Oxidation and Aging of Polymers

Understand, evaluate, and optimize the long-term stability of polymeric materials under real-world operating conditions

Throughout their entire service life, polymers are exposed to various environmental factors. Temperature, oxygen, UV radiation, moisture, and mechanical stress can lead to aging processes that alter the material’s properties and performance over the long term.

The study of oxidation and aging processes is therefore an essential part of materials development and quality assurance. Modern analytical methods make it possible to evaluate stability, service life, and resistance to aging, as well as to develop high-performance, durable polymer materials.

LINSEIS’s material characterization solutions enable the early detection of aging processes and the targeted optimization of materials for demanding applications.

Typical Challenges Related to Oxidation and Aging

Relevant Questions

  • How does a polymer change during long-term thermal exposure?
  • What effect does oxygen have on material stability?
  • How does a polymer age under real-world conditions?
  • Which additives improve resistance to aging?
  • How does the oxidation stability change over the product’s service life?
  • What temperatures accelerate aging processes?
  • How does UV radiation affect material properties?
  • When do the first signs of degradation appear?
  • Which materials offer the highest long-term stability?
  • How can outages and equipment failures be prevented?


Relevant Material and Process Parameters

Parameter
Meaning
Oxidation Induction Time (OIT)Evaluation of Oxidation Resistance
Oxidation Induction Temperature (OIT)Temperature resistance to oxidation
Mass lossDetection of degradation processes
Thermal StabilityBehavior under long-term stress
Glass transition temperatureChanges in the material structure
Decomposition temperatureAssessment of Long-Term Stability
Aging BehaviorPrediction of Service Life
Residual stabilityEvaluation of Remaining Material Properties
Moisture AbsorptionImpact on Aging Processes
UV ResistanceLong-term performance in outdoor use

Test Methods for Thermal Insulation Materials

Differential Scanning Calorimetry (DSC)

DSC enables the determination of the oxidation induction time (OIT) and the oxidation induction temperature (OIT), two of the most important parameters for evaluating the aging resistance of polymers.

Analysis of

  • Oxidation Induction Time (OIT)
  • Oxidation Induction Temperature (OOT)
  • Glass transitions
  • Aging Behavior

Typical Applications

  • Polyolefins
  • Packaging Materials
  • Pipes
  • Cable Insulation

Thermogravimetry (TGA)

The TGA examines decomposition and oxidation processes under controlled conditions.

Analysis of

  • Mass loss
  • Thermal Stability
  • Oxidation
  • Mining

Typical Applications

  • High-Performance Polymers
  • Elastomers
  • Engineering Plastics
  • Composite Materials

Simultaneous Thermal Analysis (STA)

STA combines heat flux and mass change analysis to provide a comprehensive investigation of aging and degradation processes.

Analysis of

  • Oxidation
  • Mining
  • Reactivity
  • Thermal Stability

Typical Applications

  • Polymer compounds
  • Composite Materials
  • High-temperature polymers
  • Specialty Plastics

Gas Analysis (EGA)

Coupled gas analysis identifies gases released during aging and decomposition processes.

Analysis of

  • Metabolites
  • Oxidizing gases
  • Reaction Mechanisms
  • Material degradation

Typical Applications

  • Aging Studies
  • Fire Behavior
  • Quality Control
  • Research and Development

Recommended Instruments for Oxidation and Aging

Case Study: Analysis of the Oxidation Stability of a Polymer Material

Thermal Stability of Naturally Aged PVC Formulations

This practical example shows how the Linseis STA L81 is used to investigate the aging and degradation behavior of PVC formulations. The measurements provide important information about thermal stability, degradation processes, and the long-term durability of polymeric materials under real-world environmental conditions.

Why Analyzing Oxidation and Aging Is Crucial

Aging processes affect the mechanical, thermal, and chemical properties of polymer materials. Even minor changes in the material structure can lead to embrittlement, discoloration, loss of strength, or a reduced service life.

The combination of modern measurement methods makes it possible to:

  • Analysis of Oxidative Aging Processes
  • Determination of Oxidation Stability
  • Assessment of Thermal Stress Resistance
  • Study of Material Degradation
  • Optimization of Formulations and Additives
  • Prediction of Long-Term Behavior and Service Life

Applications – Polymers

FAQ – Oxidation and Aging

Why is it important to study oxidation and aging in polymers?

Oxidation and aging have a significant impact on a material’s service life and performance. Early analysis can help prevent material damage and enable products to be specifically optimized for long-term applications.

The oxidation induction time describes the time interval until the onset of a measurable oxidation reaction under defined conditions. It is an important parameter for evaluating the aging resistance of polymers.

DSC, TGA, STA, TMA, and coupled gas analyses provide important information about oxidative stability, degradation, material breakdown, and changes in material structure.

The most important factors include temperature, oxygen, UV radiation, humidity, chemical agents, and mechanical stress. Often, several factors act simultaneously and accelerate material aging.

Aging tests allow for the evaluation of new materials and additives under accelerated conditions. This makes it possible to predict service life and improve materials in a targeted manner.

These studies are particularly important in the automotive, electronics, construction, medical technology, packaging, energy, and aerospace industries, where long-term material reliability is crucial.