum should be evaluated as part of the vacuum system.

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