Models of primary processes leading to deactivation of energy deposited by a pulse of high energy electrons were derived for epoxy matrix materials and polyl-vinyl naphthalene. The basic conclusion is that recombination of initially formed charged states is complete within 1 nanosecond, and subsequent degradation chemistry is controlled by the reactivity of these excited states. Excited states in both systems form complexes with ground state molecules. These excimers or exciplexes have their characteristics emissive and absorptive properties and may decay to form separated pairs of ground state molecules, cross over to the triplet manifold or emit fluorescence. ESR studies and chemical analyses subsequent to pulse radiolysis were performed in order to estimate bond cleavage probabilities and net reaction rates. The energy deactivation models which were proposed to interpret these data have led to the development of radiation stabilization criteria for these systems

Coulter, D.

Gupta, A.

Liang, R.

Moacanin, J.

English

NASA Technical Reports Server

Pulsed Radiolysis of Model Aromatic
Polymers and EpoxyBased Matrix Materials
Amitava Gupta, Jovan Moacanin,
Ranty Liang and DanCoulter
Energy and Materials Research Section
Jet Propulsion Laboratory
California Institute of Technology
Pasadena,California 91109
Abstract - Models of primary processes leading to deactivation of energy deposited
by a Pulse of high energy electrons have been derived for epoxy matrix materials and
poly[l-vinyl naphthalene]. The basic conclusion is that recombination of initially
formed charged states is complete within I nanosecond, and subsequent degradation
chemistry is controlled by the reactivity of these excited states. Excited states
in both systems form complexes with ground state molecules. These excimers or exci-
plexes have their characteristic emissive and absorptive properties and may decay to
form separated pairs of ground state molecules, cross over to the triplet manifold
or emit fluorescence. ESR studies and chemical analyses subsequent to pulse radio-
lysis have been performed in order to estimate bond cleavage probabilities and net
reaction rates. The energy deactivation models which have been proposed to inter-
pret these data have led to the development of radiation stabilization criteria for
these systems.
Introduction - Reliable prediction of chemical and mechanical stability of large
space structures over periods of up to thirty years requires that a fundamental un-
derstanding of damage mechanisms he built into models for prediction of long term
damage for each candidate material and the corresponding system. Methodology of
predictive model development involves adoption of a dual approach in which enqineer-
ing testing on hardware is complemented by mechanistic modeling of the effect of ra-
diation stresses on the materials and subsequent validation of these models by means
of accelerated tests. This material science approach allows better definition of
engineering tests and test facilities and may also be used to interpret engineering
test data in terms of changes in chemical structure of the material causing a speci-
fic failure mode. Development of mechanistic models requires an understanding of the
primary processes which occur on impact of the energetic species (in our work, 600-
KeV electrons) on the material. These primary processes control the subsequent cas-
cade of energy deactivation paths some of which involve bond cleavage and consequent
chemical change. Primary processes can be inferred from an investigation of the net
chemical change; however, it is necessary to use time resolved techniques in order
to directly observe them and study their mechanisms. In this work, the excitation
source is a nanosecond pulsed electron beam, which allows time resolution down to
1-2 nsec. Time and spectrally resolved fluorescence and transient absorption have
been recorded on a model aromatic-polymer poly[l-vinyl naphthalene] and a typical
epoxy matrix material, namely the tetraglycidyl 4,4'-diaminodiphenyl methane-
diaminodiphyenyl sulfone (TGDDM-DDS) system. Chemical analysis has been performed
on PIVN subsequent to pulsed excitation and ESR studies have been performed on the
epoxy resin as a function of curing and the number of beam pulses incident on the
59
https://ntrs.nasa.gov/search.jsp?R=19820010404 2020-03-21T16:24:45+00:00Z
SAMPLE --
QUARTZ FIBER
FEBERTRON
MODEL 760
ELECTRON BEAM
PULSER
4
_-_VACUUM
| MONO-
,_L_ L_J CHAMBER 7 CHROMATOR
PULSE
GENERATOR
l I _I_ELECTRICALL _
t SHIELDED
ROOM
Fig. I. Schematic diagram of JPL
pulse radiolysis laboratory.
Fig. 2.
OPTICAL
DENSITY TGDDM
• • I a
; •
." : DDS TMDDS
/ 7'}/ 1
-! |\-, t"',
'" ! 1
'" _,....\
0.0 l 1 _'_",- "_
250 300 350
WAVELENGTH(nm)
UV absorption spectra of
TGDDM (.Ol3g/l), DDS (.O13g/l)
and TMDDS (.Ollg/1) in CH2Cl 2.
E_,_,ISSION INTENSITY
I
I
I i
I
I .."
I "
300
/ ..
V ".
3 1
- _ ...
.: _ ..
\
•: % ..
% ..
\ .:
\ .
\ ".,
\_. '.,
350 400
WAVELENGTH Into)
----- DDS #_HSSION
(Xex : 290 nrn_
.......... t-Me DOS EMISSIOn,
(Xex : 315 nm)
FGDDM E_,IISSI ON
(k : 501 nm)
ex
5
45O
Fig. 3a. Photoexcited emission spectra
of TGDDM (.O13g/l), DDS
(.O13g/l) and TMDDS (.Ollg/l)
in CH2CI 2 .
NORMALIZED
EMIS SION
INTENSITY
/-/ /'-",, _o_
/ \/ ',,
/ _ ',,
/ '\ ',,
/ ,,,
300 350 400 450 500
WAVELENGTH (nm)
Fig. 3b. Photoexcited emission spectra
of TGDDM smear (Xex = 301 nm)
and solid DDS (Xex = 290 rim).
6o
material. In this paper, we report the status of degradation modeling on the epoxy
system. An account of the work on PIVN has heen published and will not be discussed
here.
Experimental Methods and Results - The source of excitation is a Febertron (Hewlett-
Packard) which generates 3-ns pulses (FWHM) of 600-KeV electrons with approximately
I0 joules per pulse. Solid samples were placed in an evacuated sample chamber.
Fluorescence was collected by a quartz lens and was transmitted via a fiber optics
assembly to a I/4-m monochromator. The spectrally resolved emission was then moni-
tored by a IP-28 phototube, the output of which was displayed on a Tektronix fast-
rise scope. Transient absorption measurements were carried out by using a xenon
flash lamp (2-_s pulses) as a probe beam incident on the sample approximately 20o to
the e-beam. After passing through the e-beam excited volume, the probe beam was
collected and transmitted via the fiber optics assembly, spectrally resolved and
analyzed as before. Figure I shows the experimental set up. Pure (neat) samples of
TGDDM, DDS, their mixtures, and cured specimens were studied by this technique. DDS
was exhaustively methylated to form NN'tetramethyl diaminodiphenyl sulfone (TMDDS).
A recrystallized sample of TMDDS was characterized by IR and NMR spectroscopy and
also by elemental analysis. TMDDS may be used as a model for DDS after it has be-
came part of the fully cross-linked network. Under actual conditions a more realis-
tic model will be some weighted statistical mixture of TMDDS, Tri-M DDS and DMDDS,
when Tri-M DDS and DMDDS are the trimethylated and dimethylated analogs of TMDDS.
Synthesis of these model compound is in progress. To obtain cured specimens, mix-
tures of TGDDM and DDS in appropriate mole ratios were heated in a vacuum oven at
175oc for five hours, and pumped overnight to remove any volatile matter. Optically
excited fluorescence spectra of these samples were recorded on a Perkin-Elmer MPF-3A
spectrofluorimeter.
NORMALIZED
EMISSION INTENSITY
t / \ (CURED AT 350°FI
i _ / _ 5 hours)
_ / _ _ UNCURED NAI_4CO
J _. / _ 5208 EPOXY
: Y \
350 408 450 500 550 600
WAVELENGTH(nm)
EMISSION INTENSITY
r_
,,,g
3OO
• DDS PELLET
0 UNCURED NARMCO
5208 EPOXY
WAVELENGTH ( nm )
Fig. 4. Photoexcited emission spectra
of cured and uncured NARMCO
5208 epoxy formulation
(_ex = 301 nm).
Fig. 5 Prompt emission spectra of
solid DDS, cured and uncured
NARMCO 5208 epoxy formulation
following pulsed electron
beam excitation.
61
Fluorescence spectra were also recorded on dilute solutions of the pure materials
and their mixtures in CH2CI 2. Figure 2 shows absorption spectra of TGDDM, DDS and
TMDDS in dilute solution. Figure 3a shows the emission spectra of DDS, TMDDS and
TGDDM in dilute CH2CI 2 solution while Figure 3b shows the same spectra taken on
TGDDM and DDS in neat form. Figure 4 shows the emission spectra of the uncured mix-
ture and the resin cured at 180°C (350F) for 5 hours. Figure 5 shows emission spec-
tra taken at O-5-ns delay following pulsed e-beam excitation on DDS, uncured mixture
and the cured resin. Figure 6 shows typical time profiles for the uncured mixture
as a function of wavelength. Table I gives fluorescence decay lifetimes measured on
these systems.
Discussion - Since the emission intensity from TGDDM is 80-150 times weaker than
that from DDS or TMDDS, it is expected that the emission of the mixture (cured or un-
cured) will be dominated by TMDDS or DDS fluorescence. Comparison of emission spec-
tra of DDS in dilute solution with the spectrum of neat DDS shows that it is consid-
erably red shifted in neat DDS. While the same effect is also observed in case of
TGDDM, it is not nearly as large. This result has been attributed to formation of
excited state complexes or excimers in these systems in which an excited molecule
interacts with a neighboring molecule in the ground state in approximate parallel
configuration with the excited molecule. Interaction between molecules of the same
species forms excimers, while interaction between two different species forms exci-
plexes. Excimers are not efficiently formed within the excited state lifetime of
DDS in dilute solution, since the formation of excimers is a bimolecular process and
requires multiple diffusive encounters. Excimer formation is found to be not nearly
as important in case of TGDDM as it is for DDS. The uncured mixture should then
show evidence of formation of two excimers as well as a heterogeneous complex, the
exciplex between DDS and TGDDM. The emission envelope of the uncured mixture (Fiq-
ure 3b) does indeed have three segments approximately corresponding to emissions
NORMALIZED
EMISSIONINTENSI_
a, _,Onm
b. 3gOnm
i _ _"---I _ I I I I I
0 20 40 60 80 100 120 140 160 180 200
TIME(nsec)
Table I. Fluorescence Decay Times
Following Pulse Radiolysis
SYSTEM X(nm) TFAST (r'4,ec) T SLOW (nsec)
TGDDM
DDS
UNCURED NARMCO 5208
CURED NA,RMCO 5208
(350°F, 5 bs)
350
45O
350-450
34O
470
470
-<5
<-5
<5
18-22
<-5
10-20
10-15
10-20
85-100
MULTI-
EXPONENTIAL
Fig. 6. Time-resolved emission from
uncured NARMCO 5208 epoxy
formulation following 3-nsec
pulsed electron beam
excitation.
62
from these three species. However, diffusive encounters of two molecules or sub-
stantial, rapid molecular rotation is eliminated on network formation, and hence
only a trace amount of excimer formation is expected in cured specimens, when the
exciting photon happens to be incident on a methylated DDS molecule in a preformed,
configuration position with a TGDDM or another methylated DDS molecule. Hence the
emission spectrum of the cured system is blue shifted and largely resembles a com-
bination of emission spectra from methylated DDS molecules. Scheme I may be pro-
posed to interpret the optical excitation data,
hv
R _ R1.
R1. + R _ [RR] 1.
RI* _ R + hvI (345 nm)
[RR]I* . .
R+A
etc
v
2R + hv 2 (360 nm)
hv
A _ A I*
2R +A
etc
A1. + A --, [AA] 1.
A1. _ A + hv3 (330 nm)
etc
[AA] I* _ 2A + hv4 (385 nm)
I._.__, etc
AI* + R or RI* + A _ [AR] I*
[AR] 1. _ A + R + hv5 (445 nm)
[AR] I* _ A + R + A
I.._.__ etc
Scheme 1
where A is DDS and R is TGDDM scheme 1. In scheme I, [AA] I* is the DDS excimer,
[RR] 1. is the TGDDM excimer, while [AR] 1. is the exciplex. These excited state com-
plexes have no ground state counterpart, since there is no ground state complex for-
mation in this system, as determined by monitoring electronic spectra as a function
of concentration. In other words, the excimers and the exciplex have potential
63
of concentration. In other words, the excimers and the exciplex have potential
minima in the excited state but no such minimum in the ground electronic state. The
nature of electronic interaction leading to stabilization of EAR] I* is not under-
stood clearly, but it seems that there is a considerable deqree of charge transfer,
allowing mixin_ of higher excited states of A and R in [AR] 1.. Under favorable con-
ditions, [AR] z may be dissociated to form radical cations and anions. This experi-
ment is in progress, and if successful, will produce useful insight into the nature
of bonding in [AR] I* and hence its reactivity and lifetime.
The primary products of e-beam excitation are radical cations and anions. Recombin-
ation takes place through the back transfer of an electron from the anion to the ca-
tion. Within the spur, the ions are nearest neighbors and recombination is u_tra-
fast, being essentially complete in less than I0 ps. Outside of the spur, recombin-
ation requires migration or hopping of the electrons from the anion until it encoun-
ters a cation• Normally,this recombination would lead to the formation of excited
states such as RI* or Az . However in that case, the emission spectra following
pulse radiolysis would be identical to that observed on optical excitation, except
for perhaps a measurable time delay in the onset of fluorescence following pulse ra-
diolysis. This is found to be the case for TGDDM, DDS and the uncured mixture, but
the emission spectrum of the cured resin is considerably red shifted following e-
beam excitation. This red shift may be rationalized as being due to direct forma-
tion of exciplexes when adjacent ionic species interact and seek to recombine within
the rigid network, particularly since the exciplex is expected to incorporate a con-
siderable degree of charge separation. Hence Scheme 2 may be proposed to interpret
pulse raaiolysis data:
e- •
R _. R+" + R-
R+'+ R-" ) R1. + R
RI* _ etc
e-
A : A+'+ A-"
AI* _ etc
A-'+ R+" _ [AR] 1. _ etc
Scheme 2
Fluorescence decay of uncured mixtures is found to have three single exponential de-
cay components (Table I). The fast component (_ = 5 ns) increases in amplitude at
shorter wavelengths (300-390 nm) and is assigned to the TGOOMmonomers (R]*). There
is a slow component of variable lifetime (c = 70-90 ns) occurin_ at longer wave-lengths (400-500 nm) which may be assigned to the exciplex (RA I ) A third com-
ponent having a lifetime of 10-25 ns, occurs at intermediate wavelengths and
is tentatively assigned to the DDS excimer AAI*.
The mechanism of excimer and exciplex formation from AI* and R1. as observed on op-
tical excitation or directly from A- and R÷ as observed on pulse radiolysis on the
cured system, requires the postulation of fast migration of excited states and elec-
trons, since diffusive encounter rates even in uncured materials are not suffi-
ciently fast to explain the observed rate of onset of excimer and exciplex fluor-
escence. Preliminary estimation of these hopping frequencies put them at or above
64
fl_Qrescence. Preliminary estimation of these hopping requencies put them at or above
101U sec -I. Such fast hopping processes allow the possibility of quenching or trap-
ping the excitation energy as well as charges by placing quenchers or acceptors in
the matrix. Less than 2 mole percent of quencher concentration is sufficient. Then
the matrix can be depleted of its excitation energy before bond cleavage can take
place. In preliminary experiments > 90% quenching of energy in PIVN was demon-
strated by using I mole percent of anthracene traps. Additives for radiation sta-
bilization may be developed according to these quenching criteria. For the TGDDM-
DDS system, the initial additive being tested is TMDDS, which is compatible to the
network, does not change its chemistry, and acts as a shallow trap of excita-
tion and electrons,
65



Pulsed radiolysis of model aromatic polymers and epoxy based matrix materials

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