polymers

Review

Polymerization Reactions and Modifications of
Polymers by Ionizing Radiation

Aiysha Ashfaq 1,†, Marie-Claude Clochard 2,†, Xavier Coqueret 3,† , Clelia Dispenza 4,5,†,
Mark S. Driscoll 6,7,†, Piotr Ulański 8,† and Mohamad Al-Sheikhly 9,*,†

1 Department of Chemistry and Biochemistry, University of Maryland, College Park, MD 20742, USA;
aiysha@umd.edu

2 Laboratoire des Solides Irradiés, CEA/DRF/IRAMIS-CNRS- Ecole Polytechnique UMR 7642,
Institut Polytechnique de Paris, 91128 Palaiseau, France; marie-claude.clochard@polytechnique.edu

3 Institut de Chimie Moléculaire de Reims, CNRS UMR 7312, Université de Reims Champagne-Ardenne,
BP 1039, 51687 Reims CEDEX 2, France; xavier.coqueret@univ-reims.fr

4 Dipartimento di Ingegneria, Università degli Studi di Palermo, Viale delle Scienze 6, 90128 Palermo, Italy;
clelia.dispenza@unipa.it

5 Istituto di BioFisica, Consiglio Nazionale delle Ricerche, Via U. La Malfa 153, 90146 Palermo, Italy
6 Department of Chemistry, State University of New York College of Environmental Science and Forestry,

Syracuse, NY 13210, USA; mdriscol@esf.edu
7 UV/EB Technology Center, State University of New York College of Environmental Science and Forestry,

Syracuse, NY 13210, USA
8 Institute of Applied Radiation Chemistry, Faculty of Chemistry, Lodz University of Technology,

Wroblewskiego 15, 93-590 Lodz, Poland; piotr.ulanski@p.lodz.pl
9 Department of Materials Science and Engineering, University of Maryland, College Park, MD 20742, USA
* Correspondence: mohamad@umd.edu; Tel.: +1-301-405-5214
† All authors have contributed equally to this review.

Received: 25 September 2020; Accepted: 23 November 2020; Published: 30 November 2020 ����������
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Abstract: Ionizing radiation has become the most effective way to modify natural and synthetic
polymers through crosslinking, degradation, and graft polymerization. This review will include
an in-depth analysis of radiation chemistry mechanisms and the kinetics of the radiation-induced
C-centered free radical, anion, and cation polymerization, and grafting. It also presents sections
on radiation modifications of synthetic and natural polymers. For decades, low linear energy
transfer (LLET) ionizing radiation, such as gamma rays, X-rays, and up to 10 MeV electron beams,
has been the primary tool to produce many products through polymerization reactions. Photons
and electrons interaction with polymers display various mechanisms. While the interactions of
gamma ray and X-ray photons are mainly through the photoelectric effect, Compton scattering,
and pair-production, the interactions of the high-energy electrons take place through coulombic
interactions. Despite the type of radiation used on materials, photons or high energy electrons,
in both cases ions and electrons are produced. The interactions between electrons and monomers
takes place within less than a nanosecond. Depending on the dose rate (dose is defined as the
absorbed radiation energy per unit mass), the kinetic chain length of the propagation can be controlled,
hence allowing for some control over the degree of polymerization. When polymers are submitted
to high-energy radiation in the bulk, contrasting behaviors are observed with a dominant effect
of cross-linking or chain scission, depending on the chemical nature and physical characteristics
of the material. Polymers in solution are subject to indirect effects resulting from the radiolysis of
the medium. Likewise, for radiation-induced polymerization, depending on the dose rate, the free
radicals generated on polymer chains can undergo various reactions, such as inter/intramolecular
combination or inter/intramolecular disproportionation, b-scission. These reactions lead to structural
or functional polymer modifications. In the presence of oxygen, playing on irradiation dose-rates,
one can favor crosslinking reactions or promotes degradations through oxidations. The competition

Polymers 2020, 12, 2877; doi:10.3390/polym12122877 www.mdpi.com/journal/polymers

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Polymers 2020, 12, 2877 2 of 67

between the crosslinking reactions of C-centered free radicals and their reactions with oxygen
is described through fundamental mechanism formalisms. The fundamentals of polymerization
reactions are herein presented to meet industrial needs for various polymer materials produced or
degraded by irradiation. Notably, the medical and industrial applications of polymers are endless
and thus it is vital to investigate the effects of sterilization dose and dose rate on various polymers and
copolymers with different molecular structures and morphologies. The presence or absence of various
functional groups, degree of crystallinity, irradiation temperature, etc. all greatly affect the radiation
chemistry of the irradiated polymers. Over the past decade, grafting new chemical functionalities
on solid polymers by radiation-induced polymerization (also called RIG for Radiation-Induced
Grafting) has been widely exploited to develop innovative materials in coherence with actual societal
expectations. These novel materials respond not only to health emergencies but also to carbon-free
energy needs (e.g., hydrogen fuel cells, piezoelectricity, etc.) and environmental concerns with the
development of numerous specific adsorbents of chemical hazards and pollutants. The modification
of polymers through RIG is durable as it covalently bonds the functional monomers. As radiation
penetration depths can be varied, this technique can be used to modify polymer surface or bulk.
The many parameters influencing RIG that control the yield of the grafting process are discussed
in this review. These include monomer reactivity, irradiation dose, solvent, presence of inhibitor
of homopolymerization, grafting temperature, etc. Today, the general knowledge of RIG can be
applied to any solid polymer and may predict, to some extent, the grafting location. A special
focus is on how ionizing radiation sources (ion and electron beams, UVs) may be chosen or mixed
to combine both solid polymer nanostructuration and RIG. LLET ionizing radiation has also been
extensively used to synthesize hydrogel and nanogel for drug delivery systems and other advanced
applications. In particular, nanogels can either be produced by radiation-induced polymerization
and simultaneous crosslinking of hydrophilic monomers in “nanocompartments”, i.e., within the
aqueous phase of inverse micelles, or by intramolecular crosslinking of suitable water-soluble
polymers. The radiolytically produced oxidizing species from water, •OH radicals, can easily abstract
H-atoms from the backbone of the dissolved polymers (or can add to the unsaturated bonds) leading
to the formation of C-centered radicals. These C-centered free radicals can undergo two main
competitive reactions; intramolecular and intermolecular crosslinking. When produced by electron
beam irradiation, higher temperatures, dose rates within the pulse, and pulse repetition rates favour
intramolecular crosslinking over intermolecular crosslinking, thus enabling a better control of particle
size and size distribution. For other water-soluble biopolymers such as polysaccharides, proteins,
DNA and RNA, the abstraction of H atoms or the addition to the unsaturation by •OH can lead to
the direct scission of the backbone, double, or single strand breaks of these polymers.

Keywords: radiation induced polymerization; ionizing radiation; radiation synthesis nanogels;
radiation induced grafting; radiation of natural polymers

1. Introduction

Throughout this review ionizing radiation and radiation is defined as photons or particles with
sufficient energy to ionize atoms and/or molecular segments of covalent compounds. The deposition
of the energy through columbic interactions (in the case of charged particles such as electron, proton,
and alpha particles), and in the case of high-energy photons (through Compton scattering, photoelectric,
and pair production), takes place in approximately 10−18 to 10−12 s. During this period, localized
ionized and excited molecules are formed along the tracks. Most of the chemical reactions take place
from 10−12 to 10−1 s. Usually, the biological processes start one second after the interaction.

There is a huge body of literature on the effects of ionizing radiation such as gamma rays from
Co-60, high-energy electron from electron beam accelerators, and X-rays on the polymeric materials and



Polymers 2020, 12, 2877 3 of 67

composites [1–10]. For the last four to five decades, a wealth of knowledge on the effects of the radiation
dose (energy per unit mass) of ionizing radiation on polymeric materials has been accumulated.

1.1. Fundamental of Radiation Effects on Polymers

The interactions of gamma photons, X-rays, and high energy electrons with matters induce
ionizations leading to the formation of ions and expelled fast-moving electrons. While the interactions
of the Co-60 gamma rays and X-rays photons through mainly photelectric, Compton scattering,
and pair-production, the interactions of the high-energy electrons take place through coulombic
interactions. So, despite the types of irradiation of materials with photons or with electrons, both cases
produce ions and electrons. While the produced secondary and Compton, and photoelectric electrons
gives rise to more ionizations, the radiolytically produced ions undergo various chemical reactions,
mainly through deprotonation reactions leading to the formation of the C-centered radicals. Depending
on the dose-rate, presence of oxygen, and the presence of antioxidants, these free radicals undergo
various reactions. In the presence of oxygen, while the irradiation with high dose-rate such as X-rays
and electron beam enhance the crosslinking reactions of these free radicals, the irradiation with
low-dose, such as in the case of Co-60 gamma rays, promotes the degradation reactions through
oxidations. At a low dose rate, competition reactions are established between the crosslinking reactions
of these C-centered free radicals and their reactions with oxygen. The reaction of the C-centered free
radicals with molecular oxygen give rise to the formation of the corresponding peroxyl radicals. Finally,
these peroxyl radicals undergo various reactions leading to the degradation of the polymers.

1.2. The Complexity of the Chemical Structures of New Polymeric Materials Used in Advanced Technology

In present times, many new polymers have been used in advanced technology. The need to
investigate the effects of the radiation dose on them is vital. These polymers and copolymers contain
different molecular structures and morphologies and hence the radiation dose has different effects
on them. It has been known that the presence of quaternary carbon atoms, halogen atoms (in the
halogenated polymers), and C–O–C bonds on the backbone of the polymer chains, functional groups,
degree of crystallinity, and the presence of the oxygen, fillers, and antioxidants, have crucial effects on
the radiation chemistry of the irradiated polymers. While the absence of quaternary carbon atoms
enhances the crosslinking reactions such as in the case of polyethylene, their presence promotes the
scission along the backbone of the polymer chains leading to degradation. Also, the presence of
C–O–C bonds like in the case of cellulosic polymers materials, the radiation induces degradation
because of the scission of the O–O bonds and the production of the alkoxyl radicals. In addition to the
chemical structures, the ratio of crystallinity/amorphous also plays important roles in the radiation
effects of polymers. Remember that most of the radiation-induced reactions, such as crosslinking
and degradation, take place in the amorphous region of the polymers. However, H-hopping on the
backbone of the chain in the crystallinity region can occur. This allows for the gradual diffusion of the
free radicals towards amorphous zones where they can undergo bimolecular reactions.

2. Fundamental and Technological Aspects of Radiation-Induced Polymerization

Polymer synthesis is the art to produce macromolecules with specific features in terms of repeat
units, degree of polymerization, microstructure and topology, as well as a means to fabricate small
objects (nano- or micro- particles) and macroscopic three-dimensional networks. This can be achieved
either by a chain addition process or by step-growth polymerization [11]. Though most polymerization
reactions proceed by chemical reactions based on conventional initiation or catalysis combined with
thermal activation, alternative methods based on enzymatic or radiation-assisted processes exhibit
specific features that have been explored early in the history of synthetic polymers.

Ionizing radiation is a form of energy carried by high energy electromagnetic waves (gamma or
X-ray photons) by particles accelerated in an electric field (electrons, light ions, swift heavy ions (SHI)) or
by elementary particles emitted from unstable atomic nuclei (α or β− particles) [12]. Energy deposition



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occurs upon interaction with matter through a variety of extremely fast physical processes (time
span up to a few fs) that end up with a physio-chemical stage during which short-lived excited
species and chemical entities are generated, through a cascade process that is initially controlled by
nonhomogeneous kinetics. Then, the medium responds more homogeneously in the chemical stage
with solvated electrons and free radicals that exhibit longer lifetimes [13]. In-situ formation of such
reactive species can be utilized to initiate chain polymerization. The subsequent stages of the chain
process are, in principle, not directly affected by the ongoing radiolysis of the medium. Polymerization
essentially proceeds by a chain mechanism with free radical active centers, and in some specific cases
by ionic active centers generated at the end of the cascade processes of physical and chemical stages
following the interaction of high energy particles and photons with molecular substrates [14].

The early articles reporting on the discovery of radiation-initiated chain polymerization of simple
monomers date back to the year 1940 [7,15,16]. These studies were primarily conducted on styrene,
various vinyl derivatives, and some dienes to examine the effects of the monomer structure, the nature
of the solvent, and of irradiation conditions in terms of dose rate and of absorbed radiation dose.
The occurrence of ionic mechanisms was also evidenced during the late 1950s for particular monomers,
reaction media, and experimental conditions that could meet the demanding criteria of such reactions
being very sensitive to the presence of moisture and other impurities.

Though step-growth polymerization can be efficiently triggered by the generation of acidic or
basic catalysts via radiation-mediated processes, this possibility has not been studied extensively.
The few known examples are essentially based on UV-visible activation of photo-base and photo-acid
generators [17]. A case is found with thiol-ene polymerization that can be induced by electron beam
irradiation and also enters in this class of step-wise build-up of macromolecular materials [18,19].

Currently, radiation-induced chain polymerization continues to develop as an attractive alternative
to photo-initiated polymerization and UV-curing [20] in the perspective of advanced applications in
material science and technology. It has been used since the early 1980’s, on a continuously increasing
industrial scale, for curing thin layers of inks and coatings deposited on solid substrates (paper, plastic
films, wood panels, and metal foils) using low-energy electron beams. The accelerators typically
operate at a voltage between 80 and 500 kV with a strong beam current permitting short curing times
and high productivity on continuous industrial lines.

The increase in the scope of applications as well as the advent of more advanced analytical
methods and of dedicated irradiation equipment has fostered growing interest on a variety of new
scientific issues and technological perspectives. The status on the most significant results will be
discussed in this part of the review dedicated to polymerization. Another section is dedicated to
radiation-induced graft polymerization as a subtopic this review.

2.1. Specificities of Radiation-Initiated Polymerization

Radiation-initiated processes exhibit very unique features that can be exploited for the design of
basic investigations or for technological purposes:

2.1.1. Instantaneous Impact of Radiation Treatment

As radiation penetrates the substrate, almost instantaneously, the beam induces the desired
chemical processes. Thermal activation of chemical reactions is limited by heat transfer kinetics, and the
use of catalysts is dependent on mixing conditions. Continuous, fractionated, intermittent, or pulsed
irradiation can be applied to the substrate at a desired instant for inducing chemical reactions with a
high degree of temporal control.

This feature is exemplified by pulse radiolysis experiments using a high-energy radiation source
which allows to identify by time-resolved spectroscopic methods the nature and the concentration of
various transient species such as radical cations, anions, and radicals derived from monomers and
solvents, and to assess the kinetic parameters of their decay on timescales ranging from picoseconds to
seconds [21,22]. Using these techniques, considerable progress has been achieved in the understanding



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of initiation mechanisms and in the technological use of pulse irradiation for the control of material
properties [23,24].

In contrast, in the absence of any radiation stimulus, ink, paint, and resin formulations including
large amounts of very reactive monomers exhibit particularly long shelf-stability, which provides a
major technological advantage for the design of cure-on-command processes [25].

2.1.2. Spatial Control of Radiation-Induced Effects

Beam directing devices and masking systems allow for a spatial control of the response induced
within a substrate. 1D to 3D patterning can be achieved by localized polymerization at different
dimension scales. The resolution depends on physical factors associated with the precision of the
beam pathway and penetration, on the scattering effects of the cascading energy transfer processes,
and from the diffusion of the active chemical species that participate in the reaction. Three recent
works that tackle the challenges of nanometric resolution in radiation-polymerizable films can illustrate
this [26–28].

Cationic polymerization of the solid epoxy resin SU-8 has been successfully used to pattern organic
surfaces by electron beam lithography. Process parameters can be tuned to optimize the fabrication
process, in terms of spatial resolution and aspect ratio for the obtained pattern. The developed
technique allows for the fabrication of high-aspect ratio, surface bound nanostructures with heights
ranging from 100 to 4000 nm and with in-plane resolution below 100 nm. Direct writing on glass plates
as a transparent glass substrate is especially convenient for studying cell structures [29].

Irradiation of thin films of 4-vinyltriphenylamine with high-energy multiply charged Ag or
Os cations induces the solid-state polymerization and crosslinking of this monomer along the
ion trajectories, resulting in the formation of insoluble uniform nanowires with precise diameters.
Polymerization of this monomer in the track of the swift heavy ions proceeds quite efficiently
in comparison with crosslinking reaction of polymer layer treated under the same conditions.
Nanowires with a cross-section lower than 10 nm were obtained and characterized after dissolution by
chromatographic and spectroscopic methods to gain information on the free radical chemistry that
takes place during the process [26,27].

2.1.3. Random Energy Deposition

Energy deposition occurs at random as a function of the electron density in the atoms within
the irradiated substrate. Early physical events are therefore nonselective with respect to the specific
structure of the molecular assemblies interacting with radiation. This leads to low degrees of conversion,
the validity of the assumption that the stages of chain polymerization process that follow initiation are
not directly affected by the ongoing radiolysis of the medium. Larger contents in branched polymers
can be expected at high conversion, as a consequence of the radiolysis of the produced macromolecules
and subsequent initiation of a new kinetic chain starting from an activated repeat unit. Another
consequence is the possibility to induce graft polymerization from a molecular substrate in contact
with the monomer within the irradiated medium. This point is treated separately by another part of
this review [21].

The nonselective energy deposition process of ionizing radiation that penetrates deeply into
the reactive material is a significant advantage by comparison with the photochemical activation
by UV-visible sources of pigmented formulations and composites including fillers or fibers. This is
demonstrated by the capability to cure 3 cm-thick epoxy acrylate composites with about 66 wt % of
carbon fiber with a 10 MeV Linac accelerator [28].

Coreaction between the polymerizable matrix and a nanoparticulate organic filler due to the
nonselective activation by high energy radiation was recently evidenced for polyurethane acrylate
nanocomposite materials including 1 wt % of cellulose nanocrystals which exhibit, for similar degree
of conversion and glass transition temperature, a tensile strength twice as high for the electron beam
cured samples compared to the UV-cured ones [30].



Polymers 2020, 12, 2877 6 of 67

2.1.4. Decoupling of Primary Initiation Steps from Thermal Activation

Radiation processing allows decoupling initiation kinetics from the effects of temperature on the
induced chemical reactions, particularly on propagation and transfer reactions for polymer synthesis.
Fundamentally, thus overcoming a critical constraint in polymerizations involving thermally activated
initiators. Radiation-induced initiation, unlike chemical methods, generally generates reactive centers
at a constant rate. This makes it possible to follow polymerization kinetics under stationary and various
experimental conditions. Favorable conditions can thereby be achieved to ensure polymer chain
propagation with minimum transfer or elimination reactions, thus reducing the risks of chain branching.

This approach has been exploited to synthesize poly(vinyl iodide), a difficult case in the class of
simple halogenated polymers. Unlike other vinyl halides, vinyl iodide is quite unstable and undergoes
decomposition by the action of light and oxygen producing free iodine which acts as an inhibitor.
Poly(vinyl iodide) was prepared by radiation-initiated treatment of the monomer in various chlorinated
solvents and isolated as a white solid with an unprecedented degree of purity [31–33].

Another example of the benefits arising from the use of radiation-induced initiation as an additional
and versatile lever in polymer synthesis is found with butadiene and substituted analogues. These can
be polymerized by various mechanisms, cationic or free-radical, in bulk state, solution, or aqueous
emulsion with different kinetics and regioselectivities for monomer insertion, therefore with potential
control on the microstructure [34–36].

As initiating species are generated randomly and softly in the solid state, in particular with
X-rays and γ-radiation, it is relatively easy to polymerize conventional monomers in a variety
of inclusion compounds. Various substituted butadienes have been polymerized successfully
as clatrates in deoxycholic acid or thiourea crystal channels, yielding highly stereoregular
poly(2,3-dimethyl-1,3-butadiene) with 97% of 1,4-trans diene units and melting temperatures as
high as 272 ◦C [37–40]. Stereoselective polymerization of acrylonitrile also takes place in the canals of
crystallized urea with formation of isotactic poly(acrylonitrile) with controlled molecular weight [41,42].

2.2. Basic Aspects

Many basic aspects of radiation-initiated polymerization were established during the pioneering
period of this new domain of radiation chemistry by Williams, Hayashi, Okamura, Metz, Chapiro,
Machi, Stannett, and Charlesby, to name some of the most significant contributors [7,16,43,44].
Most conventional monomers have been studied both as bulk substrates in the liquid or in the solid
state, as well as in solution or in heterophase systems such as aqueous suspensions or emulsions.

In dilute monomer solution or in liquid heterogeneous systems, radiolysis of the solvent generally
drives the initiation process, whereas bulk monomers produce ionized species, i.e., radical cations,
and electronically excited species which produce in turn free radicals, by neutralization and by
monomolecular dissociation, directly or after charge recombination.

A simplified picture of the main stages of the complex mechanism leading to the initiating species
is presented in Scheme 1.

The fast electrons produced during the primary ionization of the substrate gradually lose their
energy during secondary acts thus causing the formation of numerous ions and electrons of high energy.
This primary electron e- is transformed into a thermalized electron e−th, i.e., in thermal equilibrium
with the medium. The thermal electron can be trapped by radical cations formed from monomers M•+

or from the solvent S•+ that are converted into electronically excited molecules with an energy excess
of 8–5 eV higher than the strength of covalent bonds in organic molecules (~3 eV). The molecule in a
dissociative excited state therefore decomposes into free radicals, some of which are able to initiate
the propagation. Energy deposition in some cases is not sufficient to induce ionization, the resulting
excited molecules M** can dissociate into free-radicals. The formation of M* and M** are estimated to
occur with similar probabilities [7].



Polymers 2020, 12, 2877 7 of 67
Polymers 2020, 12, x 7 of 69 

 
Scheme 1. Simplified description of radiation-initiated polymerization for monomer M in the bulk or 
dissolved in solvent S. Depending on the chemical nature of the monomer, the purity of the medium 
and on the reaction conditions, chain propagation is initiated by appropriate free radical or ionic ac-
tive centers. 

The fast electrons produced during the primary ionization of the substrate gradually lose their 
energy during secondary acts thus causing the formation of numerous ions and electrons of high 
energy. This primary electron e- is transformed into a thermalized electron e−th, i.e., in thermal equi-
librium with the medium. The thermal electron can be trapped by radical cations formed from mon-
omers M●+ or from the solvent S●+ that are converted into electronically excited molecules with an 
energy excess of 8–5 eV higher than the strength of covalent bonds in organic molecules (~3 eV). The 
molecule in a dissociative excited state therefore decomposes into free radicals, some of which are 
able to initiate the propagation. Energy deposition in some cases is not sufficient to induce ionization, 
the resulting excited molecules M** can dissociate into free-radicals. The formation of M* and M** 
are estimated to occur with similar probabilities [7]. 

Those free radicals will be subject to diffusion-controlled recombination, soon establishing a 
steady state concentration in the chemically homogeneous system. The specific case of acrylate mon-
omers that involve the reduction of the conjugated unsaturation by thermalized electrons will be 
discussed in the forthcoming section. The rate for the generation of radical cations by ionizing radia-
tion is considered to be two orders of magnitude lower than that of free-radical formation, but the 
recombination constants for ions (ion and counter-ion) are approximately two orders of magnitude 
higher than those for free radicals. The stationary concentration of ions can therefore be estimated to 
be about 100 times lower than that of free radicals [7]. Consequently, radiation polymerization pro-
ceeds mainly by a free-radical mechanism unless specific conditions are met. 

Introducing onium salts such as triaryl sulfonium or diaryl-iodonium associated with low nu-
cleophilicity counter-anion in the reaction medium allows generating strong acids and / or carbenium 
that can initiate cationic processes more efficiently [45–47]. 

2.2.1. Free Radical Polymerization 

Radiation-induced polymerization has been studied with many monomers irradiated as bulk 
liquids, in solution, aqueous suspension or emulsion, the gas and solid crystalline or glassy state, as 
for other methods of initiation (conventional, thermal, photochemical initiation, etc.), potentially with 
the additional advantages developed in the preceding section. 

Intensive research has been conducted from 1960 to 1980 on monomer precursors of commodity 
polymers, such as ethylene at various pressures and temperatures, [48–50], in solution or in super-
critical CO2 [51] and at pilot-scale [52–56]. It was confirmed that short chain branching is considerably 
reduced by γ-ray initiation at low temperature [57]. 

Scheme 1. Simplified description of radiation-initiated polymerization for monomer M in the bulk or
dissolved in solvent S. Depending on the chemical nature of the monomer, the purity of the medium
and on the reaction conditions, chain propagation is initiated by appropriate free radical or ionic
active centers.

Those free radicals will be subject to diffusion-controlled recombination, soon establishing a steady
state concentration in the chemically homogeneous system. The specific case of acrylate monomers that
involve the reduction of the conjugated unsaturation by thermalized electrons will be discussed in the
forthcoming section. The rate for the generation of radical cations by ionizing radiation is considered to
be two orders of magnitude lower than that of free-radical formation, but the recombination constants
for ions (ion and counter-ion) are approximately two orders of magnitude higher than those for free
radicals. The stationary concentration of ions can therefore be estimated to be about 100 times lower
than that of free radicals [7]. Consequently, radiation polymerization proceeds mainly by a free-radical
mechanism unless specific conditions are met.

Introducing onium salts such as triaryl sulfonium or diaryl-iodonium associated with low
nucleophilicity counter-anion in the reaction medium allows generating strong acids and/or carbenium
that can initiate cationic processes more efficiently [45–47].

2.2.1. Free Radical Polymerization

Radiation-induced polymerization has been studied with many monomers irradiated as bulk
liquids, in solution, aqueous suspension or emulsion, the gas and solid crystalline or glassy state, as for
other methods of initiation (conventional, thermal, photochemical initiation, etc.), potentially with the
additional advantages developed in the preceding section.

Intensive research has been conducted from 1960 to 1980 on monomer precursors of commodity
polymers, such as ethylene at various pressures and temperatures, [48–50], in solution or in supercritical
CO2 [51] and at pilot-scale [52–56]. It was confirmed that short chain branching is considerably reduced
by γ-ray initiation at low temperature [57].

Styrene is a versatile monomer in terms of polymerization mechanism. Depending on temperature
and the nature of the solvent, a free radical [58,59], or a cationic mechanism [60–62] can operate.
Most convincing arguments supporting the nature of the dominant mechanism were obtained by
experiments using specific inhibitors, such as benzoquinone or diphenylpicrylhydrazyl radical (DPPH)
for free radicals, or water, methanol, and ammonia for cationic species. Kinetic considerations were
based on the order n of the dose rate (Ḋ), dependence of the polymerization rate of the monomer,
(Rp), expressed as Rp = K·Ḋn

·CM and of the dependence of measured molecular weight of the isolated
polymers on Ḋ, monomer concentration CM, and temperature. It was however difficult to draw clear



Polymers 2020, 12, 2877 8 of 67

conclusions from several studies, since both mechanisms can take place simultaneously, with a complex
dependence on reactions parameters and strong sensitivity of cationic entities to trace amounts of
impurities present in the reaction medium. Copolymerization experiments with monomers compatible
of only one of the two possible mechanisms were used to obtain additional evidence on the nature of
the effective propagating centers [63].

A detailed study on the temperature-dependence of the polymerization rates for styrene and
2,4-dimethylstyrene upon irradiation in chlorinated solvents showed that an ionic mechanism is
involved in the temperature range in which the activation energy is negative (Figure 1) [64].

Polymers 2020, 12, x 8 of 69 

Styrene is a versatile monomer in terms of polymerization mechanism. Depending on tempera-
ture and the nature of the solvent, a free radical [58,59], or a cationic mechanism [60–62] can operate. 
Most convincing arguments supporting the nature of the dominant mechanism were obtained by 
experiments using specific inhibitors, such as benzoquinone or diphenylpicrylhydrazyl radical 
(DPPH) for free radicals, or water, methanol, and ammonia for cationic species. Kinetic considera-
tions were based on the order n of the dose rate (Ḋ), dependence of the polymerization rate of the 
monomer, (Rp), expressed as Rp = K·Ḋn·CM and of the dependence of measured molecular weight of 
the isolated polymers on Ḋ, monomer concentration CM, and temperature. It was however difficult to 
draw clear conclusions from several studies, since both mechanisms can take place simultaneously, 
with a complex dependence on reactions parameters and strong sensitivity of cationic entities to trace 
amounts of impurities present in the reaction medium. Copolymerization experiments with mono-
mers compatible of only one of the two possible mechanisms were used to obtain additional evidence 
on the nature of the effective propagating centers [63]. 

A detailed study on the temperature-dependence of the polymerization rates for styrene and 
2,4-dimethylstyrene upon irradiation in chlorinated solvents showed that an ionic mechanism is in-
volved in the temperature range in which the activation energy is negative (Figure 1) [64]. 

 
Figure 1. Temperature-dependence of the radiation induced polymerization of styrene and 2,4-dime-
thylstyrene revealing the temperature ranges favoring the occurrence of a cationic or of free radical 
mechanism (after [64]). 

Advanced studies on the γ-ray induced polymerization of styrene under pressure were con-
ducted from 1970 to 1983 to clarify mechanistic aspects and to determine kinetic constants and ther-
modynamic parameters such as the activation volume, as a function of temperature and pressure in 
the bulk state and in emulsion [65]. 

Rubbers based on butadiene were also studied quite intensively from the late 1950s to the early 
1990s in solution and in emulsions [35,66–72]. 

Access to specialty polymers was explored with vinyl acetate and butyl acrylate polymerized in 
emulsion [70,73,74], or butyl acrylate copolymerized with butadiene, or polymerized at the surface 
of rubber particles to improve their compatibility with host matrices [75]. Water soluble poly(acryla-
mide) was obtained by γ-ray induced polymerization in various hydro-organic solutions to improve 
its efficiency as a flocculant [76]. 

The unique properties of fluorinated polymers stimulated studies on new synthetic approaches 
based on radiation-induced homo- and copolymerization of tetrafluoroethylene [77–79], hexafluoro-
propene [80], methyl trifluoroacrylate [81,82], in bulk conditions or in emulsion have been studied. 

Figure 1. Temperature-dependence of the radiation induced polymerization of styrene and
2,4-dimethylstyrene revealing the temperature ranges favoring the occurrence of a cationic or of
free radical mechanism (after [64]).

Advanced studies on the γ-ray induced polymerization of styrene under pressure were conducted
from 1970 to 1983 to clarify mechanistic aspects and to determine kinetic constants and thermodynamic
parameters such as the activation volume, as a function of temperature and pressure in the bulk state
and in emulsion [65].

Rubbers based on butadiene were also studied quite intensively from the late 1950s to the early
1990s in solution and in emulsions [35,66–72].

Access to specialty polymers was explored with vinyl acetate and butyl acrylate polymerized in
emulsion [70,73,74], or butyl acrylate copolymerized with butadiene, or polymerized at the surface of
rubber particles to improve their compatibility with host matrices [75]. Water soluble poly(acrylamide)
was obtained by γ-ray induced polymerization in various hydro-organic solutions to improve its
efficiency as a flocculant [76].

The unique properties of fluorinated polymers stimulated studies on new synthetic
approaches based on radiation-induced homo- and copolymerization of tetrafluoroethylene [77–79],
hexafluoropropene [80], methyl trifluoroacrylate [81,82], in bulk conditions or in emulsion have
been studied.

Various other studies devoted to monomers including heteroatoms, such as diphenylvinyl
phosphine oxide obtaining polymers with polar yet aprotic properties useful as a host matrix [83],
vinylsulfonamide to produce functional polymers useful as synthetic fibers, adhesives, ion exchange
resins [84], vinylbenzyltrimethyl ammonium chloride, as a precursor of chemically stable separation
membranes and resins [85], and highly reactive multifunctional acrylates including Si, Sn, or Ge atoms
as a consequence of their high stopping power and/or for potential applications as high refractive
index materials [86–88] have been reported.



Polymers 2020, 12, 2877 9 of 67

Several new polymers or polymers with a specific microstructure have been synthesized by
radiation-induced polymerization. Many of those products exhibit excellent properties with potential
practical uses, however little if any commercial products are currently on the market.

Radiation-induced polymerization also proceeds in bulk solid state in spite of the limited molecular
diffusion for the propagation steps and of an expectable poor energetic efficiency. Topochemical
effects and confinement in solid guest materials have stimulated various fundamental investigations.
Contrasting behaviors were observed depending on monomer orientation and on the gap between the
reactive functions within the crystal lattice. In some systems, polymerization seems to be initiated
within crystalline defects, and continues as the formation of amorphous polymer domains affects the
original crystalline lattice. In some favorable systems, the relative orientation of monomers prefigures
the order of repeating units of the resultant polymer [44].

The potentialities of these self-orienting polymerizations has stimulated more studies on MMA [89],
a long series of articles by Hardy (e.g., N-vinyl succinimide in liquid and solid state [90,91]),
maleimides [92], vinyl chloride and trichlorofluoroethylene [93,94], methacrylamide, allylurea and
N-vinylpyrrolidone [95], diacetylenes [96,97], and various monomers confined in clathrates, as already
mentioned in the preceding section.

2.2.2. Ionic Polymerization

Due to the formation of active species of different natures, free radical and ions, the actual and
precise propagation mechanism requires careful investigation. Ionic polymerizations are sensitive
to the presence of impurities that may arise and to temperature, which activates the dissociation of
propagating species but also favors transfer reaction.

2.2.3. Cationic Polymerization

The radiation-induced polymerization of styrene is a good example of the intense debates which
took place when comparing the results obtained by different teams from the radiation chemistry
community [59]. The kinetic data obtained with styrene thoroughly dried by distillation over Na-K
alloy were quite different from the values reported from previous studies in conditions where the
radical mechanism was predominantly operating. In dry medium the free radical mechanism can be
ruled out on the basis of the following arguments. Addition of small amounts of water and ammonia
caused a remarkable reduction in the rate of polymerization (Rp), whereas the activation energy
for propagation was nearly zero between −20 and +80 ◦C and Rp was proportional to (dose rate)n,
with 0.8 < n < l, while the molecular weight was independent of dose rate. These results strongly
support the intermediacy of ionic species. The cationic or anionic nature of the mechanism was
further clarified by performing copolymerization of styrene with α-methyl styrene and with isobutyl
vinyl ether which proved to be effective, hence confirming the occurrence of a cationic mechanism.
This was established by additional evidence based on the retardation propagation by the addition
of ammonia and diethyl ether in the medium. Radical scavengers such as DPPH and oxygen also
retarded the polymerization, suggesting the intermediacy of an ion-radical in the initiation stages.
It can be concluded that the propagation mechanism involves free ions.

Many other advanced studies conducted on vinyl and diene derivatives irradiated in the liquid or
in the solid states include ethylene [97], isobutene [60], butadiene [34,98], α-methyl styrene, pinene
and other terpenes, vinyl ethers [99,100]. Cyclic oligo-acetals [101] and cyclic ethers such as trio-, tetra-,
and penta-oxane [102,103] were studied during the same period.

The radiation-initiated ring-opening polymerization of oligocyclosiloxanes has also been
considered to occur via a cationic mechanism on the basis of the molecular weight distributions
that show limited back-biting reactions. The intermediacy of a chelated silicenium has been proposed
to account for the small differences in reactivity observed in the reaction rates of the cyclic oligomers
and distribution of reaction products, in contrast with chemically initiated polymerization [104].



Polymers 2020, 12, 2877 10 of 67

Probably, the more important results from the viewpoint of the potential applications is the
cationic polymerization of epoxides [105,106] which will be further discussed later in this review.

2.2.4. Anionic Polymerization

Nitroethylene is among the most representative monomer proved to polymerize by
radiation-initiated anionic process. Its reactivity has been studied during the period 1966–1969 [107,108].
The anionic mechanism involves free ions. Its polymerization kinetics were investigated by using
hydrogen bromide as an anionic scavenger. G(initiation) was about 0.3 µmol J−1, which is much larger
than the value (0.01 µmol J−1) obtained for many ionic polymerizations of unsaturated hydrocarbons.
This difference may be explained by the large dielectric constant of the medium and high electron
affinity of this particular monomer. Additional information on the mechanism and on the lifetime of
transient species was obtained with pulse radiolysis experiments conducted at low temperature [109].
β-nitrostyrene [110] has also been confirmed to polymerize by an anionic mechanism.

2.2.5. Controlled Free Radical Polymerization

Since the early developments of controlled free-radical polymerization, radiation-mediated
methods have been tested and developed in tandem with RAFT because of advantages of the soft,
regular and penetrating mean of activation provided by γ irradiation [111]. This combined technique
is particularly useful to conduct mechanistic and kinetic investigations [112,113]. From a preparative
standpoint, it has been demonstrated as a unique approach to synthesize some polymers with the
features of controlled polymerization [114]. The potentialities for the precise modification of various
types of surfaces and substrates by radiation grafting are demonstrated by an increasing number of
reports [115,116].

In conclusion to this section, the potential advantages of radiation-induced polymerization as
an industrial method for the synthesis of commodity or low value-added polymers has not been
confirmed to a sufficient level nor with significant economic benefit to allow industrial development
for the production of commodity polymers. One of the basic limitations of the radiation-induced
process is that the advantages in terms of structural features of polymers in specific conditions are lost
at higher conversion, as a consequence of radiolytic effects on the polymer formed in situ.

However, the research that was conducted during these years has produced quite important
results with significant impact in polymer science. The radiation-induced grafting and radiation
curing by cross-linking polymerization, negative-tone lithography as well as specific applications
based on radiation-induced polymerization in confined or multiphase components and media have
been established as valuable technological options for specific and value-added applications.

2.3. Radiation-Induced Cross-Linking Polymerization

The curing of mixed monomers and prepolymers formulations is by far the largest application
domain of radiation-induced polymerization. Cross-linking polymerization is initiated almost
instantaneously upon interaction with the triggering beam to form covalent polymer networks
resembling those in thermosets (Scheme 2).

Polymers 2020, 12, x 11 of 69 

 
Scheme 2. Radiation-induced cross-linking polymerization of blends based on reactive prepolymers 
and multifunctional monomers. 

Solvent-free formulations of adhesives, inks, overprint varnishes, coatings, and paints can be 
cured by UV- or radiation-induced crosslinking polymerization. These methods are gaining shares 
over conventional solvent-based and/or heat-curing processes which are gradually phased-out in 
graphic arts and coatings industries because of their reduced environmental footprint and better san-
itary profile (reduced energy consumption and volatile organic compounds emission) [117]. 

Compared to UV-visible photon sources and accelerated electrons, high energy X-rays and γ 
radiation indeed penetrate more deeply in heavily pigmented inks and paints and in composites with 
high levels of fillers or fibers. High energy radiation can cure sealants which are sandwiched between 
non-transparent materials. In addition to this advantage relating to the physical characteristics of 
ionizing radiation, as no primary initiator nor photosensitizer are needed to generate free radicals 
upon irradiation, the risk of producing toxic extractable chemicals is considerably reduced. The re-
sulting formulations and the cured materials are consequently even safer for food packaging, bio-
materials, and environmentally friendly applications [118]. 

These specific features are particularly well-exploited in the remarkable restauration process for 
damaged archaeological objects made of wood, and for some other types of weak artistic pieces with 
a porous structure. After infusion of a restorative monomer-based resins, the unique in-depth chem-
ical effects of high energy radiation result in the consolidation of the artefacts by solidification of the 
liquid by polymerization, all stages of the process being conducted under mild conditions [119]. 

2.3.1. General Description 

Two main classes of monomers are commercially available depending on the type of polymeri-
zation mechanism. The first group is comprised of monomers fitted with ethylenic unsaturations, 
mainly acrylates and methacrylates, but also styrene and its derivatives as well as some N-vinyl lac-
tams. Most of them undergo fast free radical polymerization. The second group includes molecules 
bearing epoxy or vinylether functionalities for polymerization mechanisms mediated by cationic cen-
ters. The architecture, the chemical nature of the backbone, and number of monomer units attached 
to these monomers and prepolymers have a strong impact on their reactivity and on the physical 
properties of the cured material. The requirements in terms of tensile strength, flexibility and elonga-
tion, gloss, scratch and solvent resistance, adhesion to substrate or the reinforcing materials durability 
upon photochemical and hygrothermal ageing may differ considerably, depending on the domain of 
application. 

The different generic structures represented in Scheme 3 exist with aliphatic or aromatic hydro-
carbon scaffolds, with linear or branched polyethers, polyesters, polyurethanes, silicones, with vari-
ous molecular weight and number of attached monomer units. The balance between the rigidity of 
the scaffold’s segments and the final crosslink density strongly influences the thermo-mechanical 
properties of the obtained networks. Mono- or multifunctional reactive diluents which are primarily 
added to the prepolymer blends to adjust its rheological properties also influence the curing reactivity 
by acting on the initial concentration in monomer groups and on the density of cross-links. A variety 
of reactive additives specifically developed for radiation-curing applications help to improve surface 
properties. 

Scheme 2. Radiation-induced cross-linking polymerization of blends based on reactive prepolymers
and multifunctional monomers.



Polymers 2020, 12, 2877 11 of 67

Solvent-free formulations of adhesives, inks, overprint varnishes, coatings, and paints can be
cured by UV- or radiation-induced crosslinking polymerization. These methods are gaining shares over
conventional solvent-based and/or heat-curing processes which are gradually phased-out in graphic
arts and coatings industries because of their reduced environmental footprint and better sanitary
profile (reduced energy consumption and volatile organic compounds emission) [117].

Compared to UV-visible photon sources and accelerated electrons, high energy X-rays and γ

radiation indeed penetrate more deeply in heavily pigmented inks and paints and in composites with
high levels of fillers or fibers. High energy radiation can cure sealants which are sandwiched between
non-transparent materials. In addition to this advantage relating to the physical characteristics of
ionizing radiation, as no primary initiator nor photosensitizer are needed to generate free radicals upon
irradiation, the risk of producing toxic extractable chemicals is considerably reduced. The resulting
formulations and the cured materials are consequently even safer for food packaging, biomaterials,
and environmentally friendly applications [118].

These specific features are particularly well-exploited in the remarkable restauration process for
damaged archaeological objects made of wood, and for some other types of weak artistic pieces with a
porous structure. After infusion of a restorative monomer-based resins, the unique in-depth chemical
effects of high energy radiation result in the consolidation of the artefacts by solidification of the liquid
by polymerization, all stages of the process being conducted under mild conditions [119].

2.3.1. General Description

Two main classes of monomers are commercially available depending on the type of polymerization
mechanism. The first group is comprised of monomers fitted with ethylenic unsaturations, mainly
acrylates and methacrylates, but also styrene and its derivatives as well as some N-vinyl lactams. Most of
them undergo fast free radical polymerization. The second group includes molecules bearing epoxy or
vinylether functionalities for polymerization mechanisms mediated by cationic centers. The architecture,
the chemical nature of the backbone, and number of monomer units attached to these monomers
and prepolymers have a strong impact on their reactivity and on the physical properties of the cured
material. The requirements in terms of tensile strength, flexibility and elongation, gloss, scratch and
solvent resistance, adhesion to substrate or the reinforcing materials durability upon photochemical
and hygrothermal ageing may differ considerably, depending on the domain of application.

The different generic structures represented in Scheme 3 exist with aliphatic or aromatic
hydrocarbon scaffolds, with linear or branched polyethers, polyesters, polyurethanes, silicones,
with various molecular weight and number of attached monomer units. The balance between
the rigidity of the scaffold’s segments and the final crosslink density strongly influences the
thermo-mechanical properties of the obtained networks. Mono- or multifunctional reactive diluents
which are primarily added to the prepolymer blends to adjust its rheological properties also influence
the curing reactivity by acting on the initial concentration in monomer groups and on the density of
cross-links. A variety of reactive additives specifically developed for radiation-curing applications
help to improve surface properties.

Polymers 2020, 12, x 12 of 69 

 
Scheme 3. Generic structures of monomers and prepolymers with soft or rigid segments used in ra-
diation-curable blends. 

2.3.2. Initiation Mechanisms 

Pulse-radiolysis experiments performed with simple acrylate monomers, either in the bulk state 
or in solution in various solvents provide a better understanding of the pathways leading to effective 
initiation of polymerization. Irradiation of acrylates and methacrylates were studied in cyclohexane 
solution [21,120,121]. Diacrylates were studied in n-butyl chloride solution [122] and water-soluble 
diacrylates in diluted aqueous solution [123,124]. Kinetic and mechanistic information are obtained 
by analyzing the decay of the transient species known to appear upon irradiation of the solvent. The 
bulk monomer generally behaves in a more complex manner, since it is composed of various struc-
tural moieties. A schematic depiction of the mechanism operating aliphatic acrylates such as tripro-
pyleneglycol diacrylate irradiated in the bulk state can however be proposed by the sequence of 
events shown in Scheme 4. Attachment of a thermalized electron to the carbonyl of acrylate esters, 
and the subsequent formation of a radical anion dimer either represented by a charge transfer com-
plex, or by a covalent adduct. Protonation of the corresponding radical-anions leads to the effective 
neutral free radical species that initiate propagation. The direct formation of free radicals by homo-
lytic dissociation of electronically excited monomer moieties is considered to be a minor initiation 
pathway.  

 
Scheme 4. Proposed mechanism for the initiation of acrylate polymerization upon exposure to high 
energy radiation [122]. 

As mentioned earlier, radiation-induced cationic reactions are sensitive to the chemical nature 
of the medium and to the presence of impurities. Cationic polymerization is preferably conducted in 

Scheme 3. Generic structures of monomers and prepolymers with soft or rigid segments used in
radiation-curable blends.



Polymers 2020, 12, 2877 12 of 67

2.3.2. Initiation Mechanisms

Pulse-radiolysis experiments performed with simple acrylate monomers, either in the bulk state
or in solution in various solvents provide a better understanding of the pathways leading to effective
initiation of polymerization. Irradiation of acrylates and methacrylates were studied in cyclohexane
solution [21,120,121]. Diacrylates were studied in n-butyl chloride solution [122] and water-soluble
diacrylates in diluted aqueous solution [123,124]. Kinetic and mechanistic information are obtained
by analyzing the decay of the transient species known to appear upon irradiation of the solvent.
The bulk monomer generally behaves in a more complex manner, since it is composed of various
structural moieties. A schematic depiction of the mechanism operating aliphatic acrylates such as
tripropyleneglycol diacrylate irradiated in the bulk state can however be proposed by the sequence of
events shown in Scheme 4. Attachment of a thermalized electron to the carbonyl of acrylate esters,
and the subsequent formation of a radical anion dimer either represented by a charge transfer complex,
or by a covalent adduct. Protonation of the corresponding radical-anions leads to the effective neutral
free radical species that initiate propagation. The direct formation of free radicals by homolytic
dissociation of electronically excited monomer moieties is considered to be a minor initiation pathway.

Polymers 2020, 12, x 12 of 69 

 
Scheme 3. Generic structures of monomers and prepolymers with soft or rigid segments used in ra-
diation-curable blends. 

2.3.2. Initiation Mechanisms 

Pulse-radiolysis experiments performed with simple acrylate monomers, either in the bulk state 
or in solution in various solvents provide a better understanding of the pathways leading to effective 
initiation of polymerization. Irradiation of acrylates and methacrylates were studied in cyclohexane 
solution [21,120,121]. Diacrylates were studied in n-butyl chloride solution [122] and water-soluble 
diacrylates in diluted aqueous solution [123,124]. Kinetic and mechanistic information are obtained 
by analyzing the decay of the transient species known to appear upon irradiation of the solvent. The 
bulk monomer generally behaves in a more complex manner, since it is composed of various struc-
tural moieties. A schematic depiction of the mechanism operating aliphatic acrylates such as tripro-
pyleneglycol diacrylate irradiated in the bulk state can however be proposed by the sequence of 
events shown in Scheme 4. Attachment of a thermalized electron to the carbonyl of acrylate esters, 
and the subsequent formation of a radical anion dimer either represented by a charge transfer com-
plex, or by a covalent adduct. Protonation of the corresponding radical-anions leads to the effective 
neutral free radical species that initiate propagation. The direct formation of free radicals by homo-
lytic dissociation of electronically excited monomer moieties is considered to be a minor initiation 
pathway.  

 
Scheme 4. Proposed mechanism for the initiation of acrylate polymerization upon exposure to high 
energy radiation [122]. 

As mentioned earlier, radiation-induced cationic reactions are sensitive to the chemical nature 
of the medium and to the presence of impurities. Cationic polymerization is preferably conducted in 

Scheme 4. Proposed mechanism for the initiation of acrylate polymerization upon exposure to high
energy radiation [122].

As mentioned earlier, radiation-induced cationic reactions are sensitive to the chemical nature
of the medium and to the presence of impurities. Cationic polymerization is preferably conducted
in the presence of onium salts to ensure efficient initiation. Many of the diaryliodonium and triaryl
sulfonium salts which are used as oxidative coinitiators in the radiolytic process can also operate by
direct and selective UV photolysis [125]. The two activation processes are actually quite different.
The dominant pathway in an irradiated medium rich in monomers and where energy deposition
occurs at random, is the production of free radicals which can be oxidized by electron transfer to
the onium salt, generating carbenium cations (Scheme 5) [126]. Reduction of the onium salt can also
occur from its interaction with solvated electrons (direct reduction pathway). More complex radiolytic
processes mechanism were confirmed by pulse radiolysis experiments on phenyl glycidyl ether in
the presence of an iodonium salt [126]. The decomposition of the low nucleophilicity counter-anions,
such as hexafluorophosphate or hexafluoroantimonate, has been also been reported based on early
observations of these systems, but still remains to be elucidated [127,128].



Polymers 2020, 12, 2877 13 of 67

Polymers 2020, 12, x 13 of 69 

the presence of onium salts to ensure efficient initiation. Many of the diaryliodonium and triaryl sul-
fonium salts which are used as oxidative coinitiators in the radiolytic process can also operate by 
direct and selective UV photolysis [125]. The two activation processes are actually quite different. The 
dominant pathway in an irradiated medium rich in monomers and where energy deposition occurs 
at random, is the production of free radicals which can be oxidized by electron transfer to the onium 
salt, generating carbenium cations (Scheme 5) [126]. Reduction of the onium salt can also occur from 
its interaction with solvated electrons (direct reduction pathway). More complex radiolytic processes 
mechanism were confirmed by pulse radiolysis experiments on phenyl glycidyl ether in the presence 
of an iodonium salt [126]. The decomposition of the low nucleophilicity counter-anions, such as hex-
afluorophosphate or hexafluoroantimonate, has been also been reported based on early observations 
of these systems, but still remains to be elucidated [127,128]. 

 
Scheme 5. Simplified mechanism for the formation of the initiating species for epoxy monomers in 
presence of diaryliodonium salt upon exposure to high energy radiation (counter-anions of the onium 
salt are omitted in this scheme for the sake of simplicity). 

At the dose rate provided by high energy radiation sources, preferably electron accelerators, the 
number of active centers per time unit is generally sufficient to ensure the fast and extensive polymer-
ization of the organic binder. In this situation, inhibition by monomer stabilizers, by atmospheric 
oxygen in the case of free radical initiation, or by nucleophiles and moisture that deactivate cationic 
centers, are overcome during the first instants of irradiation by the formation of a larger amount of 
reactive species. Thermal aspects related to the exothermal flux induced by the polymerization and 
by the enthalpic conversion of the absorbed radiation are crucial since translational and segmental 
mobility is needed to ensure the development of covalent networks by cross-linking polymerization 
[129]. A precise control of temperature profiles is therefore required during the elaboration of high-
performance materials capable of withstanding high service temperature and exhibiting high me-
chanical properties. 

The simple bisphenol-A derived diepoxy monomer DGEBA, and the diacrylate EPAC shown in 
Scheme 6 are representative models of the radiation-curable resins used for such applications. Many 
studies have examined their reactivity upon radiation-induced cationic and free radical polymeriza-
tion, respectively. The idealized structure of the corresponding networks emphasizes the very high 
cross-linking density in the two types of resulting networks which include quite rigid bisphenol-A 
segments. 

Scheme 5. Simplified mechanism for the formation of the initiating species for epoxy monomers in
presence of diaryliodonium salt upon exposure to high energy radiation (counter-anions of the onium
salt are omitted in this scheme for the sake of simplicity).

At the dose rate provided by high energy radiation sources, preferably electron accelerators,
the number of active centers per time unit is generally sufficient to ensure the fast and extensive
polymerization of the organic binder. In this situation, inhibition by monomer stabilizers,
by atmospheric oxygen in the case of free radical initiation, or by nucleophiles and moisture that
deactivate cationic centers, are overcome during the first instants of irradiation by the formation of
a larger amount of reactive species. Thermal aspects related to the exothermal flux induced by the
polymerization and by the enthalpic conversion of the absorbed radiation are crucial since translational
and segmental mobility is needed to ensure the development of covalent networks by cross-linking
polymerization [129]. A precise control of temperature profiles is therefore required during the
elaboration of high-performance materials capable of withstanding high service temperature and
exhibiting high mechanical properties.

The simple bisphenol-A derived diepoxy monomer DGEBA, and the diacrylate EPAC shown
in Scheme 6 are representative models of the radiation-curable resins used for such applications.
Many studies have examined their reactivity upon radiation-induced cationic and free radical
polymerization, respectively. The idealized structure of the corresponding networks emphasizes
the very high cross-linking density in the two types of resulting networks which include quite rigid
bisphenol-A segments.

Beyond the already mentioned differences due to the chemical nature of the monomers and in
precise initiation mechanisms, a number of other contrasting features associated with the radiation
treatment or with the physical characteristics of the reactive system may exert, in a direct or indirect
manner, an influence on the build-up of the network and on the final properties of resulting material.

2.3.3. Gelation and Vitrification during Network Formation

The combination of spectroscopic and thermophysical analyses allows for a more precise
description of the curing behavior. The following results highlight the key aspects of polymerization
kinetics and network formation.

Crosslinking-polymerization of blends based on multifunctional monomers and prepolymers
undergo macroscopic gelation at rather low conversion degree [130]. The resulting auto-acceleration
or Trommsdorff effect is exemplified by comparing the conversion plots for a monoacrylate to those
recorded of diacrylates. Butyl acrylate (nBuA), hexanediol diacrylate (HDDA) and tripropyleneglycol
diacrylate (TPGDA) have comparable acrylate functionality contents in the bulk state (between 6.7 and



Polymers 2020, 12, 2877 14 of 67

8.8 mol kg−1). The conversion plots of Figure 2 were obtained by FTIR monitoring after cumulative
application of 10 kGy e-beam dose increments at the same dose rate of 11 kGy s−1. The profiles show
that the initial polymerization rates are 30 times faster for HDDA, and 60 times faster for TPGDA than
that of nBuA. Since the viscosities of the bulk monomers are not very different, assuming that the
generation of initiating species and that the intrinsic reactivity of the acrylate functions are similar
for the three monomers, the contrasting initial polymerization rates would essentially result from
differences in the steady-state concentration in free radicals due to the much slower bimolecular
termination rate in multifunctional monomers.Polymers 2020, 12, x 14 of 69 

 
Scheme 6. Molecular structure of bis-phenol A diglycidyl ether (DGEBA), of bis-phenol A epoxy acry-
late (EPAC) and of the networks resulting from their radiation-initiated crosslinking polymerization. 

Beyond the already mentioned differences due to the chemical nature of the monomers and in 
precise initiation mechanisms, a number of other contrasting features associated with the radiation 
treatment or with the physical characteristics of the reactive system may exert, in a direct or indirect 
manner, an influence on the build-up of the network and on the final properties of resulting material. 

2.3.3. Gelation and Vitrification During Network Formation 

The combination of spectroscopic and thermophysical analyses allows for a more precise de-
scription of the curing behavior. The following results highlight the key aspects of polymerization 
kinetics and network formation. 

Crosslinking-polymerization of blends based on multifunctional monomers and prepolymers 
undergo macroscopic gelation at rather low conversion degree [130]. The resulting auto-acceleration 
or Trommsdorff effect is exemplified by comparing the conversion plots for a monoacrylate to those 
recorded of diacrylates. Butyl acrylate (nBuA), hexanediol diacrylate (HDDA) and tripropyleneglycol 
diacrylate (TPGDA) have comparable acrylate functionality contents in the bulk state (between 6.7 
and 8.8 mol kg−1). The conversion plots of Figure 2 were obtained by FTIR monitoring after cumula-
tive application of 10 kGy e-beam dose increments at the same dose rate of 11 kGy s−1. The profiles 
show that the initial polymerization rates are 30 times faster for HDDA, and 60 times faster for 
TPGDA than that of nBuA. Since the viscosities of the bulk monomers are not very different, assum-
ing that the generation of initiating species and that the intrinsic reactivity of the acrylate functions 
are similar for the three monomers, the contrasting initial polymerization rates would essentially re-
sult from differences in the steady-state concentration in free radicals due to the much slower bimo-
lecular termination rate in multifunctional monomers. 

Scheme 6. Molecular structure of bis-phenol A diglycidyl ether (DGEBA), of bis-phenol A epoxy
acrylate (EPAC) and of the networks resulting from their radiation-initiated crosslinking polymerization.

Polymers 2020, 12, x 15 of 69 

 
Figure 2. Kinetic profiles of acrylate consumption in monomer films as a function of EB radiation dose 
(nBuA (●), tripropyleneglycol diacrylate (TPGDA) (�☐) and hexanediol diacrylate (HDDA) (○). 

This phenomenon explains to a large extent the extremely fast polymerization of acrylate-based 
ink formulations for graphic arts and for coatings for optical fibers, with curing speeds under UV or 
high energy radiation as high as several hundreds of meters per minute on high-performance indus-
trial lines [131–133]. 

Dramatic changes in the rheology arise as cross-linking polymerization progresses in solvent-
free radiation-polymerizable compositions. Initially, the blends viscosity ranges from 0.5 to 5 Pa s at 
the application temperature which facilitates the spreading of the blend onto the substrate or the 
impregnation of fibers or fillers during the fabrication of composite materials. Network formation 
proceeds with a gradual reduction of mobility from the fluid state, to a gel, and eventually to a vitre-
ous material. The viscosity increases by several orders of magnitude until solidification, at first with 
the positive influence on polymerization kinetics discussed in the previous section, and then by a 
strong reduction of polymerization rate as the monomer is depleted and as the material approaches 
vitrification. 

Comparison of the EB-curing kinetics for an aliphatic polyurethane triacrylate (APU) having an 
initial acrylate content of 3.5 mol kg−1 with an aromatic epoxy-diacrylate (EPAC) with a higher initial 
acrylate content (about 6 mol kg−1) is quite instructive. These experiments were conducted under 
conditions minimizing the thermal effects due to polymerization exothermicity by applying small 
dose increments onto thin films of the prepolymer mixtures cast on NaCl windows [134]. 

While the polyurethane acrylate possesses a flexible backbone, which yields a soft material upon 
curing, the epoxy acrylate tends to form a glassy network even at low conversion levels. The kinetic 
profiles illustrate quite clearly the effects of incipient vitrification that occurs at different conversion 
levels. The acrylate plot shows a steep increase in monomer conversion to 0.75 for a dose lower than 
10 kGy (Figure 3). The curve then levels off to a plateau with a conversion value about 0.9. The plot 
for the aromatic epoxy diacrylate indicates that the fast-initial stage has abated at a low conversion 
level of 0.2, the conversion approaching 0.4 only for a dose of 60 kGy. At this stage, the concentration 
of unreacted acrylates is 3.6 mol kg−1, a value that is even higher than the acrylate concentration in 
the unreacted APU sample. The poor reactivity observed in spite of the large concentration of mon-
omer reveals the influence of incipient vitrification that hinders propagation. 

Figure 2. Kinetic profiles of acrylate consumption in monomer films as a function of EB radiation dose
(nBuA (•), tripropyleneglycol diacrylate (TPGDA) (�) and hexanediol diacrylate (HDDA) (#).

This phenomenon explains to a large extent the extremely fast polymerization of acrylate-based
ink formulations for graphic arts and for coatings for optical fibers, with curing speeds under UV
or high energy radiation as high as several hundreds of meters per minute on high-performance
industrial lines [131–133].



Polymers 2020, 12, 2877 15 of 67

Dramatic changes in the rheology arise as cross-linking polymerization progresses in solvent-free
radiation-polymerizable compositions. Initially, the blends viscosity ranges from 0.5 to 5 Pa s at
the application temperature which facilitates the spreading of the blend onto the substrate or the
impregnation of fibers or fillers during the fabrication of composite materials. Network formation
proceeds with a gradual reduction of mobility from the fluid state, to a gel, and eventually to a vitreous
material. The viscosity increases by several orders of magnitude until solidification, at first with the
positive influence on polymerization kinetics discussed in the previous section, and then by a strong
reduction of polymerization rate as the monomer is depleted and as the material approaches vitrification.

Comparison of the EB-curing kinetics for an aliphatic polyurethane triacrylate (APU) having an
initial acrylate content of 3.5 mol kg−1 with an aromatic epoxy-diacrylate (EPAC) with a higher initial
acrylate content (about 6 mol kg−1) is quite instructive. These experiments were conducted under
conditions minimizing the thermal effects due to polymerization exothermicity by applying small dose
increments onto thin films of the prepolymer mixtures cast on NaCl windows [134].

While the polyurethane acrylate possesses a flexible backbone, which yields a soft material upon
curing, the epoxy acrylate tends to form a glassy network even at low conversion levels. The kinetic
profiles illustrate quite clearly the effects of incipient vitrification that occurs at different conversion
levels. The acrylate plot shows a steep increase in monomer conversion to 0.75 for a dose lower than
10 kGy (Figure 3). The curve then levels off to a plateau with a conversion value about 0.9. The plot for
the aromatic epoxy diacrylate indicates that the fast-initial stage has abated at a low conversion level
of 0.2, the conversion approaching 0.4 only for a dose of 60 kGy. At this stage, the concentration of
unreacted acrylates is 3.6 mol kg−1, a value that is even higher than the acrylate concentration in the
unreacted APU sample. The poor reactivity observed in spite of the large concentration of monomer
reveals the influence of incipient vitrification that hinders propagation.Polymers 2020, 12, x 16 of 69 

 
Figure 3. Kinetic profiles of acrylate consumption in prepolymer films as a function of EB-radiation 
dose: (a) APU and (b) EPAC. 

As curing was performed at quasi-isothermal conditions, vitrification took place in the APU ma-
terial at conversion levels slightly above 0.7, the critical value at which the kinetics started to level 
off. The vitrification phenomenon took place at much lower conversion levels (typically 0.2) in the 
more rigid EPAC prepolymer when cured at room temperature. 

The dose rate-dependence of the quasi-isothermal kinetic profiles on polymerization kinetics of 
the EPAC diacrylate at EB currents corresponding to dose rates between 19 and 110 kGy s−1 is shown 
in Figure 4. 

 
Figure 4. Kinetic profiles of acrylate consumption for EPAC prepolymer processed at different dose 
rates. 

Three kinetic regimes were considered for each plot. At low conversion, the initial polymeriza-
tion rate was proportional to the square root of the dose rate Ḋ, as is expected from the bimolecular 
termination kinetics occurring for free radical chain processes in fluid media (Equation (1)). 𝑅 = 𝑘 𝑅2 𝑘 [𝐶 = 𝐶] ∝ 𝑘2 𝑘 [𝐶 = 𝐶]𝐷 . 𝐺(𝑅⋅) (1) 

where kp: the reaction rate constant of the propagation reaction; 

Rinit: the rate of initiation reaction; 
kt: the reaction rate constant of the termination reaction; 

Figure 3. Kinetic profiles of acrylate consumption in prepolymer films as a function of EB-radiation
dose: (a) APU and (b) EPAC.

As curing was performed at quasi-isothermal conditions, vitrification took place in the APU
material at conversion levels slightly above 0.7, the critical value at which the kinetics started to level
off. The vitrification phenomenon took place at much lower conversion levels (typically 0.2) in the
more rigid EPAC prepolymer when cured at room temperature.

The dose rate-dependence of the quasi-isothermal kinetic profiles on polymerization kinetics of
the EPAC diacrylate at EB currents corresponding to dose rates between 19 and 110 kGy s−1 is shown
in Figure 4.



Polymers 2020, 12, 2877 16 of 67

Polymers 2020, 12, x 16 of 69 

 
Figure 3. Kinetic profiles of acrylate consumption in prepolymer films as a function of EB-radiation 
dose: (a) APU and (b) EPAC. 

As curing was performed at quasi-isothermal conditions, vitrification took place in the APU ma-
terial at conversion levels slightly above 0.7, the critical value at which the kinetics started to level 
off. The vitrification phenomenon took place at much lower conversion levels (typically 0.2) in the 
more rigid EPAC prepolymer when cured at room temperature. 

The dose rate-dependence of the quasi-isothermal kinetic profiles on polymerization kinetics of 
the EPAC diacrylate at EB currents corresponding to dose rates between 19 and 110 kGy s−1 is shown 
in Figure 4. 

 
Figure 4. Kinetic profiles of acrylate consumption for EPAC prepolymer processed at different dose 
rates. 

Three kinetic regimes were considered for each plot. At low conversion, the initial polymeriza-
tion rate was proportional to the square root of the dose rate Ḋ, as is expected from the bimolecular 
termination kinetics occurring for free radical chain processes in fluid media (Equation (1)). 𝑅 = 𝑘 𝑅2 𝑘 [𝐶 = 𝐶] ∝ 𝑘2 𝑘 [𝐶 = 𝐶]𝐷 . 𝐺(𝑅⋅) (1) 

where kp: the reaction rate constant of the propagation reaction; 

Rinit: the rate of initiation reaction; 
kt: the reaction rate constant of the termination reaction; 

Figure 4. Kinetic profiles of acrylate consumption for EPAC prepolymer processed at different dose rates.

Three kinetic regimes were considered for each plot. At low conversion, the initial polymerization
rate was proportional to the square root of the dose rate Ḋ , as is expected from the bimolecular
termination kinetics occurring for free radical chain processes in fluid media (Equation (1)).

Rp =
kpRinit

2
√

kt
[C = C] ∝

kp

2
√

kt
[C = C]

.
D

0.5
G(R·) (1)

where kp: the reaction rate constant of the propagation reaction;
Rinit: the rate of initiation reaction;
kt: the reaction rate constant of the termination reaction;
Ḋ: dose rate;
G(R•): G—value of carbon centered radicals;
Rp: reaction rate of the propagation reaction;
C=C: initial concentration of vinyl group.

Deviations from this initial regime were evidenced as soon as the initial slope is affected by incipient
vitrification. The curved part of the profile is assigned to a transition regime which evolves to the final
segment where the polymerization rate is directly proportional to the dose rate. This corresponds to a
monomolecular termination by occlusion of the growing free radicals in the vitrified matrix.

UV-curing experiments performed under iso-thermal conditions at controlled temperatures clearly
establish a correlation between the curing temperature and the conversion level at the beginning of
third regime. Dynamic mechanical analysis of samples prepared with this critical conversion level
indeed show that the glass transition of the network does not differ from the curing temperature by
more than 5 ◦C [135]. These results stress the importance of the relation between the effective curing
temperature and the conversion dependence of the glass transition on the material network. From a
practical view, it is therefore crucial to control the thermal profile in the processed materials along with
the radiation treatment, if one wants to take advantage of radiation processing as an out-of-autoclave
alternative to conventional curing of thermosets [136]. To achieve the desired degree of curing without
external heating, there should be a finely-tuned interplay between the control of the polymerization
exotherm (typically 80 and 100 kJ mol−1, for acrylates and epoxy functionality, respectively), the energy
conversion from the deposited radiation dose, the heat and radiative exchanges with the surrounding
environment, and the conversion dependence of vitrification.

The large thermal effects occurring upon exposure to the electron beam of a 20 kW/10 MeV
accelerator have been measured in a 125 g EPAC sample fitted with a series of thermocouples placed in



Polymers 2020, 12, 2877 17 of 67

thin-walled aluminum box and treated with a single 50 kGy dose in the configuration represented in
Figure 5a. The plots of Figure 5b show that in central positions where energy deposition is maximal and
where heat dissipation is minimal, the raise in temperature can be as high as 180 ◦C in the sample which
was at room temperature before irradiation. The temperature increase within the sample increases is
essentially due to the polymerization reaction. Assuming that the heat capacity of the epoxy resin is
about 2 J K−1 g−1 [137], the increase due to the absorption of the 50 kGy dose would amount to about
25 ◦C at best, a value calculated for a strictly adiabatic process which is not the case in practice.

Polymers 2020, 12, x 17 of 69 

Ḋ: dose rate; 
G(R●): G—value of carbon centered radicals; 
Rp: reaction rate of the propagation reaction; 
C=C: initial concentration of vinyl group. 

Deviations from this initial regime were evidenced as soon as the initial slope is affected by in-
cipient vitrification. The curved part of the profile is assigned to a transition regime which evolves to 
the final segment where the polymerization rate is directly proportional to the dose rate. This corre-
sponds to a monomolecular termination by occlusion of the growing free radicals in the vitrified 
matrix. 

UV-curing experiments performed under iso-thermal conditions at controlled temperatures 
clearly establish a correlation between the curing temperature and the conversion level at the begin-
ning of third regime. Dynamic mechanical analysis of samples prepared with this critical conversion 
level indeed show that the glass transition of the network does not differ from the curing temperature 
by more than 5 °C [135]. These results stress the importance of the relation between the effective 
curing temperature and the conversion dependence of the glass transition on the material network. 
From a practical view, it is therefore crucial to control the thermal profile in the processed materials 
along with the radiation treatment, if one wants to take advantage of radiation processing as an out-
of-autoclave alternative to conventional curing of thermosets [136]. To achieve the desired degree of 
curing without external heating, there should be a finely-tuned interplay between the control of the 
polymerization exotherm (typically 80 and 100 kJ mol−1, for acrylates and epoxy functionality, respec-
tively), the energy conversion from the deposited radiation dose, the heat and radiative exchanges 
with the surrounding environment, and the conversion dependence of vitrification. 

The large thermal effects occurring upon exposure to the electron beam of a 20 kW/10 MeV ac-
celerator have been measured in a 125 g EPAC sample fitted with a series of thermocouples placed 
in thin-walled aluminum box and treated with a single 50 kGy dose in the configuration represented 
in Figure 5a. The plots of Figure 5b show that in central positions where energy deposition is maximal 
and where heat dissipation is minimal, the raise in temperature can be as high as 180 °C in the sample 
which was at room temperature before irradiation. The temperature increase within the sample in-
creases is essentially due to the polymerization reaction. Assuming that the heat capacity of the epoxy 
resin is about 2 J K−1 g−1 [137], the increase due to the absorption of the 50 kGy dose would amount to 
about 25 °C at best, a value calculated for a strictly adiabatic process which is not the case in practice. 

 
Figure 5. Position of thermocouples in a 125 g EPAC resin sample contained in a thin-walled alumi-
num box to (dotted line indicating the dose-depth deposition profile) and plots of the variations of 
the temperature in the sample submitted to a 50 kGy dose of 10 MeV electrons. 

Figure 5. Position of thermocouples in a 125 g EPAC resin sample contained in a thin-walled aluminum
box to (dotted line indicating the dose-depth deposition profile) and plots of the variations of the
temperature in the sample submitted to a 50 kGy dose of 10 MeV electrons.

This explains why the glass transition temperature (Tg) of EB-cured EPAC networks can reach
values as high as 180 ◦C. The conversion-dependence of Tg determined by Dynamic Mechanical
Analysis of thin films and bar-shaped specimens treated under various irradiation conditions exhibits
a monotonous increase suggesting a continuous build-up of the network, as a consequence of the
increase in crosslinks density (Figure 6).

Polymers 2020, 12, x 18 of 69 

This explains why the glass transition temperature (Tg) of EB-cured EPAC networks can reach 
values as high as 180 °C. The conversion-dependence of Tg determined by Dynamic Mechanical Anal-
ysis of thin films and bar-shaped specimens treated under various irradiation conditions exhibits a 
monotonous increase suggesting a continuous build-up of the network, as a consequence of the in-
crease in crosslinks density (Figure 6). 

 
Figure 6. Plot of the Tg (tanδ maximum in DMA spectrogram) as a function of acrylate conversion for 
EB-cured EPAC materials (for various EB doses, dose rates, and dose increments). The dotted line 
corresponds the simulation based on DiBenedetto’s model. 

The variations can be satisfactorily described by the DiBenedetto or Pascault–Williams relation 
(Equation (2)), where Tg is the glass transition temperature of network at conversion degree x, Tg0 is 
the glass transition temperature of the uncured resin (x = 0), Tg ∞ is the glass transition temperature of 
the fully reacted resin (x = 1), and λ is a structure-dependent parameter with value between 0 and 1), 
as represented by the continuous line in Figure 6. 𝑇 − 𝑇𝑇 − 𝑇 = 𝜆𝑥1 − (1 − 𝜆)𝑥 (2) 

The established relation between Tg vs monomer conversion can be used to describe the varia-
tions of viscosity in the sample subject to curing by using the Williams–Landel–Ferry (WLF) model 
expressed by Equation (3), 𝜂𝜂 = 𝑒𝑥𝑝 𝐶 𝑇 − 𝑇𝐶 𝑇 − 𝑇  (3) 

The WLF relation is commonly used to describe the increase in viscosity ηT when the tempera-
ture of a softened polymer approaches Tg from higher temperatures T, ηTgC1 (unitless) and C2 (°C) 
being numerical parameters. 

By adapting the reading of this description to a curing process, at a given polymerization tem-
perature T, it is possible to relate the decrease in segment mobility due to the progress of conversion 
vitrification that gradually shifts the network Tg to higher temperatures. 

A model was developed for predicting the Tg of a volume element in a radiation-cured material. 
Studies on temperature effects on isothermal polymerization kinetics for EPAC monomers showed 
that only regime 1 was thermally activated. Once vitrification has occurred in the sample, propaga-
tion appeared unsensitive to thermal effects. The kinetics of isothermal polymerization is modeled 
on the basis of the two extreme kinetic regimes observed in the conversion vs dose plots and from 
the assumption that a linear combination of the 2 regimes can describe satisfactorily the transition 
regime, as written in Equation (4) [138], 

Figure 6. Plot of the Tg (tanδ maximum in DMA spectrogram) as a function of acrylate conversion
for EB-cured EPAC materials (for various EB doses, dose rates, and dose increments). The dotted line
corresponds the simulation based on DiBenedetto’s model.



Polymers 2020, 12, 2877 18 of 67

The variations can be satisfactorily described by the DiBenedetto or Pascault–Williams relation
(Equation (2)), where Tg is the glass transition temperature of network at conversion degree x, Tg0 is
the glass transition temperature of the uncured resin (x = 0), Tg∞ is the glass transition temperature of
the fully reacted resin (x = 1), and λ is a structure-dependent parameter with value between 0 and 1),
as represented by the continuous line in Figure 6.

Tg − Tg0

Tg∞ − Tg0
=

λx
1− (1− λ)x

(2)

The established relation between Tg vs. monomer conversion can be used to describe the variations
of viscosity in the sample subject to curing by using the Williams–Landel–Ferry (WLF) model expressed
by Equation (3),

ηT

ηTg

= exp

 C1
(
T − Tg

)
C2 +

(
T − Tg

)  (3)

The WLF relation is commonly used to describe the increase in viscosity ηT when the temperature
of a softened polymer approaches Tg from higher temperatures T, ηTgC1 (unitless) and C2 (◦C) being
numerical parameters.

By adapting the reading of this description to a curing process, at a given polymerization
temperature T, it is possible to relate the decrease in segment mobility due to the progress of conversion
vitrification that gradually shifts the network Tg to higher temperatures.

A model was developed for predicting the Tg of a volume element in a radiation-cured material.
Studies on temperature effects on isothermal polymerization kinetics for EPAC monomers showed
that only regime 1 was thermally activated. Once vitrification has occurred in the sample, propagation
appeared unsensitive to thermal effects. The kinetics of isothermal polymerization is modeled on
the basis of the two extreme kinetic regimes observed in the conversion vs. dose plots and from the
assumption that a linear combination of the 2 regimes can describe satisfactorily the transition regime,
as written in Equation (4) [138],

Rp = [M]0(1−π)
{
α

[
A

.
D

0.5
e−

E1
a

RT

]
+ (1− α)

[
B

.
D
]}

(4)

the dependence of the weighing factors α and (1 − α) for each extreme regime as a function of the
progressive change of the Tg being expressed through the WLF equation by means of Equation (5),
where f N is a normalization factor.

α = fNexp

 C1
(
T − Tg(x)

)
C2 +

(
T − Tg(x)

)  (5)

The crosslinking polymerization of multifunctional monomers is known to yield brittle matrices,
therefore limiting the development of this technique for the production of high-performance composite
materials. Among the various possible causes of the brittleness, the spontaneous formation of
nanoheterogeneities during radiation-initiated polymerization. Solid state 1H NMR relaxation
experiments in radiation-cured materials prepared from model difunctional monomers allows one
to distinguish two phases inside the materials: one consisting in rigid domains, and a second one
with higher local mobility and distinct relaxation kinetic features [139]. The two-component decay
of the transverse magnetization are associated with one short and one long T2 value which can be
assigned to the highly cross-linked and the loosely cross-linked phase, respectively. The influence of
acrylate conversion on the relaxation behavior of cured samples was examined to describe the gradual
evolution of the different domains, in terms of local mobility and associated fraction of material,
along the curing process.



Polymers 2020, 12, 2877 19 of 67

AFM analysis of the EPAC samples in the phase imaging mode provides a complementary picture
of the network with indications on the actual dimensions of the soft and rigid domains. Topographically,
the images reveal a very flat surface with a roughness of 0.2 nm, whereas the phase contrast picture
highlights a more complex network structure [140]. Dense nodules appear very early at the brighter
zones with a mean cross-section of about 15 nm, whereas the darker interstitial zones correspond to
loosely crosslinked and swollen domains (Figure 7). Measurements of the number, Feret’s diameter, and
cross-section area of the rigid domains reveal that nanogel clusters are initially embedded in a soft gel,
undergoing limited evolution by growth and by aggregation up to a limiting size at higher conversion
levels. Nucleation within the monomer rich domains further continues up to a 50% conversion,
together with limited growth by aggregation of adjacent particles. Polymerization then continues in
interstitial domains, generating a stringy network with some discrete low conversion domains.

Polymers 2020, 12, x 19 of 69 

𝑅 = [𝑀] (1 − 𝜋) 𝛼 𝐴 𝐷 . 𝑒 (1 − 𝛼) 𝐵𝐷  (4) 

the dependence of the weighing factors ⍺ and (1-⍺) for each extreme regime as a function of the pro-
gressive change of the Tg being expressed through the WLF equation by means of Equation (5), where 
fN is a normalization factor. 

𝛼 = 𝑓 𝑒𝑥𝑝 𝐶 𝑇 − 𝑇 (𝑥)𝐶 𝑇 − 𝑇 (𝑥)   (5) 

The crosslinking polymerization of multifunctional monomers is known to yield brittle matrices, 
therefore limiting the development of this technique for the production of high-performance compo-
site materials. Among the various possible causes of the brittleness, the spontaneous formation of 
nanoheterogeneities during radiation-initiated polymerization. Solid state 1H NMR relaxation exper-
iments in radiation-cured materials prepared from model difunctional monomers allows one to dis-
tinguish two phases inside the materials: one consisting in rigid domains, and a second one with 
higher local mobility and distinct relaxation kinetic features [139]. The two-component decay of the 
transverse magnetization are associated with one short and one long T2 value which can be assigned 
to the highly cross-linked and the loosely cross-linked phase, respectively. The influence of acrylate 
conversion on the relaxation behavior of cured samples was examined to describe the gradual evolu-
tion of the different domains, in terms of local mobility and associated fraction of material, along the 
curing process. 

AFM analysis of the EPAC samples in the phase imaging mode provides a complementary pic-
ture of the network with indications on the actual dimensions of the soft and rigid domains. Topo-
graphically, the images reveal a very flat surface with a roughness of 0.2 nm, whereas the phase con-
trast picture highlights a more complex network structure [140]. Dense nodules appear very early at 
the brighter zones with a mean cross-section of about 15 nm, whereas the darker interstitial zones 
correspond to loosely crosslinked and swollen domains (Figure 7). Measurements of the number, 
Feret’s diameter, and cross-section area of the rigid domains reveal that nanogel clusters are initially 
embedded in a soft gel, undergoing limited evolution by growth and by aggregation up to a limiting 
size at higher conversion levels. Nucleation within the monomer rich domains further continues up 
to a 50% conversion, together with limited growth by aggregation of adjacent particles. Polymeriza-
tion then continues in interstitial domains, generating a stringy network with some discrete low con-
version domains. 

  
Figure 7. Height (a) and phase contrast (b–d) AFM images recorded in tapping mode of EB-cured 
epoxy diacrylate (EPAC) samples at conversion levels x = 0.41 (a,b), 0.46 (c), and 0.59 (d). 

Differential scanning calorimetry (DSC) of UV- and EB-cured diacrylate materials exhibiting a 
fractional degree of conversion ranging from 0.1 to 0.8 have been analyzed in the light of these results 
[140]. Two main second-order thermodynamic transitions were observed by using the temperature-
modulated mode of DSC which avoids perturbations coming from irreversible heat exchanges, as 
postpolymerization enthalpy. The bimodal distribution of transition temperatures observed as fused 
peaks in the thermograms representing the first derivative of reversible heat capacity dCp,rev/dT is 
satisfactorily resolved by a two-component fit, allowing for a quantitative exploitation of the data in 
terms of Gaussian contributions, with a central relaxation temperature and a peak width assigned to 

Figure 7. Height (a) and phase contrast (b–d) AFM images recorded in tapping mode of EB-cured
epoxy diacrylate (EPAC) samples at conversion levels x = 0.41 (a,b), 0.46 (c), and 0.59 (d).

Differential scanning calorimetry (DSC) of UV- and EB-cured diacrylate materials exhibiting
a fractional degree of conversion ranging from 0.1 to 0.8 have been analyzed in the light of these
results [140]. Two main second-order thermodynamic transitions were observed by using the
temperature-modulated mode of DSC which avoids perturbations coming from irreversible heat
exchanges, as postpolymerization enthalpy. The bimodal distribution of transition temperatures
observed as fused peaks in the thermograms representing the first derivative of reversible heat capacity
dCp,rev/dT is satisfactorily resolved by a two-component fit, allowing for a quantitative exploitation
of the data in terms of Gaussian contributions, with a central relaxation temperature and a peak
width assigned to each domain. The domains exhibiting the high transition temperature undergo an
evolution towards a well-defined state with a narrowing distribution of relaxation temperatures at the
higher conversion values, whereas the low temperature relaxation is continuously extending over a
wider domain. Comparing the NMR relaxation data as well as the calorimetric features of networks
prepared by UV- or by EB-induced polymerization does not reveal noticeable differences to be related
to the initiation mechanism (UV, EB or X-ray) and/or curing conditions (anisothermal or isothermal,
dose rate). This was established for two undiluted aromatic diacrylates, but one should be careful
and not generalize this finding to systems where mixtures of monomers are involved, since phase
separation is likely to occur, hence inducing different reactivities in the segregated domains.

A common scenario accounting for these observations and measurements is proposed for the
build-up of the network (Scheme 7). Irradiation of the liquid monomer induces the nucleation of softly
interconnected gel nanoparticles within the swollen loose network, which will increase in number by
additional nucleation, and in size by aggregation while the crosslink density goes up to form glassy
nanoclusters. At a critical level, percolation of the nanoclusters induces syneresis of the material
that ends up as a monolithic glassy solid. This illustrates variations of Tg and the broadness of the
transitions in relation with the variety of defects and heterogeneities in the spatial distribution of
cross-links density [138,141].



Polymers 2020, 12, 2877 20 of 67

Polymers 2020, 12, x 20 of 69 

each domain. The domains exhibiting the high transition temperature undergo an evolution towards 
a well-defined state with a narrowing distribution of relaxation temperatures at the higher conversion 
values, whereas the low temperature relaxation is continuously extending over a wider domain. 
Comparing the NMR relaxation data as well as the calorime