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New Developments in Ionomer Technology for Film Applications

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Title: New Developments in Ionomer Technology for Film Applications


1
New Developments in Ionomer Technology for Film
Applications
  • Barry Morris
  • DuPont Packaging and Industrial Polymers

2
Acknowledgements
  • Dave Walsh
  • Karlheinz Hausmann
  • John Chen
  • David Londono
  • Donna Visioli

3
Discussion Outline
  • Ethylene Ionomer Introduction
  • New Antistatic Ionomer
  • Background
  • Film Results
  • New Highly Permeable Ionomers
  • Novel ionomer technology
  • Novel ionomer performance capabilities
  • Morphological studies and modeling
  • Conclusions

4
Ethylene Ionomer Introduction
  • Partially neutralized ethylene co-polymers
    containing carboxylic acid
  • E/AA or E/MAA
  • neutralized with Na, Zn, etc.
  • Thermally reversible network structure
  • Crystals
  • Ionic crosslinks
  • Amorphous regions

5
Characteristic Ionomer MorphologyNetwork per
Ionic Domains and Crystallites
6
Ethylene Ionomer Performance Characteristics
  • low seal initiation temperature
  • broad hot tack strength
  • High melt strength and formability
  • oil and grease resistance/ seal around
    contamination
  • high stiffness (for a sealant resin)
  • outstanding toughness and puncture resistance
  • optical clarity and high gloss
  • high abrasion resistance
  • excellent chemical resistance
  • high resilience and cut resistance (golf balls)

7
Traditional Ionomer Design Parameters
  • Acid copolymer base resin
  • MI
  • acid level
  • acid type
  • Termonomers (e.g. acrylate)
  • Architecture (small extent)
  • Neutralizing cation
  • neutralization

8
Antistats
9
Surface Resistance Spectrum
1016
Insulating
Polymers
1014
1012
Chemical Antistatic Compounds
1010
Dissipative
IDP Compounds
108
Surface Resistivity, W/sq.
106
104
Carbon powders and fibers based compounds
Conductive
102
10
Highly Conductive
EMI Compounds (carbon and metal fibers)
10-2
10-4
Metals
10-6
10
Antistatic Ionomer
  • Polyolefins are prone to static build-up
  • Electrical insulator
  • Do not readily pick up moisture
  • Susceptible to dust accumulation, static
    discharge, etc.
  • Methods used to reduce static build-up
  • Antistatic additives
  • Conductive fillers
  • Antistatic coatings

11
Current Types of Antistatic Additives
  • Blooming
  • Come to surface during processing
  • 1 2 added
  • Low cost
  • Most do not work well at low RH
  • Wear off with time
  • May cause problems with delamination/adhesion
  • Permanent
  • Added at 10-30 levels
  • Usually work at low RH
  • Do not wear off
  • Can cause processing and aesthetics problems
  • May yellow upon aging

12
Potassium Ionomers as Antistats
  • Permanent type does not wear off
  • Effective immediately (no blooming time)
  • Compatible with polyolefins minimum change in
    optical properties
  • Non-yellowing
  • FDA compliant for direct food contact
  • Effective at 30 RH and higher

13
Blends with PE
Similar results were found for PP cast films
14
Blown film
15
Static Decay
16
Highly Permeable Ionomers
17
Novel Ionomers Through Fatty Acid Salt
Modification
  • Mg Stearate used in the present study
  • Novel performance capability for packaging
    applications
  • Increased gas permeability
  • Performance balance between breathability and
    stiffness
  • Thermoplastic processibility
  • Cast or blown film, Monolayer or multilayer coex
  • Thermoformable

18
Comparable modulus, much higher OTR
19
Typical Heat Seal Strength Conventional
Ionomers vs. Novel Ionomers
Seal strength at 135 C,g/15 mm
20
Higher modulus at comparable OTR
21
Fundamental Study of Ionic Morphology
  • SAXS analysis
  • Liquid-like ionic domain modeling
  • Thermal analysis (DSC)
  • Primary and secondary ethylenic crystallites
  • WAXS analysis
  • Formation of small stearate crystals
  • Proposed ionomer morphology changes
  • Origin of performance enhancement

22
SAXS Analysis of Novel Ionomers
Significant increase in the population of ionic
domains in MgSt modified ionomers
23
SAXS Analysis For Morphology Study
Bimodal distribution in domain size and increase
in number density of domains
24
DSC Analysis of Modified Ionomer
Ethylenic crystallinity reduced by MgSt
modification
25
WAXS Analysis of Stearate Crystallinity Formation
Additional crystalline phase is developed by MgSt
modification
26
ConclusionsOrigin of Performance Enhancement
  • Ionic morphology refinement and enhancement
  • Substantial increase in ionic domain population
  • Suppressed ethylenic crystallinity
  • Enhanced network structure leads to
  • Higher gas permeability
  • Stiffness decreased by reduction in primary
    crystallinity, increased by enhanced network
    structure
  • Lower heat seal strength

27
ConclusionsGraphical Representation of
Ionomer Morphology Changes
Fine secondary crystals are included in the
morphology
28
Summary
  • Ionomers have a unique combination of attributes
    for film applications
  • New attributes continue to be developed
  • The potassium cation creates antistatic
    functionality for blending with polyolefins
  • Fatty acid salt modification creates new
    morphologies
  • Breathabilty with stiffness

29
Thank You.
Questions?
Barry Morris DuPont Packaging Industrial
Polymers
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