MS. KATARZYNA BANDZIERZPROF. DARIUSZ BIELIŃSKI

Lodz University of Technology, Poland

Radiation methods of polymer modification:

Hybride crosslinking of butadiene – acrylonitrile rubber

Ionizing radiation

Any kind of radiation (electromagnetic, corposcular or mixture of both), which carry enough energy to break chemical bonds,separate electrons from parent atoms and molecules – cause ionization of irradiated matter.

Ionizing radiation - ENERGYSecondary electron

-

Ionizing radiation

Radiation engineering – involves practical application of chemical reactions (and biological and physcical processes) initiated with ioniznig radiation.

Any kind of radiation (electromagnetic, corposcular or mixtureof both), which carry enough energy to break chemical bonds, separate electrons from parent atoms and molecules – cause ionization of irradiated matter.

Ionizing radiation - ENERGYSecondary electron

-

Electron beam (EB) as a form of ionizing radiation

Electron accelerator Elektronica ELU-6E(Institute of Applied Radiation Chemistry, Lodz University of Technology)

Operating pulpit and control cabinet of electron accelarator

Linear electron accelerator

Radiation modification of polymers

curing of surface layers leading to surface modification

grafting (of bulk material or surface)

chain-scissioning for recycling purposes

crosslinking of polymer materials (including heat-shrink products and hydrogels)

… and many others

Crosslinking of polymers

Radiation crosslinking – scheme

Crosslinking – process of forming bonds (crosslinks) between macromolecules’ chains, which leads to three-dimentional polymer network.

Crosslinking is fundamental and indispensable process in polymer processing !

Advantages of radiation crosslinking

Simplicity to control network density Irradiation process can be carried out in room temperature

(or either lower or higher), in air or another medium of choice (e. g. inert gas atmosphere)

Comparing to products crosslinked ‘classically’ – thermally, general improvement of properties occurs

Radiation crosslinking do not create residual stress in material (as thermal crosslinking do)

The method is fast, efficient and inexpensive, defined as “green process”

Author’s own research

Results – crosslinking of nitrile rubber

*

CH2

CH

CH

CH2

CH2

CH *

N

n

m

C

2,2 10∙ -4 [mol/cm3]

Network density of sample crosslinked solely thermally:

material composition: NBR (100 phr), MBTS (1,5 phr), S8 (2 phr), ZnO (5 phr), stearic acid (1 phr), silica Aerosil A380 (40 phr)

Density of network as a function of ionizing radiation dose

Results – mechanical properties of composite

200 kGy 250 kGy

material composition: NBR (100 phr), MBTS (1,5 phr), S8 (2 phr), ZnO (5 phr), stearic acid (1 phr), silica Aerosil A380 (40 phr)

Results – hybride structure of crosslinks

100 kGy 150 kGy 200 kGy 250 kGy

material composition: NBR (100 phr), MBTS (1,5 phr), S8 (2 phr), ZnO (5 phr), stearic acid (1 phr), silica Aerosil A380 (40 phr)

Summary

Radiation modyfication of polymers (including radiation crosslinking) is highly useful method to enhance properties of polymers

The radiation modification can be run under precise control, so that properties can be ‘tailord’ for specific end-use of material

Results of autors’ research show that upon radiation crosslinking of nitrile rubber, hybride network structure can be obtained and the general properties of such material are better than of ‘classically’ – thermaly crosslinked

The process of radiation crosslinking of nitrile rubber is a promising alternative for up-till-now used method of thermal crosslinking and can be used in industry

THANK YOU FOR YOUR ATTENTION

Contact: katarzyna.bandzierz@gmail.com

MS. Katarzyna BandzierzInstitute of Polymer and Dye

TechnologyFaculty of Chemistry

Lodz University of Technology, Poland