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Surface modification of MgO filler by radiation
Rodiot. Printed
Phys. Chem. Vol. in Great Britain
42, Nos
l-3,
pp. 77-80,
0146-5724/93
1993
Pergamon
$6.00
+ 0.00
Press
Ltd
SURFACEMODIFICATIONOF NgO FILLER BY RADIATION
Feng Yuding, (Department
Huang Guanglin,Gan
of ChemistryrSichuan
Chonglin,
Chen Zefang
Universityr610084,P.R.China)
Abstract Direct radiation method has been used to graft methyl methaorylateMlA) onto magnesium oxide(Ng0) powder. surface The graft products were oharacterized by FT-IRS X-ray diffraction. Their properties were studied by ESCAI SEH and &termination of water contact angle. The grafted RgO was used as a filler of HDPE. The experimental results showed that the dispersibility of MgO in polymer matrix is remarkably improved, when the NgO is grafted with MA. The tensile strength and elongation percentage at break of HDPE filled the modified MgO were higher than those of unmodified. When the HDPE was filled by modified MgO, its thermal stability was remarkably improved.
Keywords:
Ragnesium oxides
Filler.
Radiation
grafting,
Surface
modification.
Magnesium oxide #gOI is one of the important fillers used in polymer materials. Low molecular weight coupling agenttsuch as titanate* aluminate, phosphate etc.) is always used to improve the compatibility between filler and polymer matrixt but it is easily fallen from filler during processing, because the coupling-bridge between polymer and filler is not covalent bond. In resent years* using grafting method to modify the (R.Laible. 1980). Because grafted polymer chain surfaoe duing prooessingr thus the properties of studies on surface modification of carbon black by 1990; N.Tsubokawa) .
surface properties of filler is developed can not fall from inorganic mater ial complex materials can be improved. Some chemical grafting were reported(K.Fujiki.
In the present paper* direct radiation method has been used to graft MA onto MgO powder filler. The properties of grafted MgO were studied. Further more? the effects of grafted Kg0 on the properties of HDPE were discussed.
Experimental 1. Grafting procedure and characterization of grafted copolymer: The RgO with MMAand solvent were irradiated at room temperature in air by 1.5 t4eV electron beams from a JJ-2 type accelerator. After irradidtionp the products were extracted with benzene for 24 hours in order to remove off ungrafted PNRA homopolymer. The weight increasing over k0 was characterized by FT-IRI X-ray diffractions SE% element analysis and water contact angle &termina,tion. 2. Blending with HDPE and the &termination of properties of filled HDPE: Blend grafted RgO with HDPE at ratio of 10: 90~ then press it to plate under 17
oil-compressor.
78
FENG
Determine
its
properties
Results 1.
1.
showed
results
obtained
method
coincided
DTA and
tension
of that
grafted
the
yield
increasing
with
each
other
Table
1.
Graft
Weight
was
increased
is
with
the
e I emcnt
method,
increasing
analysis
yield
of
MgO at
increeasing
different
Element
analysts
Thermal
method(%)
5.04
7.72
7.18
7.80
6
10.02
9.52
9.87
8
11.97
10.13
12.05
10
12.14
11.41
12.10
of
MgO and MgO-g-PMMA.
spectra
related
C=O vibration
to
C-H
vibration
The
gravity
gravity
5.43
FT-IR
dose.
thermal
method(%)
4
the
irradiated and
doses
2
1700cm’-’
of
method
reliably.
method(I)
Fig.1
tester.
copolymer:
graft
by weight
doses(Mradr
and
et al.
and Discussion
Characterization
Table
by SEM,
YUDING
peak.
5.21
It
800-1400cm-’ can
related
be known
that
to
MMA has
been
peak,
grafted
onto
MgO powder.
F-Fig.1.
FT-IR
spectra
grafted
of
MgO and
20'
Fig.2.
X-ray
MgO.
of
structure
influence chain peak 2.
of
into at
7’
Surface
Fig.3.
indicated
properties the
but
MgO was determined
grafted
structure
on crystal
MgO crystalpits
showed
much looset
of
grafting
surface
that
the
of
grafted
grafting.
of
by
of
X-ray
the
grafting
schame MgO
diffraction
samll
because
amorphous
(Fig. of
2)~
insertion
peaks
and
there of
the
is
less
grafting
non-crystal
chain.
copolymer: of the
MgO and grafted apparentness
of
MgO. The MgO became
apparentness compact.
b.
a. Fig.3.
65
diffraction
MgO and grafted
MgO. However,
was damaged,
existence
SEM photographs
after
50”
(a-MgO; b-MgO-g-PM?4A)
(a-MgO; b-MgO-g-PMMA) Crystal
35”
SEM photographs
of
MgO and grafted
(a-MgO;b-MgO-g-PMMA)
MgO.(XSOOO)
of
ungrafted
MgO was
8th International
Fig.
4a-4b
were
binding
energy
more
shifting
the
level.
It
Cl., of
01. Cl.
ESCA spectra is
shifted
extent.
was supposed
Howevert that
of
to
Meeting
on Radiation
grafted
copolymerr
lower
the
energy
binding
energy
of
C=O was formed
covalent
respectively.
p and
level
19
Processing
the
01.
were
between
It
higher
the
the
can
be
graft
shifted
to
lattice
0
seen
yield
that
is.
higher
the
energy
in HgO and
B-C
in
=H, HHA. i.e.*
Ch arge
(MgO),-(Ctls-6-L
cloud
of
lattice
0 biased
to
CI
and
charge
that
made the
charge
density
cOOLtij of
C increased.
binding
The
ratio
of
so
energy
of
0 to
graft
yield,
Fig.4a.
Ct.
its
binding
energy
decreased.
C was determined the
O/C
Binding
by ESCA.
water
increasing
contact
modificationpthe it
can
angle
of
grafted
2.
that
listed
Relationship
the
of
01.
in Table
of
0 decreased.
its
2.
With
the
increaing
EnergyCev)
ESCA spectra
O/C with
graft
graft
yield(Z)
o/c
1
3.
397
3.
358
7.72
3
2.
243
11.97
MgO plate
yield,
Fig.4b.
UgO
2
the
hydrophilicity
predict
were
Bindins
of
of
graft
Results
(eV)
Energv
ESCA spectra
sample
the
density
decreased.
Table
The
the
increased.
of
before
contact
angle
t4gO decreased9
compatibility
of
grafted
MgO
yield
5.43
was determined water
of
and
grafted
and after
became
the
grafting
hydrophobicity
MgO with
(Table
much bigger.
organic
That
increased.
polymer
3). is,
From
materials
With after theset
must
be
increased. Table
3.
Determination
of
samp I e
water
graft
yield(X)
1
The effects
Fig.5. matrix* well,
of
showed the
modified
unmodified
i.e.rits
(a--filled
with
yield(Z)
Spread
2
3.
356
7.72
2.
243
11.97
of
with
properties
unmodified
polymer
of
MgO
out
HDPE:
and modified
appeared
modified
5.43
obviously,
matrix
is
a Fig.S.SEH
graft
3
higO particals
compatibility
of
397
3.
MgO on the
SEM photographs
angle
0
W
3.
contact
MgO with
HDPE.
however*
modified
We can
much better.
b photographs 107, MgO;
of b--filled
HDPE filled with
with
MgO.(XSOOO,
107, G%=7.727.
modified
&O)
MgO
see
thattin
dispersed
HDPE very
80
FENG YUDING
et al.
Table 4. showed the effects of modified and unmodified HgO on break elongation percentage and break strength of BDPE. It can be seen that the elongation decreased with the adding of filler. But the elongation percentage of HDPE with modified BgO is higher than that with unmodified )IgOr beoause of the increasing of oompatibility. And the break strength is the same tendency. Table 4. The effects Sample
of modified
Break strength(N/sm?)
Pure HDPE
MgO on mechantical Break elongation
properties percentage(X)
25.6
800
HDPE filled
10X m-I&O 18.2
600
HDPE filled
10X u-k&l
450
12.7
of HDPE.
Fig. 6-7 showed the DTA and TCA picture of HDPE and blend of HDPE with modified adding of modified RgO, the thermal stability of HDPE was increased. The melting 25“ Grand the maximum weight-loss temparature increased 40” C. loo 83 60
1
40 x 0L 0 1mmmmsa3 T ( “C.1
Y-+= lal
Fig.6. The TCA schame of HDPE. (a-pure HDPE;b-HDPE filled 10X G%=7.72% m-MgO)
M) -
Fig.7. The DTA schame of HDPE. (a-pure HDPE:b-HDPE filled 1071 Ci%=7.72%m-t4gO)
References Adv.Colloid Interface 5ci.t 1. R. Laib1e.t Po1ym.J.t 22(8),661(1990). 2. K. Fujiki., 3. N. Tsubokawa.r Po1ym.J.e 22(93.827(1690).
2co T( T 1
600
13,65(1680).
MgO. With the point arised
Phys. Chem. Vol. in Great Britain
42, Nos
l-3,
pp. 77-80,
0146-5724/93
1993
Pergamon
$6.00
+ 0.00
Press
Ltd
SURFACEMODIFICATIONOF NgO FILLER BY RADIATION
Feng Yuding, (Department
Huang Guanglin,Gan
of ChemistryrSichuan
Chonglin,
Chen Zefang
Universityr610084,P.R.China)
Abstract Direct radiation method has been used to graft methyl methaorylateMlA) onto magnesium oxide(Ng0) powder. surface The graft products were oharacterized by FT-IRS X-ray diffraction. Their properties were studied by ESCAI SEH and &termination of water contact angle. The grafted RgO was used as a filler of HDPE. The experimental results showed that the dispersibility of MgO in polymer matrix is remarkably improved, when the NgO is grafted with MA. The tensile strength and elongation percentage at break of HDPE filled the modified MgO were higher than those of unmodified. When the HDPE was filled by modified MgO, its thermal stability was remarkably improved.
Keywords:
Ragnesium oxides
Filler.
Radiation
grafting,
Surface
modification.
Magnesium oxide #gOI is one of the important fillers used in polymer materials. Low molecular weight coupling agenttsuch as titanate* aluminate, phosphate etc.) is always used to improve the compatibility between filler and polymer matrixt but it is easily fallen from filler during processing, because the coupling-bridge between polymer and filler is not covalent bond. In resent years* using grafting method to modify the (R.Laible. 1980). Because grafted polymer chain surfaoe duing prooessingr thus the properties of studies on surface modification of carbon black by 1990; N.Tsubokawa) .
surface properties of filler is developed can not fall from inorganic mater ial complex materials can be improved. Some chemical grafting were reported(K.Fujiki.
In the present paper* direct radiation method has been used to graft MA onto MgO powder filler. The properties of grafted MgO were studied. Further more? the effects of grafted Kg0 on the properties of HDPE were discussed.
Experimental 1. Grafting procedure and characterization of grafted copolymer: The RgO with MMAand solvent were irradiated at room temperature in air by 1.5 t4eV electron beams from a JJ-2 type accelerator. After irradidtionp the products were extracted with benzene for 24 hours in order to remove off ungrafted PNRA homopolymer. The weight increasing over k0 was characterized by FT-IRI X-ray diffractions SE% element analysis and water contact angle &termina,tion. 2. Blending with HDPE and the &termination of properties of filled HDPE: Blend grafted RgO with HDPE at ratio of 10: 90~ then press it to plate under 17
oil-compressor.
78
FENG
Determine
its
properties
Results 1.
1.
showed
results
obtained
method
coincided
DTA and
tension
of that
grafted
the
yield
increasing
with
each
other
Table
1.
Graft
Weight
was
increased
is
with
the
e I emcnt
method,
increasing
analysis
yield
of
MgO at
increeasing
different
Element
analysts
Thermal
method(%)
5.04
7.72
7.18
7.80
6
10.02
9.52
9.87
8
11.97
10.13
12.05
10
12.14
11.41
12.10
of
MgO and MgO-g-PMMA.
spectra
related
C=O vibration
to
C-H
vibration
The
gravity
gravity
5.43
FT-IR
dose.
thermal
method(%)
4
the
irradiated and
doses
2
1700cm’-’
of
method
reliably.
method(I)
Fig.1
tester.
copolymer:
graft
by weight
doses(Mradr
and
et al.
and Discussion
Characterization
Table
by SEM,
YUDING
peak.
5.21
It
800-1400cm-’ can
related
be known
that
to
MMA has
been
peak,
grafted
onto
MgO powder.
F-Fig.1.
FT-IR
spectra
grafted
of
MgO and
20'
Fig.2.
X-ray
MgO.
of
structure
influence chain peak 2.
of
into at
7’
Surface
Fig.3.
indicated
properties the
but
MgO was determined
grafted
structure
on crystal
MgO crystalpits
showed
much looset
of
grafting
surface
that
the
of
grafted
grafting.
of
by
of
X-ray
the
grafting
schame MgO
diffraction
samll
because
amorphous
(Fig. of
2)~
insertion
peaks
and
there of
the
is
less
grafting
non-crystal
chain.
copolymer: of the
MgO and grafted apparentness
of
MgO. The MgO became
apparentness compact.
b.
a. Fig.3.
65
diffraction
MgO and grafted
MgO. However,
was damaged,
existence
SEM photographs
after
50”
(a-MgO; b-MgO-g-PM?4A)
(a-MgO; b-MgO-g-PMMA) Crystal
35”
SEM photographs
of
MgO and grafted
(a-MgO;b-MgO-g-PMMA)
MgO.(XSOOO)
of
ungrafted
MgO was
8th International
Fig.
4a-4b
were
binding
energy
more
shifting
the
level.
It
Cl., of
01. Cl.
ESCA spectra is
shifted
extent.
was supposed
Howevert that
of
to
Meeting
on Radiation
grafted
copolymerr
lower
the
energy
binding
energy
of
C=O was formed
covalent
respectively.
p and
level
19
Processing
the
01.
were
between
It
higher
the
the
can
be
graft
shifted
to
lattice
0
seen
yield
that
is.
higher
the
energy
in HgO and
B-C
in
=H, HHA. i.e.*
Ch arge
(MgO),-(Ctls-6-L
cloud
of
lattice
0 biased
to
CI
and
charge
that
made the
charge
density
cOOLtij of
C increased.
binding
The
ratio
of
so
energy
of
0 to
graft
yield,
Fig.4a.
Ct.
its
binding
energy
decreased.
C was determined the
O/C
Binding
by ESCA.
water
increasing
contact
modificationpthe it
can
angle
of
grafted
2.
that
listed
Relationship
the
of
01.
in Table
of
0 decreased.
its
2.
With
the
increaing
EnergyCev)
ESCA spectra
O/C with
graft
graft
yield(Z)
o/c
1
3.
397
3.
358
7.72
3
2.
243
11.97
MgO plate
yield,
Fig.4b.
UgO
2
the
hydrophilicity
predict
were
Bindins
of
of
graft
Results
(eV)
Energv
ESCA spectra
sample
the
density
decreased.
Table
The
the
increased.
of
before
contact
angle
t4gO decreased9
compatibility
of
grafted
MgO
yield
5.43
was determined water
of
and
grafted
and after
became
the
grafting
hydrophobicity
MgO with
(Table
much bigger.
organic
That
increased.
polymer
3). is,
From
materials
With after theset
must
be
increased. Table
3.
Determination
of
samp I e
water
graft
yield(X)
1
The effects
Fig.5. matrix* well,
of
showed the
modified
unmodified
i.e.rits
(a--filled
with
yield(Z)
Spread
2
3.
356
7.72
2.
243
11.97
of
with
properties
unmodified
polymer
of
MgO
out
HDPE:
and modified
appeared
modified
5.43
obviously,
matrix
is
a Fig.S.SEH
graft
3
higO particals
compatibility
of
397
3.
MgO on the
SEM photographs
angle
0
W
3.
contact
MgO with
HDPE.
however*
modified
We can
much better.
b photographs 107, MgO;
of b--filled
HDPE filled with
with
MgO.(XSOOO,
107, G%=7.727.
modified
&O)
MgO
see
thattin
dispersed
HDPE very
80
FENG YUDING
et al.
Table 4. showed the effects of modified and unmodified HgO on break elongation percentage and break strength of BDPE. It can be seen that the elongation decreased with the adding of filler. But the elongation percentage of HDPE with modified BgO is higher than that with unmodified )IgOr beoause of the increasing of oompatibility. And the break strength is the same tendency. Table 4. The effects Sample
of modified
Break strength(N/sm?)
Pure HDPE
MgO on mechantical Break elongation
properties percentage(X)
25.6
800
HDPE filled
10X m-I&O 18.2
600
HDPE filled
10X u-k&l
450
12.7
of HDPE.
Fig. 6-7 showed the DTA and TCA picture of HDPE and blend of HDPE with modified adding of modified RgO, the thermal stability of HDPE was increased. The melting 25“ Grand the maximum weight-loss temparature increased 40” C. loo 83 60
1
40 x 0L 0 1mmmmsa3 T ( “C.1
Y-+= lal
Fig.6. The TCA schame of HDPE. (a-pure HDPE;b-HDPE filled 10X G%=7.72% m-MgO)
M) -
Fig.7. The DTA schame of HDPE. (a-pure HDPE:b-HDPE filled 1071 Ci%=7.72%m-t4gO)
References Adv.Colloid Interface 5ci.t 1. R. Laib1e.t Po1ym.J.t 22(8),661(1990). 2. K. Fujiki., 3. N. Tsubokawa.r Po1ym.J.e 22(93.827(1690).
2co T( T 1
600
13,65(1680).
MgO. With the point arised