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Pervaporation of ethanol-water mixture by plasma films prepared from hexamethyldisiloxane
Desalination, 70 (1988) 465-479 Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
PERVAPORATION
OF EX-HANOL-WATER
MIXTURE
465
BY PLASMA
FILMS PREPARED
FROM HEXAMETHnDISILOXANE N. INAGAKI,
S. TASAKA
and Y. KOBAYASHI
Laboratory of Polymer 3-5-l Johoku, Hamamatsu,
Chemistry, Faculty 432 (JAPAN)
of
Engineering,
Shizuoka
University
SUMMARY The plasma polymerization process was investigated to obtain plasma films like poly(dimethylsiloxane), and the formed films were applied as membranes for pervaporation of ethanol-water solution. A reaction chamber which had the triode electrode structure for initiation of a glow discharge was provided for preparation of films like poly(dimethylsiloxane) by plasma polymerization. Films plasma-polymerized from hexamethyldisiloxane (HMDSO) resembled poly(dimethylsiloxane) in spectroscopic view and were composed of dimethylsiloxane chains with branches of trimethylsilyl groups. The surface energy for the films was 19.6 mN/m. The films deposited from HMDSO on membrane showed good ethanol-selectivity in Nuclepore pervaporation of ethanol-water solution. The separation factor depended on the film thickness as well as the feed composition. The film-thickness effect was maximized at 34 nm thick, and the separation factor reached 4.5. A model for the separation process using our composite membrane was discussed.
INTRODUCTION Pervaporation is
interpreted
interested of
is a separation
by
separation ethanol
of
ethanol
include
membranes
(refs.
from
silicon
blems
including
poor
nol in practical
use
from
its
ments
recombine and
of
is an unique Molecules
electrons,
to form
different
for
e.g.,
azeotropic
for
separation Hydra
but have
and swelling
process.
pro-
by etha-
or copolymerization
from
This uniqueness
conventional
into plasma
and
and fit
11-13).
thin-film
deposits
toughness,
are
solution.
selectivity
by cross-linking
(refs.
molecule.
finally
ethanol
ethanol
poor
introduced radicals,
a large
recombination
OOll-9164/88/$03.50
films
suitable
fermented the
Modification
of these reactions
or ionic.
e.g., show
membranes
solution,
are
are
for pervaporation
membranes
aqueos
membranes
process
investigators
water-selective
ethanol
properties,
3-10).
polymer-forming by actions
mentation,
(refs.
polymerization
such as radical mented
film-forming
for improvement
Plasma
1,2).
films
Many
Water-selective
solution,
polymer
The separation
1).
Membranes
types,
concentrated
ethanol
and fluoro
solution. (ref.
solution.
two
ethanol-selective
dilute
phobic
is applied
from
while
from model
of ethanol-water
solution
water
solution,
process
sorption-diffusion
in the separation
ethanol-water
ethanol-selective
of
the
ions,
and
The repetition polymers
0 1966 Elsevier Science Publishers B.V.
polymerizations
are activated then
and frag-
activated
frag-
of the activation,
frag-
(ref.
two
results
14).
Therefore,
the
466 formed even
polymers when
crosslinked
are
the
different
same
monomers
and superior
The aim of this by plasma
conventional
are
in mechanical
study
polymerzation
in pervaporation
from
The
used.
to
polymer
evaluate
of ethanol-water
plasma
in chemical polymers,
structure
generally,
are
properties.
is to prepare and
polymers
the
films
like poly(dimethylsiloxane)
performance
of
the
formed
films
solution.
EXPERIMENTAL Plasma
polymerization
The system mm
reactor
system
operating diameter,
at 470
(150 x 150 mm, trode), electrode
mm
two
a thickness
The electrodes
for
with
a monomer
plate
electrodes
monitor,
a vacuum
an aluminum
and the lower
electrode
50 mm space
of The V
the
frequency
was
applied
electrode
was
grounded
the
and glass
plates)
Triode
middle
on which
were
plasma
These
between and
the the
polymers
upper
lower (porous
deposited
coupled
of a bell
parallel
a triode
electrode
Substrates
electrode.
inlet,
three steel
electrodes
enhancement structure:
Schema
of the reaction
chamber
system.
set-up.
steel
electrodes
horizontally
were
(approximately and
the
electrode
middle was
membranes, were
mounted
silicon
mesh,
400 volts) electrode.
biased
at
-50
wafers,
on the surface
Thickness Meter
1.
elec-
The upper
*Thickness Monitor
Fig.
(400
mesh
l-
Vacuum System
jar
was a stainless
A high voltage
middle
capacitively
and a stainless
plate.
apart.
a
and a magnetic
middle
was an aluminum
20 kHz against
system,
of glow discharge plate,
was
It consisted
(af).
height)
positioned
at
polymerization
of 20 kHz
aluminum
for initiation
was
plasma
a frequency
467 of
the
lower
action
chamber The
the
electrode
same
as reported 0.13
cm3(STP)/min
current
sided
adhesive
represented
in Fig.
procedures
for
plasma
elsewhere
(ref.
Pa,
at
was turned
af current
double
is schematically
experimental
to approximately 4.8
with
and
15 Pa
then
was
on and the
the 15).
the
polymerization reaction
monomer into
of the
re-
were
system
essentially
was
evacuated
gas
adjusted
to a flow rate
of
the
reaction
chamber.
af
polymerization
(HMDSO)
(purchased
Japan),
ethynyltrimethylsilane
(ETMS),
Petrach
System
tetramethylsilane
Co.,
from
detail
was conducted
The
at a constant
of 20 mA.
Hexamethyldisiloxane
Kogyo
The
1.
The
introduced
plasma
tape.
Inc.,
U.S.A.),
Japan),
Petrach
and
System
from
Tokyo
trimethylvinylsilane
U.S.A.)
were
used
Kogyo
Co.,
(TMVS) (purchased
(TMS) (purchased
bis(dimethylamino)methylvinylsilane
Inc.,
Kasei from
(BDMAMVS)
as monomers
without
from
Tokyo Kasei (purchased
further
purifi-
cation.
Elemental
analysis
The C, H, and N contents with
a Yanagimoto after
as Si02 tent
was
a difference
of the between
plasma
The Si content
TM-2 analyzer.
combustion
and Si contents
of the deposited
polymers the
polymers
was determined
in an oxygen
sample
were
weight
gravimetrically
atmosphere.
and
the
sum
determined
The 0 con-
of the
C, H, N,
determined.
IR and XPS spectra IR spectra Bunko fourier
of the plasma transform
XPS spectra on silicon ploying
of
wafers
Mg K o
the
FT/IR-3.
polymers
(approximately
plasma recorded
with
a Shimadzu
exciting
radiation
at 8 kV and 30 mA.
of the binding
energy
recorded
with a Nihon
100 nm thick)
electronspectrometer The Au core
deposited 750 em-
level
at 84.0
scale.
energy
Contact phosphate “C
as a KBr disk were
spectrometer
were
eV was used for calibration
Surface
polymers
infrared
with
data
were
(ref.
16).
angles
against an
of
the
Erma
water,
plasma
glycerol, films
contactanglemeter
analyzed
to estimate
formamide,
deposited G-I with
the
surface
diiodomethane,
on glass
plate
were
a goniometer.
energy
according
and
tricresyl
measured
at
The
contact
to Kaelble’s
20
angle method
Pervaporation Composite
membranes,
and 30 nm; 6 urn the
plasma
thick)
polymers
porous
(purchased
prepared
from
polycarbonate from the
films
Nuclepore silicon
Co.,
(Nuclepore; U.S.A.)
compounds,
and
pore
were
size,
coated
served
for
15 with per-
468 vaporation
experiments.
The
composite
membrane the
area
membranes
of 13.8 cm’.
ethanol-water
a flow rate was kept through
solution
rate
a measured
of
The
permeation
estimated
from
in traps
the
JGC-ZOFP)
rate
with
glycol
the following
liquid
of the
the
membrane
The vapor
in the
column
at
permeated
trap
over
liquid was determined
a separation
a
membrane
The vapor
collected
with
at 25 “C and
by liquid nitrogen.
of the
and
cell
of the side
gauge.
1000 supported
(R in kg/m2-h)
steel
was kept
side
downstream
cooled
by weighing
10 % polyethylene
upper
a Pirani
and the composition
(JEOL,
2 m long)
of the cell
at the with
was condensed
of time,
a gas chromatograph
in a stainless
on the
The pressure
was determined
period
vapor
circulated
100 Pa by monitoring
membrane
permeation
positioned
The temperature
was
of 5 ml/min.
below the
were
with
(3 mm diameter,
on Flusin
T (60/80
separation
factor
mesh).
(a ) were
equations.
W R=43.5x
-
where
W and
(1)
t are
the
weight
(in g) of the
permeant
and the
permeation
time
(in min), respectively.
o
%2JCw2
=
(2)
‘El”W where
1
and CE2 are
CEl
respectively.
cw1 respectively.
meant,
the
ethanol
concentration
are the
and cw2
water
of the
concentration
feed
and the
of the
feed
permeant,
and the per-
RESULTS Chemical silicon
composition
surface
property
of
plasma
polymers
prepared
from
compounds To
obtain
of silicon A triode in this
poly(dimethylsiloxane)-like
compounds structure
study
structure
for
with
construction study) initiation
a reaction
with
voltage
A glow
for
electrodes,
first
This
which
electrode
triggered
polymerization
in Fig.
reaction
is biased high
discussed.
1, was employed from as the
system
a diode electrode
with
400 V was used
electrode
by the
was
is different
of approximately second
plasma
is a familiar
In the
and the
The third
discharge
from
polymerization
as shown
discharge.
(A voltage
the
films
plasma
electrodes,
a glow
polymerization.
of a glow discharge. electrode.
parallel
of parallel
between
thin
system
of
for plasma
a high
is applied
three
initiation
a pair
used
ode structure,
second
and
(mesh
the
in this
electrode)
at -50 V against voltage
tri-
is confined
for the to
469
a space bias
surrounded
of the
plasma
polymers
deposit
on
polymers tion
between
third
formed
the
could
surface avoid
system
with
the
irradiation
under of the been
deposited
films
Colorless, the
silicon
polymer
irradiation
(ref.
deposition
Table
not?
transparent
compounds
1 shows
polymers
was
prepared
those
influence plasma
irradiation
from
has
with
CVD.
structure
the conventional
damage
investigated
of
the
silicon
influence
plasma
from
analysis
of
plasma the
which
polymerization
triode
was
l/3
structure. - l/4
of The
as slow
as
structure.
effects
the silicon
effect
by plasma
irradiation
from
chamber
of the diode
always
polymers.
deposited
reaction
reac-
are
of the triode
less
was
and plasma
and degradation
films
prepared of
plasma
1 - 2.5 ug/cm*-min,
chamber plasma
silicon chamber
the
polymers
This irradiation
reaction
Does
were
the
plasma
because
The
electrode,
deposited
polymerization,
somewhat.
with
mesh the
negative
space.
in the conventional
amorphous
the
The
films
using
rate
deposited
in the
the
While,
plasma
by the
occurs
through
the
structure 17).
electrode
Therefore,
the
of
with
for the formed
when used the reaction
plasma
or
down
irradiation.
compared
diode
composition
pass
will occur
preparation
second
electrode.
during
prepared
the
the
polymerization
structure
polymers
reactions
of chemical
and
plasma
properties of
by plasma
the
diode
films
chamber
polymerization
space third
in the
show good electrical reaction
in the of
of plasma
plasma
silicon
first
and plasma
possible
the
emphasized
Amorphous
the
electrode,
on
the
compounds.
elemental The plasma
composition
of
polymerizations
TABLE 1 Elemental under
composition
of
plasma
polymers
prepared
No plasma
TMS
W/FM (MJ/kg) 246
C2.4H6.701.3Si
217
TMVS
irradiation Atomic
K4H12SiJ* (C5H12Si)
ratio
C2.3H5.601.4Si
ETMS (C5H10Si)
101
C2.7H5.701.8Si
HMDSO (C3Hg00.5SiJ
170
C2.8H8.702.4Si
BDMAMVS K7H18N2SiJ
160
‘4 . 6H10 . 3’1 . gNt . tsi
:
plasma
irradiation
no irradiation.
Monomers
*
under
Atomic
ratio
of the monomers.
Plasma
irradiation
W/FM (MJkg)
Atomic
290
C3,7H8.201.1N0.2Si
290
‘5
170
‘6 . 6H12 . 9’1 . BNO. lsi
120
C2.6H5.601.3Si
ratio
. BHll . 3’1 . gsi
and
470 were
performed
MJkg). tative
The W/FM expression
apparent
input
electrical and
under
observe
some
formed
under
differences
yielded
in silicon
content.
mass
of
of the
polymers
poor
C/S1 and H/Si
atomic
TMS, TMVS, and ETMS, shown
irradiation), atron),
2.4 and 6.7 (under
2.3 and
2.7
and
the
plasma
tinctive (Si2p core
5.7
5.6 (under
(under polymers
differences level)
monomer,
where
was could
of typical
Binding
1.3 -
(in J/set),
no irradiation);
1.8 independently
plasma
polymers
the
plasma 3.7 and
However, of the
prepared
We could
content
and rich
polymers
prepared
8.2 (under
plasma
plasma
plasma
O/Si plasma
polymers No plasma
irradi-
irradiation),
atomic
ratio
irradiation.
Fig. 2 shows from
an
(in mol/sec),
plasma
11.3 (under
12.9 (under
in XPS spectra.
means
W, F, and M are the flow rate
and hydrogen
5.8 and
respectively.
for quanti-
no irradiation:
for the
6.6 and
100 - 300
parameter
between
1, were
of
respectively.
under
in carbon
in Table
be observed
the
(in kg/mol),
ratios
values
14) was used
W/FM
formed
no irradiation);
no irradiation),
(ref.
composition
and those
W/FM
The
monomer
in elemental
irradiation
plasma
the
(at
by Yasuda
conditions.
for a glow discharge
weight
plasma
conditions
proposed
operating
per unit
energy
irradiation
from
the
energy
molecular
operating
parameter
of
input
the
similar
for Dis-
XPS spectra
TMVS and ETMS.
The
Energy (eV)
for plasma polymers prepared from TMVS (A, A’) and ETMS Fig. 2. XPS spectra (B, B’) under plasma irradiation (A’, B’) and under no irradiation (A, B).
471 plasma with
polymers peaks
mers
not
different mers
be
completely
oxidation
formed
peak
Sizp geneous the
near
levels
sense
preparation
irradiation
but
103 eV with that states may
reaction
of plasma
with
surely
of
with
the
from
Wave Fig. 3. IR spectra methylsiloxane) (B).
resembled
Number of
plasma
100.9,
These
peaks
silicon
atoms
poly-
Si spectrum
silicon
Conclusively, structure
having
plasma
moieties
whose of the hetero-
the
restriction
of silicon
moieties.
may be adequate
for
like poly(dimethylsiloxane).
spectroscopic
HMDSO
100.2,
The comparison
makes
homogeneity
triode
99.6,
Si spectra 2P plasma poly-
ETMS.
While the
of 3 eV.
view
among
the
HMDSO, TMS, TMVS, ETMS, and BDMAMVS showed
prepared
to
a symmetric
atoms). for
at
from
18-21).
irradiation
silicon
peaks
related
showed
be favorable
complex
103.7 eV for the
prepared
a FWHM value
chamber
polymers
from
are
the plasma
oxidation
showed
102.6, and
irradiation
irradiation the
Comparison from
plasma 102.2,
@iOx, x = 1 - 4) (refs.
no plasma
indicates
(many plasma
In this
the
101.8,
assigned
number
under
appeared core
under
100.2,
from TMVS, and Si spectra 2P 103.6 eV for the plasma polymers
102.2,
could
of
99.6,
prepared
101.8,
formed
at
mostly
plasma that
polymers the
prepared
plasma
poly(dimethylsiloxane).
Fig.
prepared
(A) and
polymers
3 shows
IR
x 10-Z(cm-l) polymers
from
HMDSO
polyfdi-
472 spectra
for
(PS048,
purchased
absorption
plasma
CH3
streching
and 617 cm -’ ported
that
the
dimethylsilyl ((CH3)3Si-), for both
C-H
and
HMDSO
methylsilyl
the
may
be
in CH3
(ref.
2967
(C-H
22).
vibration
deformation we assume
composed
dimethylsiloxane
streching
860,
Smith
(ref.
796,
in sym700,
23) has re-
appears at 1412 cm-l in -1 . in trimethylsilyl groups
vibration that
groups),
1260 (C-H
streching),
1454 and 1415 cm
symmetric
shows
in CH3 groups).
in CH3 groups),
the reference of
at
1020 (Si-0
deformation and at
appears
the plasma chains
at
1260 cm-l
polymers
with
prepared
branches
of tri-
moieties.
Table
2 shows
the
critical
surface
from
TMS, TMVS, ETMS, HMDSO,
from
HMDSO
possessed
methylsiloxane) which
1087,
in CH3 groups)
asymmetric
From
polymers
1454, 1408 (C-H asymmetric
peaks
deformation
groups),
((CH3)2Si-)
that
groups.
poly(dimethylsiloxane) plasma
symmetric deformation -1 (C-H deformation
absorption
asymmetric
deformation
groups
and The
799, and 686 cm
in CH3
(C-H
HMDSO U.S.A.).
in CH3 groups),
shows
1410 (C-H
deformation
Inc.
1257 (C-H
841,
poly(dimethylsiloxane)
metric
from
System
groups),
streching),
CH3 groups),
from
prepared
Petrach
at 2960(C-H
of
1044 (Si-0 While,
from
peaks
deformation
polymers
This table
a surface
(22.1
contained
mN/m).
nitrogen
indicates
energy
The
moieties,
that
these
energy
of the
and BDMAMVS. of
plasma
polymers polymers
19.6
mN/m
polymers
possessed
plasma
plasma
The plasma
higher
polymers
comparable
prepared
surface
possess
from
energy
hydrophobic
prepared prepared to
poly(di-
BDMAMVS,
of 34.1 mN/m. surfaces.
TABLE 2 Surface
energy
of plasma Surface
Monomers
energy
Surface
energy
Pervaporation The
24.2 29.6 29.3 19.6 34.1
Y,
23.6 29.2 21.3 17.3 22.0
0.6 0.4 8.0 2.4 12.1
of Nuclepore
polymers
membrane
experiments. on
( Y,) = Y sd
with plasma
plasma
pervaporation
Nuclepore of
(mN/m)
Y,d
YS
TMS TMVS ETMS HMDSO BDMAMVS
polymers.
+ Y sp
polymer prepared
(pore
size
membrane ethanol-water
membranes from
HMDSO
were
deposited
15 nm) and used as membranes itself,
as shown
solution.
The
in Fig. permeants
on the
surface
for pervaporation
4, had through
no influence Nuclepore
473
0
10
20
Ethanol Concentration
30
in Feed (wt%)
Fig. 4. Permeant composition through as a function of feed composition.
membrane
had
concentration
the of the
the azeotropic Fig. the
5 shows
feed
solution
typical
(a)
factor
varied
results of
was
indicating
plasma
films
increasing
the
near
20 wt%
ethanol.
including
silicon
plasma
films
lost
ration
of 4 wt%
as a function out
at
ethanol
and fluorine that
the
34, and 41 nm thick of the
thin
ethanol possessed
ethanol
even
size,
when
15 nm)
the
ethanol
This indicates
that
ethanol
film
prepared the
that
solution
from
composite
depended
using
HMDSO.
The
membrane
strongly
composition.
concentration
A similar
feed
of the
in pervaporation
an
The separation
of the
dependence
is
on the thicksolution, separation
using other
memb-
polymers. plasma
films
showed
selectivity:
For
a separation
factor
solution,
concentrations
of ethanol-water
factor
feed composition has been observed
It is of interest
(pore
0 to 100 wt%.
as well as the feed
with
ranes
solution
polymers
The separation
decreased
on the
from
plasma
and became unity factor
feed
in pervaporation
the 4.5,
membrane.
ness of the deposited
as the
membrane
occurred.
membranes
ethanol-selective factor
composition
pervaporation
composite
separation
same
Nuclepore
respectively.
thickness.
The
ethanol
example,
the
plasma
but films
thick of 27,
of 4.5, 3.1, and 1.0 in pervapo-
Fig. 6 shows pervaporation
of 4 and 8 wt%.
selectivity
The
the
separation
experiments separation
were factor
factor carried increased
474
4
0
5
10
15 20
25 30
Ethanol Concentration in Feed
(wt%)
Fig. 5. Separation factor Ca, (),a ) and flux (A, 0, n ) as a function of ethanol concentration in feed; plasma film thickness de osited on Nuclepore, 27 nm thick, A , A ; 34 nm thick,0 , l ; 41 nm thick, 0 , 4.
:,A, :;,
’
57
0
0
10
20
30
40
50
100
200
300
400
Plasma Film Thickness (nm> Fig. 6. Separation factor in pervaporation nol, 0, 0 and 8 wt%, A 1 as a function size 15 nm; 0, 30 nm. with
increasing
4 wt% at
ethanol
used
film
thickness,
reached
and 3.8 at 8 wt% ethanol),
41 nm thick.
another was
the
of ethanol-water of plasma film
Nuclepore
A similar having
as a substrate
effect
a larger (Fig.
6).
of the pore The
a maximum and afterward
size
film
thickness
solution thickness;
at
34 nm thick
decreased could
of 30 nm instead
separation
factor
(4 wt% etha0, A, pore
was
rapidly
(4.5
at
to unity
be observed
when
of 15 nm pore
size
maximized
at
200
475 nm thick
and was
producible
evidence
from
HMDSO
maximum could
the
independent
of
thickness
also
showed
separation
the
factor
and
effect
substrates.
other
ETMS (a = 4.5),
ethanol the
The
is not
selectivity.
surface
haphazard
plasma
and
films
of
the
prepared
BDMAMVS
A relationship
energy
but re-
(a = 2.1)
between
deposited
the
plasma
films
were
com-
not be observed. The performance
pared
with
rate
for
sited for
Therefore,
(a = 1.5), TMVS (~1 = 3.4),
TMS
besides
3.1.
those
our
on
composite
Nuclepore,
pervaporation The
polymers
tributes
from
10 to
and
hydrophobic
plasma 0.46
solution,
in this
The table
and permeation
HMDSO and depo-
been
in the
separation and the
permeation
3 summarizes
have
listed
The
study
and the
from
Table
which
properties,
factor
prepared
membranes
10-2 kg/m’-h. ability
films
kg/m’-h.
surface.
on polymer
formed
The separation
ethanol-selective
of 3.0 to 25 depending
yet good in separation
4.5
ethanol-water
with
membrane
membranes.
membrane, was
of
investigators. fluoro
of the composite
of other
table
factor
are
that
by many silicon
is in the
permeation
indicates
membranes
prepared
rate
widely
our membrane
or
range dis-
is not
rate.
TABLE 3 Performance
of membranes
Membranes
Ethanol cont. in feed(wt%)
Plasma films from HMDSO Styrene-dimethylsiloxane copolymer Styrene-fluoroalkyl acrylate graft copolymer Polydimethylsiloxane block copolymer Poly[l-(trimethylsilyl)1-propyne] Zeolite-filled silicon rubber Gore-Tex *:
in pervaporation
of ethanol-water
Separation factor
solution.
Flux (kg-m/m*-h)
Reference
0.46*
ours 12
4
4.5
7
3.1-25
l.l-2.7~10-~
8
16.3-45
0.6-l.l~lO-~
24 -6
10
5.7-9.4
1.1-5.6x10
10
11.2
1.15x1o-3
25
5-5.5
14.9-16.5
3.6-5.1~10-~
26
a
3-5.5
3.3-6.1
27
13
in kg/m’-h.
DISCUSSION
The separation interpreted
in understanding rate,
but
especially
process
by the does the
in pervaporation
sorption-diffusion membrane
not
completely
film-thickness
model.
behaviors
such
explain effect
of ethanol-water The concept as
ethanol
characteristics
as illustrated
solution of the
is frequently
model
selectivity
and
of our composite Fig.
6.
Why does
the
is helpful permeation membrane, separation
476 factor
reach
the maximum
Firstly, banes
we discuss
porous
complete
at 34 nm thick?
or
plugging
films
about
result
into
the
non-porous of pores
five
times
pores
ments
showed
which
was
the
about
lo3
times
of membrane
as thick
consideration
to plug the
membrane
membranes?
of Nuclepore
that
the
same
when
the
composite
membranes
nm may be not non-porous
The surface concentration, 69.56
mN/m
and 28.93 tension
by
tension
especially (water),
mN/m the
at
Preferential Sorption
Fig. 7.
48.25
A tentative
less
model
(ref.
ethanol
Capillary Streaming
size.
15 nm). the
that
of plasma
Taking
Sakata’s
may be a critical
thickness
Permeation composite
pervaporation
with
with
solution 20 wt%.
at
8 wt%
30).
experimembrane
experiment
Therefore
became
polymers
than
34
35.50
adsorption
on the
ethanol
at
40 “C is
tension mN/m
with composite
at
decrease of
ethanol
Evaporation
for pervaporation
conclude
thinner
strongly
surface
an exponential
the
we
micropores.
depends The
ethanol,
Such
suggests
thick.
plasma
membranes
than
mN/m
of
pore
mem-
reported
the deposition
across
the
41 nm
deposited
of ethanol-water
41.6 wt%
addition
at
but porous
at
rate
for
permeation rate was 1 x -5 3 x 10 cms(STP)/cm’-see-cmHg
that
size,
our composite
deposition was over 34 nm thick. Actually, the -2 10 cm’(STP)/cm*-set-cmHg at 27 nm thick
nitrogen and
(pore
as used
the
requires
membrane
permeation
specimen
less
28,291 has
(refs.
of 34 nm thick
membrane
nitrogen
Are
Sakata surfaces
as the
the deposition
construction.
membranes.
19.6 wt%, in surface molecules
477 at
the
31)
interface
have
ethanol-water of
at the
On the
membranes
have
are
then
basis
separation
at the
above
using our composite
stage
(ref.
at
flow)
for
the
would
preferetial it
be
is
assumed
and ethanol-water
propose
out.
model
The composite
in size.
Ethanol
of the
micropores,
wall
The separation
micropore.
reverse
a tentative
(Fig. 7).
molecules
hydrophobic
The concept
size.
and
Consequently,
membrane
membranes
the wall of the
(ref.
materials
with the solution.
to two the
co-workers
assumed
molecules
we could
evaporated
micropore
ferential-sorption-capillary Sourirajan
consideration
comparable
onto
to the
ethanol
contacted
of the
are
and
surface.
of our composite
process
molecules
adsorption
may be related
of
and
membrane
hydrophobic
adsorption
adsorbed
Morimoto
between
calorimetry,
membrane
micropores
adsorbed
solution.
the
the surface
predominantly
the
at
similar
between
the
interaction
immersion
when the composite
for the
and
molecules
that
interface
cules
from
ethanol
unreasonable
solution
air the
solution
adsorption not
between
discussed
mole-
operates
and mainly
The film-thickness is similar
osmosis
to the
membranes
effect
model
(pre-
proposed
by
32).
CONCLUSION The like
plasma
pervaporation process
restriction
is favorable
reaction
the plasma
process
and
of ethanol-water
The
1. The
polymerization
poly(dimethylsiloxane),
chamber
the
the
to
were
obtain
applied
of silicon
during
moieties
electrode
films for
as follows.
plasma
of the
structure
for preparation
plasma
as membranes
are summarized
irradiation
triode
and is available
investigated films
Results
plasma
homogeneity with
irradiation
was
formed
solution.
of
for
the
polymerization
formed
restricts
of plasma
polymers.
influences
films
of
like poly(di-
methylsiloxane). Films
2.
plasma-polymerized
from
poly(dimethylsiloxane)
in spectroscopic
chains
of
with
branches
trimethylsilyl
hexamethyldisiloxane
view
and
are
(HMDSO)
composed
groups.
The
surface
from
HMDSO
and
resemble
of dimethylsiloxane energy
for
the
films
is 19.6 mN/m. The
3. membrane
show
The separation tion.
The
factor
reaches 4.
ranes wall
films
good ethanol-selectivity factor
molecules
depends
film-thickness
A tentative micropores are
on the
effect
in pervaporation film
thickness
deposited
on Nuclepore
of ethanol-water
as well
as the
is maximized
at 34 nm thick,
the
separation
process
adsorption
of ethanol
solution.
feed
and the
composiseparation
4.5.
is proposed. of
plasma-polymerized
model
for
The preferential of
evaporated.
the
composite
membranes,
The separation
onto the wall of the micropores.
operates
and
using
our composite
molecules then
mainly
the at the
occurs
adsorbed adsorption
membat
the
ethanol stage
478 REFERENCES
4
5
6
7
8 9 10 11
12
13 14 15 16 17 18 19 20 21 22 23 24
M. Senoo, Maku no Kagaku (in Japanese) Dainippon Tosho, Tokyo, 1987. K. Okamoto and H. Kita, Separation of water-organic compound mixtures by polymer membrane, Kobushi Kako, 34 (1985) 527-533. P. Aptel, J. Cuny, J. Jozefowicz, G. Morel and J. Neel, Liquid transport through membranes prepared by grafting of polar monomers onto poly(tetrafluoroethylene) films I., Fractionations of liquid mixtures by pervaporation, J. Appl. Polym. Sci., 16 (1972) 1061-1076. P. Aptel, J. Cuny, J. Jozefonvicz, G. Morel and J. Neel, Pervaporation through N-vinylpyrrolidone-gafted poly(tetrafluoroethylene) films, Eur. Polym. J., 9 (1973) 877-886. P. Aptel, J. Cuny, J. Jozefowica, G. Morel and J. Neel, Liquid transport through membranes prepared by grafting of polar monomers onto poly(tetrafluoroethylene) films II, Factor determing pervaporation rate and selectivity, J. Appl. Polym. Sci., 18 (1974) 351-364. P. Aptel, J. Cuny, J. Jozefowicz, G. Morel and J. Neel, Liquid transport through membranes prepared by grafting of polar monomers onto poly(tetrafluoroethylene) films III, Steady-state distribution in membranes during pervaporation, J. Appl. Polym. Sci., 18 (1974) 365-378. H. Eustache and G. Histi, Separation of aqueous organic mixtures by pervaporation and analysis by mass spectrometry or a coupled gas chromatograph-mass spectrometer, J. Membr. Sci., 8 (1981) 105-114. K. C. Hoover and S. T. Hwang, Pervaporation by a continuous membrane column, J. Membr. Sci., 10 (1982) 253-271. S. Kimura and T. Nomura, Pervaporation of organic substance-water system, Maku, 8 (1983) 177-183. M. H. V. Mulder, J. 0. Hendrikman, H. Hegeman and C. A. Smolders, Ethanol-water separation by pervaporation, J. Membr. Sci., 16 (1983) 269284. W. J. Ward III, W. R. Browall and R. M. Salemann, Ultrathin silicon/polycarbonate membranes for gas separation process, J. Membr. Sci., 1 (1976) 99-108. K. Ishihara, R. Kogure and K. Matsui, Separation of ethanol through styrenedimethylsiloxane grafted copolymer membranes by pervaporation, Kobunshi Ronbunshu, 43 (1986) 779-785. K. Okamoto, A. Butsuen, S. Tsuru, S. Nishioka, K. Tanaka, H. Kita and S. Asakawa, Preparation of water-ethanol mixtures through polydimethylsiloxane block-copolymer membranes, Polym. J., 19 (1987) 747-756. H. Yasuda, Plasma Polymerization, Academic Press, New York, 1985. N. lnagakf and M. Hashimoto, Application of plasma-films from tetramethyltin to gas sensor devices, Kobunshi Ronbunshu, 43 (1986) 711-716. D. H. Kaelble, Physical Chemistry of Adhesion, Wiley, New York, 1979. A. Matsuda, Plasma CVD and control of film properties, Proc. 3rd. Meeting on Plasma Processing, Kiryu (Japan), Jan. 28-30, 1986, pp. 61-64. R. Nordberg, H. Brecht, R. G. Albridge, A. Fahlman and J. R. Van Wazer, Binding energy of the “2~” electrons of silicon in various compounds, Inorg. Chem., 9 (1970) 2469-2474. R. G. Gray, J. C. Carver and D. M. Hercules, An ESCA study of organosilicon compounds, J. Electron Spect. Related Pheno., 8 (1976) 343-357. B. Carriere and J. P. Deville, X-ray photoelectron study of some siliconoxygen compounds, J. Electron Spect. Related Pheno., 10 (1977) 85-91. J. H. Thomas III and A. M. Goodman, AES and XPS studies of semi-insulating polycrystalline silicon (SIPOS) layers, J. Electrochem. Sot., 126 (1979) 1766-1770. L. J. Bellamy, The Infrared Spectra of Complex Molecules, Wiley, New York, 1964. A. L. Smith, Analysis of Silicon, Wiley, New York, 1974. K. Ishihara and K. Matsui, Pervaporation of ethanol-water mixture through composite membranes composed of styrene-fluoroalkyl acrylate graft copolymers and cross-linked polydimethylsiloxane membrane, J. Appl. Polym. Sci.,
479
25 26 27
28 29 30 31
32
34 (1987) 437-440. K. Ishihara, Y. Nagase and K. Mitsui, Pervaporation of alcohol/water mixtures through poly[l-(trimethylsilyl)-1-propynej membrane, Makromol. Chem., Rapid Commun., 7 (1986) 43-46. H. J. C. te Hennepe, D. Bargeman, M. H. V. Mulder and C. C. A. Smolders, Zeolite-filled silicon rubber membranes Part I, Membrane preparation and pervaporation results, J. Membr. Sci., 35 (1987) 39-55. E. Hoffmann, D. M. Pfenning, E. Philippsen, P. Schmahn, M. Sieber, R. Wehn and D. Woermann, Evaporation of alcohol/water mixtures through hydrophobic porous membranes, J. Membr. Sci., 34 (1987) 199-206. J. Sakata, M. Hirai and M. Yamamoto, Plasma polymerized membranes and gas permeability III, J. Appl. Polym. Sci., 34 (1987) 2701-2711. J. Sakata, Simulation of behavior of gas permeation in composite membranes prepared by the plasma polymerization method, Maku, 13 (1988) 45-50. and Physics, C. W. Robert and M. J. Astle eds., CRC Handbook of Chemical CRC Press, Boca Raton, 1981, pp. F-36. S. Morimoto, T. Tsuru, M. Ataka, K. Mizoguchi, K. Tsuda and Y. Suda, Immersion calorimetric study on the interaction between membrane-material and ethanol aqueous solution, Proc. the 1987 Int. Cong. on Membr. and Membr. Processes (ICOM’87), Tokyo, June 8-12, 1987. S. Sourirajan, Reverse osmosis separation and concentration of sucrose in aqueous solutions by using porous celluloseacetate membranes, Ind. Eng. Chem., Process. Res. Develop., 6 (1967) 154-160.
PERVAPORATION
OF EX-HANOL-WATER
MIXTURE
465
BY PLASMA
FILMS PREPARED
FROM HEXAMETHnDISILOXANE N. INAGAKI,
S. TASAKA
and Y. KOBAYASHI
Laboratory of Polymer 3-5-l Johoku, Hamamatsu,
Chemistry, Faculty 432 (JAPAN)
of
Engineering,
Shizuoka
University
SUMMARY The plasma polymerization process was investigated to obtain plasma films like poly(dimethylsiloxane), and the formed films were applied as membranes for pervaporation of ethanol-water solution. A reaction chamber which had the triode electrode structure for initiation of a glow discharge was provided for preparation of films like poly(dimethylsiloxane) by plasma polymerization. Films plasma-polymerized from hexamethyldisiloxane (HMDSO) resembled poly(dimethylsiloxane) in spectroscopic view and were composed of dimethylsiloxane chains with branches of trimethylsilyl groups. The surface energy for the films was 19.6 mN/m. The films deposited from HMDSO on membrane showed good ethanol-selectivity in Nuclepore pervaporation of ethanol-water solution. The separation factor depended on the film thickness as well as the feed composition. The film-thickness effect was maximized at 34 nm thick, and the separation factor reached 4.5. A model for the separation process using our composite membrane was discussed.
INTRODUCTION Pervaporation is
interpreted
interested of
is a separation
by
separation ethanol
of
ethanol
include
membranes
(refs.
from
silicon
blems
including
poor
nol in practical
use
from
its
ments
recombine and
of
is an unique Molecules
electrons,
to form
different
for
e.g.,
azeotropic
for
separation Hydra
but have
and swelling
process.
pro-
by etha-
or copolymerization
from
This uniqueness
conventional
into plasma
and
and fit
11-13).
thin-film
deposits
toughness,
are
solution.
selectivity
by cross-linking
(refs.
molecule.
finally
ethanol
ethanol
poor
introduced radicals,
a large
recombination
OOll-9164/88/$03.50
films
suitable
fermented the
Modification
of these reactions
or ionic.
e.g., show
membranes
solution,
are
are
for pervaporation
membranes
aqueos
membranes
process
investigators
water-selective
ethanol
properties,
3-10).
polymer-forming by actions
mentation,
(refs.
polymerization
such as radical mented
film-forming
for improvement
Plasma
1,2).
films
Many
Water-selective
solution,
polymer
The separation
1).
Membranes
types,
concentrated
ethanol
and fluoro
solution. (ref.
solution.
two
ethanol-selective
dilute
phobic
is applied
from
while
from model
of ethanol-water
solution
water
solution,
process
sorption-diffusion
in the separation
ethanol-water
ethanol-selective
of
the
ions,
and
The repetition polymers
0 1966 Elsevier Science Publishers B.V.
polymerizations
are activated then
and frag-
activated
frag-
of the activation,
frag-
(ref.
two
results
14).
Therefore,
the
466 formed even
polymers when
crosslinked
are
the
different
same
monomers
and superior
The aim of this by plasma
conventional
are
in mechanical
study
polymerzation
in pervaporation
from
The
used.
to
polymer
evaluate
of ethanol-water
plasma
in chemical polymers,
structure
generally,
are
properties.
is to prepare and
polymers
the
films
like poly(dimethylsiloxane)
performance
of
the
formed
films
solution.
EXPERIMENTAL Plasma
polymerization
The system mm
reactor
system
operating diameter,
at 470
(150 x 150 mm, trode), electrode
mm
two
a thickness
The electrodes
for
with
a monomer
plate
electrodes
monitor,
a vacuum
an aluminum
and the lower
electrode
50 mm space
of The V
the
frequency
was
applied
electrode
was
grounded
the
and glass
plates)
Triode
middle
on which
were
plasma
These
between and
the the
polymers
upper
lower (porous
deposited
coupled
of a bell
parallel
a triode
electrode
Substrates
electrode.
inlet,
three steel
electrodes
enhancement structure:
Schema
of the reaction
chamber
system.
set-up.
steel
electrodes
horizontally
were
(approximately and
the
electrode
middle was
membranes, were
mounted
silicon
mesh,
400 volts) electrode.
biased
at
-50
wafers,
on the surface
Thickness Meter
1.
elec-
The upper
*Thickness Monitor
Fig.
(400
mesh
l-
Vacuum System
jar
was a stainless
A high voltage
middle
capacitively
and a stainless
plate.
apart.
a
and a magnetic
middle
was an aluminum
20 kHz against
system,
of glow discharge plate,
was
It consisted
(af).
height)
positioned
at
polymerization
of 20 kHz
aluminum
for initiation
was
plasma
a frequency
467 of
the
lower
action
chamber The
the
electrode
same
as reported 0.13
cm3(STP)/min
current
sided
adhesive
represented
in Fig.
procedures
for
plasma
elsewhere
(ref.
Pa,
at
was turned
af current
double
is schematically
experimental
to approximately 4.8
with
and
15 Pa
then
was
on and the
the 15).
the
polymerization reaction
monomer into
of the
re-
were
system
essentially
was
evacuated
gas
adjusted
to a flow rate
of
the
reaction
chamber.
af
polymerization
(HMDSO)
(purchased
Japan),
ethynyltrimethylsilane
(ETMS),
Petrach
System
tetramethylsilane
Co.,
from
detail
was conducted
The
at a constant
of 20 mA.
Hexamethyldisiloxane
Kogyo
The
1.
The
introduced
plasma
tape.
Inc.,
U.S.A.),
Japan),
Petrach
and
System
from
Tokyo
trimethylvinylsilane
U.S.A.)
were
used
Kogyo
Co.,
(TMVS) (purchased
(TMS) (purchased
bis(dimethylamino)methylvinylsilane
Inc.,
Kasei from
(BDMAMVS)
as monomers
without
from
Tokyo Kasei (purchased
further
purifi-
cation.
Elemental
analysis
The C, H, and N contents with
a Yanagimoto after
as Si02 tent
was
a difference
of the between
plasma
The Si content
TM-2 analyzer.
combustion
and Si contents
of the deposited
polymers the
polymers
was determined
in an oxygen
sample
were
weight
gravimetrically
atmosphere.
and
the
sum
determined
The 0 con-
of the
C, H, N,
determined.
IR and XPS spectra IR spectra Bunko fourier
of the plasma transform
XPS spectra on silicon ploying
of
wafers
Mg K o
the
FT/IR-3.
polymers
(approximately
plasma recorded
with
a Shimadzu
exciting
radiation
at 8 kV and 30 mA.
of the binding
energy
recorded
with a Nihon
100 nm thick)
electronspectrometer The Au core
deposited 750 em-
level
at 84.0
scale.
energy
Contact phosphate “C
as a KBr disk were
spectrometer
were
eV was used for calibration
Surface
polymers
infrared
with
data
were
(ref.
16).
angles
against an
of
the
Erma
water,
plasma
glycerol, films
contactanglemeter
analyzed
to estimate
formamide,
deposited G-I with
the
surface
diiodomethane,
on glass
plate
were
a goniometer.
energy
according
and
tricresyl
measured
at
The
contact
to Kaelble’s
20
angle method
Pervaporation Composite
membranes,
and 30 nm; 6 urn the
plasma
thick)
polymers
porous
(purchased
prepared
from
polycarbonate from the
films
Nuclepore silicon
Co.,
(Nuclepore; U.S.A.)
compounds,
and
pore
were
size,
coated
served
for
15 with per-
468 vaporation
experiments.
The
composite
membrane the
area
membranes
of 13.8 cm’.
ethanol-water
a flow rate was kept through
solution
rate
a measured
of
The
permeation
estimated
from
in traps
the
JGC-ZOFP)
rate
with
glycol
the following
liquid
of the
the
membrane
The vapor
in the
column
at
permeated
trap
over
liquid was determined
a separation
a
membrane
The vapor
collected
with
at 25 “C and
by liquid nitrogen.
of the
and
cell
of the side
gauge.
1000 supported
(R in kg/m2-h)
steel
was kept
side
downstream
cooled
by weighing
10 % polyethylene
upper
a Pirani
and the composition
(JEOL,
2 m long)
of the cell
at the with
was condensed
of time,
a gas chromatograph
in a stainless
on the
The pressure
was determined
period
vapor
circulated
100 Pa by monitoring
membrane
permeation
positioned
The temperature
was
of 5 ml/min.
below the
were
with
(3 mm diameter,
on Flusin
T (60/80
separation
factor
mesh).
(a ) were
equations.
W R=43.5x
-
where
W and
(1)
t are
the
weight
(in g) of the
permeant
and the
permeation
time
(in min), respectively.
o
%2JCw2
=
(2)
‘El”W where
1
and CE2 are
CEl
respectively.
cw1 respectively.
meant,
the
ethanol
concentration
are the
and cw2
water
of the
concentration
feed
and the
of the
feed
permeant,
and the per-
RESULTS Chemical silicon
composition
surface
property
of
plasma
polymers
prepared
from
compounds To
obtain
of silicon A triode in this
poly(dimethylsiloxane)-like
compounds structure
study
structure
for
with
construction study) initiation
a reaction
with
voltage
A glow
for
electrodes,
first
This
which
electrode
triggered
polymerization
in Fig.
reaction
is biased high
discussed.
1, was employed from as the
system
a diode electrode
with
400 V was used
electrode
by the
was
is different
of approximately second
plasma
is a familiar
In the
and the
The third
discharge
from
polymerization
as shown
discharge.
(A voltage
the
films
plasma
electrodes,
a glow
polymerization.
of a glow discharge. electrode.
parallel
of parallel
between
thin
system
of
for plasma
a high
is applied
three
initiation
a pair
used
ode structure,
second
and
(mesh
the
in this
electrode)
at -50 V against voltage
tri-
is confined
for the to
469
a space bias
surrounded
of the
plasma
polymers
deposit
on
polymers tion
between
third
formed
the
could
surface avoid
system
with
the
irradiation
under of the been
deposited
films
Colorless, the
silicon
polymer
irradiation
(ref.
deposition
Table
not?
transparent
compounds
1 shows
polymers
was
prepared
those
influence plasma
irradiation
from
has
with
CVD.
structure
the conventional
damage
investigated
of
the
silicon
influence
plasma
from
analysis
of
plasma the
which
polymerization
triode
was
l/3
structure. - l/4
of The
as slow
as
structure.
effects
the silicon
effect
by plasma
irradiation
from
chamber
of the diode
always
polymers.
deposited
reaction
reac-
are
of the triode
less
was
and plasma
and degradation
films
prepared of
plasma
1 - 2.5 ug/cm*-min,
chamber plasma
silicon chamber
the
polymers
This irradiation
reaction
Does
were
the
plasma
because
The
electrode,
deposited
polymerization,
somewhat.
with
mesh the
negative
space.
in the conventional
amorphous
the
The
films
using
rate
deposited
in the
the
While,
plasma
by the
occurs
through
the
structure 17).
electrode
Therefore,
the
of
with
for the formed
when used the reaction
plasma
or
down
irradiation.
compared
diode
composition
pass
will occur
preparation
second
electrode.
during
prepared
the
the
polymerization
structure
polymers
reactions
of chemical
and
plasma
properties of
by plasma
the
diode
films
chamber
polymerization
space third
in the
show good electrical reaction
in the of
of plasma
plasma
silicon
first
and plasma
possible
the
emphasized
Amorphous
the
electrode,
on
the
compounds.
elemental The plasma
composition
of
polymerizations
TABLE 1 Elemental under
composition
of
plasma
polymers
prepared
No plasma
TMS
W/FM (MJ/kg) 246
C2.4H6.701.3Si
217
TMVS
irradiation Atomic
K4H12SiJ* (C5H12Si)
ratio
C2.3H5.601.4Si
ETMS (C5H10Si)
101
C2.7H5.701.8Si
HMDSO (C3Hg00.5SiJ
170
C2.8H8.702.4Si
BDMAMVS K7H18N2SiJ
160
‘4 . 6H10 . 3’1 . gNt . tsi
:
plasma
irradiation
no irradiation.
Monomers
*
under
Atomic
ratio
of the monomers.
Plasma
irradiation
W/FM (MJkg)
Atomic
290
C3,7H8.201.1N0.2Si
290
‘5
170
‘6 . 6H12 . 9’1 . BNO. lsi
120
C2.6H5.601.3Si
ratio
. BHll . 3’1 . gsi
and
470 were
performed
MJkg). tative
The W/FM expression
apparent
input
electrical and
under
observe
some
formed
under
differences
yielded
in silicon
content.
mass
of
of the
polymers
poor
C/S1 and H/Si
atomic
TMS, TMVS, and ETMS, shown
irradiation), atron),
2.4 and 6.7 (under
2.3 and
2.7
and
the
plasma
tinctive (Si2p core
5.7
5.6 (under
(under polymers
differences level)
monomer,
where
was could
of typical
Binding
1.3 -
(in J/set),
no irradiation);
1.8 independently
plasma
polymers
the
plasma 3.7 and
However, of the
prepared
We could
content
and rich
polymers
prepared
8.2 (under
plasma
plasma
plasma
O/Si plasma
polymers No plasma
irradi-
irradiation),
atomic
ratio
irradiation.
Fig. 2 shows from
an
(in mol/sec),
plasma
11.3 (under
12.9 (under
in XPS spectra.
means
W, F, and M are the flow rate
and hydrogen
5.8 and
respectively.
for quanti-
no irradiation:
for the
6.6 and
100 - 300
parameter
between
1, were
of
respectively.
under
in carbon
in Table
be observed
the
(in kg/mol),
ratios
values
14) was used
W/FM
formed
no irradiation);
no irradiation),
(ref.
composition
and those
W/FM
The
monomer
in elemental
irradiation
plasma
the
(at
by Yasuda
conditions.
for a glow discharge
weight
plasma
conditions
proposed
operating
per unit
energy
irradiation
from
the
energy
molecular
operating
parameter
of
input
the
similar
for Dis-
XPS spectra
TMVS and ETMS.
The
Energy (eV)
for plasma polymers prepared from TMVS (A, A’) and ETMS Fig. 2. XPS spectra (B, B’) under plasma irradiation (A’, B’) and under no irradiation (A, B).
471 plasma with
polymers peaks
mers
not
different mers
be
completely
oxidation
formed
peak
Sizp geneous the
near
levels
sense
preparation
irradiation
but
103 eV with that states may
reaction
of plasma
with
surely
of
with
the
from
Wave Fig. 3. IR spectra methylsiloxane) (B).
resembled
Number of
plasma
100.9,
These
peaks
silicon
atoms
poly-
Si spectrum
silicon
Conclusively, structure
having
plasma
moieties
whose of the hetero-
the
restriction
of silicon
moieties.
may be adequate
for
like poly(dimethylsiloxane).
spectroscopic
HMDSO
100.2,
The comparison
makes
homogeneity
triode
99.6,
Si spectra 2P plasma poly-
ETMS.
While the
of 3 eV.
view
among
the
HMDSO, TMS, TMVS, ETMS, and BDMAMVS showed
prepared
to
a symmetric
atoms). for
at
from
18-21).
irradiation
silicon
peaks
related
showed
be favorable
complex
103.7 eV for the
prepared
a FWHM value
chamber
polymers
from
are
the plasma
oxidation
showed
102.6, and
irradiation
irradiation the
Comparison from
plasma 102.2,
@iOx, x = 1 - 4) (refs.
no plasma
indicates
(many plasma
In this
the
101.8,
assigned
number
under
appeared core
under
100.2,
from TMVS, and Si spectra 2P 103.6 eV for the plasma polymers
102.2,
could
of
99.6,
prepared
101.8,
formed
at
mostly
plasma that
polymers the
prepared
plasma
poly(dimethylsiloxane).
Fig.
prepared
(A) and
polymers
3 shows
IR
x 10-Z(cm-l) polymers
from
HMDSO
polyfdi-
472 spectra
for
(PS048,
purchased
absorption
plasma
CH3
streching
and 617 cm -’ ported
that
the
dimethylsilyl ((CH3)3Si-), for both
C-H
and
HMDSO
methylsilyl
the
may
be
in CH3
(ref.
2967
(C-H
22).
vibration
deformation we assume
composed
dimethylsiloxane
streching
860,
Smith
(ref.
796,
in sym700,
23) has re-
appears at 1412 cm-l in -1 . in trimethylsilyl groups
vibration that
groups),
1260 (C-H
streching),
1454 and 1415 cm
symmetric
shows
in CH3 groups).
in CH3 groups),
the reference of
at
1020 (Si-0
deformation and at
appears
the plasma chains
at
1260 cm-l
polymers
with
prepared
branches
of tri-
moieties.
Table
2 shows
the
critical
surface
from
TMS, TMVS, ETMS, HMDSO,
from
HMDSO
possessed
methylsiloxane) which
1087,
in CH3 groups)
asymmetric
From
polymers
1454, 1408 (C-H asymmetric
peaks
deformation
groups),
((CH3)2Si-)
that
groups.
poly(dimethylsiloxane) plasma
symmetric deformation -1 (C-H deformation
absorption
asymmetric
deformation
groups
and The
799, and 686 cm
in CH3
(C-H
HMDSO U.S.A.).
in CH3 groups),
shows
1410 (C-H
deformation
Inc.
1257 (C-H
841,
poly(dimethylsiloxane)
metric
from
System
groups),
streching),
CH3 groups),
from
prepared
Petrach
at 2960(C-H
of
1044 (Si-0 While,
from
peaks
deformation
polymers
This table
a surface
(22.1
contained
mN/m).
nitrogen
indicates
energy
The
moieties,
that
these
energy
of the
and BDMAMVS. of
plasma
polymers polymers
19.6
mN/m
polymers
possessed
plasma
plasma
The plasma
higher
polymers
comparable
prepared
surface
possess
from
energy
hydrophobic
prepared prepared to
poly(di-
BDMAMVS,
of 34.1 mN/m. surfaces.
TABLE 2 Surface
energy
of plasma Surface
Monomers
energy
Surface
energy
Pervaporation The
24.2 29.6 29.3 19.6 34.1
Y,
23.6 29.2 21.3 17.3 22.0
0.6 0.4 8.0 2.4 12.1
of Nuclepore
polymers
membrane
experiments. on
( Y,) = Y sd
with plasma
plasma
pervaporation
Nuclepore of
(mN/m)
Y,d
YS
TMS TMVS ETMS HMDSO BDMAMVS
polymers.
+ Y sp
polymer prepared
(pore
size
membrane ethanol-water
membranes from
HMDSO
were
deposited
15 nm) and used as membranes itself,
as shown
solution.
The
in Fig. permeants
on the
surface
for pervaporation
4, had through
no influence Nuclepore
473
0
10
20
Ethanol Concentration
30
in Feed (wt%)
Fig. 4. Permeant composition through as a function of feed composition.
membrane
had
concentration
the of the
the azeotropic Fig. the
5 shows
feed
solution
typical
(a)
factor
varied
results of
was
indicating
plasma
films
increasing
the
near
20 wt%
ethanol.
including
silicon
plasma
films
lost
ration
of 4 wt%
as a function out
at
ethanol
and fluorine that
the
34, and 41 nm thick of the
thin
ethanol possessed
ethanol
even
size,
when
15 nm)
the
ethanol
This indicates
that
ethanol
film
prepared the
that
solution
from
composite
depended
using
HMDSO.
The
membrane
strongly
composition.
concentration
A similar
feed
of the
in pervaporation
an
The separation
of the
dependence
is
on the thicksolution, separation
using other
memb-
polymers. plasma
films
showed
selectivity:
For
a separation
factor
solution,
concentrations
of ethanol-water
factor
feed composition has been observed
It is of interest
(pore
0 to 100 wt%.
as well as the feed
with
ranes
solution
polymers
The separation
decreased
on the
from
plasma
and became unity factor
feed
in pervaporation
the 4.5,
membrane.
ness of the deposited
as the
membrane
occurred.
membranes
ethanol-selective factor
composition
pervaporation
composite
separation
same
Nuclepore
respectively.
thickness.
The
ethanol
example,
the
plasma
but films
thick of 27,
of 4.5, 3.1, and 1.0 in pervapo-
Fig. 6 shows pervaporation
of 4 and 8 wt%.
selectivity
The
the
separation
experiments separation
were factor
factor carried increased
474
4
0
5
10
15 20
25 30
Ethanol Concentration in Feed
(wt%)
Fig. 5. Separation factor Ca, (),a ) and flux (A, 0, n ) as a function of ethanol concentration in feed; plasma film thickness de osited on Nuclepore, 27 nm thick, A , A ; 34 nm thick,0 , l ; 41 nm thick, 0 , 4.
:,A, :;,
’
57
0
0
10
20
30
40
50
100
200
300
400
Plasma Film Thickness (nm> Fig. 6. Separation factor in pervaporation nol, 0, 0 and 8 wt%, A 1 as a function size 15 nm; 0, 30 nm. with
increasing
4 wt% at
ethanol
used
film
thickness,
reached
and 3.8 at 8 wt% ethanol),
41 nm thick.
another was
the
of ethanol-water of plasma film
Nuclepore
A similar having
as a substrate
effect
a larger (Fig.
6).
of the pore The
a maximum and afterward
size
film
thickness
solution thickness;
at
34 nm thick
decreased could
of 30 nm instead
separation
factor
(4 wt% etha0, A, pore
was
rapidly
(4.5
at
to unity
be observed
when
of 15 nm pore
size
maximized
at
200
475 nm thick
and was
producible
evidence
from
HMDSO
maximum could
the
independent
of
thickness
also
showed
separation
the
factor
and
effect
substrates.
other
ETMS (a = 4.5),
ethanol the
The
is not
selectivity.
surface
haphazard
plasma
and
films
of
the
prepared
BDMAMVS
A relationship
energy
but re-
(a = 2.1)
between
deposited
the
plasma
films
were
com-
not be observed. The performance
pared
with
rate
for
sited for
Therefore,
(a = 1.5), TMVS (~1 = 3.4),
TMS
besides
3.1.
those
our
on
composite
Nuclepore,
pervaporation The
polymers
tributes
from
10 to
and
hydrophobic
plasma 0.46
solution,
in this
The table
and permeation
HMDSO and depo-
been
in the
separation and the
permeation
3 summarizes
have
listed
The
study
and the
from
Table
which
properties,
factor
prepared
membranes
10-2 kg/m’-h. ability
films
kg/m’-h.
surface.
on polymer
formed
The separation
ethanol-selective
of 3.0 to 25 depending
yet good in separation
4.5
ethanol-water
with
membrane
membranes.
membrane, was
of
investigators. fluoro
of the composite
of other
table
factor
are
that
by many silicon
is in the
permeation
indicates
membranes
prepared
rate
widely
our membrane
or
range dis-
is not
rate.
TABLE 3 Performance
of membranes
Membranes
Ethanol cont. in feed(wt%)
Plasma films from HMDSO Styrene-dimethylsiloxane copolymer Styrene-fluoroalkyl acrylate graft copolymer Polydimethylsiloxane block copolymer Poly[l-(trimethylsilyl)1-propyne] Zeolite-filled silicon rubber Gore-Tex *:
in pervaporation
of ethanol-water
Separation factor
solution.
Flux (kg-m/m*-h)
Reference
0.46*
ours 12
4
4.5
7
3.1-25
l.l-2.7~10-~
8
16.3-45
0.6-l.l~lO-~
24 -6
10
5.7-9.4
1.1-5.6x10
10
11.2
1.15x1o-3
25
5-5.5
14.9-16.5
3.6-5.1~10-~
26
a
3-5.5
3.3-6.1
27
13
in kg/m’-h.
DISCUSSION
The separation interpreted
in understanding rate,
but
especially
process
by the does the
in pervaporation
sorption-diffusion membrane
not
completely
film-thickness
model.
behaviors
such
explain effect
of ethanol-water The concept as
ethanol
characteristics
as illustrated
solution of the
is frequently
model
selectivity
and
of our composite Fig.
6.
Why does
the
is helpful permeation membrane, separation
476 factor
reach
the maximum
Firstly, banes
we discuss
porous
complete
at 34 nm thick?
or
plugging
films
about
result
into
the
non-porous of pores
five
times
pores
ments
showed
which
was
the
about
lo3
times
of membrane
as thick
consideration
to plug the
membrane
membranes?
of Nuclepore
that
the
same
when
the
composite
membranes
nm may be not non-porous
The surface concentration, 69.56
mN/m
and 28.93 tension
by
tension
especially (water),
mN/m the
at
Preferential Sorption
Fig. 7.
48.25
A tentative
less
model
(ref.
ethanol
Capillary Streaming
size.
15 nm). the
that
of plasma
Taking
Sakata’s
may be a critical
thickness
Permeation composite
pervaporation
with
with
solution 20 wt%.
at
8 wt%
30).
experimembrane
experiment
Therefore
became
polymers
than
34
35.50
adsorption
on the
ethanol
at
40 “C is
tension mN/m
with composite
at
decrease of
ethanol
Evaporation
for pervaporation
conclude
thinner
strongly
surface
an exponential
the
we
micropores.
depends The
ethanol,
Such
suggests
thick.
plasma
membranes
than
mN/m
of
pore
mem-
reported
the deposition
across
the
41 nm
deposited
of ethanol-water
41.6 wt%
addition
at
but porous
at
rate
for
permeation rate was 1 x -5 3 x 10 cms(STP)/cm’-see-cmHg
that
size,
our composite
deposition was over 34 nm thick. Actually, the -2 10 cm’(STP)/cm*-set-cmHg at 27 nm thick
nitrogen and
(pore
as used
the
requires
membrane
permeation
specimen
less
28,291 has
(refs.
of 34 nm thick
membrane
nitrogen
Are
Sakata surfaces
as the
the deposition
construction.
membranes.
19.6 wt%, in surface molecules
477 at
the
31)
interface
have
ethanol-water of
at the
On the
membranes
have
are
then
basis
separation
at the
above
using our composite
stage
(ref.
at
flow)
for
the
would
preferetial it
be
is
assumed
and ethanol-water
propose
out.
model
The composite
in size.
Ethanol
of the
micropores,
wall
The separation
micropore.
reverse
a tentative
(Fig. 7).
molecules
hydrophobic
The concept
size.
and
Consequently,
membrane
membranes
the wall of the
(ref.
materials
with the solution.
to two the
co-workers
assumed
molecules
we could
evaporated
micropore
ferential-sorption-capillary Sourirajan
consideration
comparable
onto
to the
ethanol
contacted
of the
are
and
surface.
of our composite
process
molecules
adsorption
may be related
of
and
membrane
hydrophobic
adsorption
adsorbed
Morimoto
between
calorimetry,
membrane
micropores
adsorbed
solution.
the
the surface
predominantly
the
at
similar
between
the
interaction
immersion
when the composite
for the
and
molecules
that
interface
cules
from
ethanol
unreasonable
solution
air the
solution
adsorption not
between
discussed
mole-
operates
and mainly
The film-thickness is similar
osmosis
to the
membranes
effect
model
(pre-
proposed
by
32).
CONCLUSION The like
plasma
pervaporation process
restriction
is favorable
reaction
the plasma
process
and
of ethanol-water
The
1. The
polymerization
poly(dimethylsiloxane),
chamber
the
the
to
were
obtain
applied
of silicon
during
moieties
electrode
films for
as follows.
plasma
of the
structure
for preparation
plasma
as membranes
are summarized
irradiation
triode
and is available
investigated films
Results
plasma
homogeneity with
irradiation
was
formed
solution.
of
for
the
polymerization
formed
restricts
of plasma
polymers.
influences
films
of
like poly(di-
methylsiloxane). Films
2.
plasma-polymerized
from
poly(dimethylsiloxane)
in spectroscopic
chains
of
with
branches
trimethylsilyl
hexamethyldisiloxane
view
and
are
(HMDSO)
composed
groups.
The
surface
from
HMDSO
and
resemble
of dimethylsiloxane energy
for
the
films
is 19.6 mN/m. The
3. membrane
show
The separation tion.
The
factor
reaches 4.
ranes wall
films
good ethanol-selectivity factor
molecules
depends
film-thickness
A tentative micropores are
on the
effect
in pervaporation film
thickness
deposited
on Nuclepore
of ethanol-water
as well
as the
is maximized
at 34 nm thick,
the
separation
process
adsorption
of ethanol
solution.
feed
and the
composiseparation
4.5.
is proposed. of
plasma-polymerized
model
for
The preferential of
evaporated.
the
composite
membranes,
The separation
onto the wall of the micropores.
operates
and
using
our composite
molecules then
mainly
the at the
occurs
adsorbed adsorption
membat
the
ethanol stage
478 REFERENCES
4
5
6
7
8 9 10 11
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