PET Surface Properties affected by low temperature plasma modification Tarek S. Salem Tarek S. Salem Polymer Interface Department Leibniz Institute for Polymer Research-Dresden Mühlleithen / Vogtland, 10. - 12. March 2009 E-Mail: [email protected] •Poly(ethylene terephthalate) properties •Oxygen plasma pre-treatment •Subsequent treatment with polyelectrolytes •Textile Printing
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PET Surface Properties affected by low temperature plasma modification
Tarek S. SalemTarek S. SalemPolymer Interface Department
Leibniz Institute for Polymer Research-Dresden
Mühlleithen / Vogtland, 10. -
12. March 2009E-Mail: [email protected]
•Poly(ethylene terephthalate) properties•Oxygen plasma pre-treatment•Subsequent treatment with polyelectrolytes•Textile Printing
2
High tensile strength , dimensional stability
Resistance to many chemicals
In Blends , PET makes the fabrics more resilient and wrinkle free
Poly(ethylene terphthalate) (PET) fabric
PET Surface Properties affected by low temperature plasma modification
3
Crystal structure of poly(ethylene terephthalate)
R.H.Peters, the chemistry of fibers, Vol.1, Elseiver publications ,1963
Amorphous region
Crystalline region
Morphology of PET fibre
Encylopedia of polymer scienceand technology ©
2003
Motivations :Motivations :
PET Surface Properties affected by low temperature plasma modification
4
Fibres& Textiles In eastern Europe April/june
2003, v.11, no.2 (41)
Motivations :Motivations :
Different classes of dyes
Moisture regain : 0.2-0.8 % at RH 65% , 20oC
Different textiles substrates
Textiles Ink-jet Printer
PET Surface Properties affected by low temperature plasma modification
Printing pastes in traditional printing
5
Objective :Objective :
Surface modification of PET fabrics in order to open numerous
opportunities for improvement of
• wetting,
• printing behavior (substrate-independent printing)
without altering the mechanical / physical properties of the bulk materials .
PET Surface Properties affected by low temperature plasma modification
6
Strategy Strategy
Application of low temperature oxygen plasma to endow the PET surface with moieties of polar groups ( -COOH, -OH,..) . Such introduced oxygen-containing groups increase the surface free energy and enhance the fabric’s wettability, but they can also act as anchor for further surface modifications by weak polyelectrolytes
O
O
O
PET
O
OHO
OH-
Heat
CONH
+
O
O HO
O
PET Surface Properties affected by low temperature plasma modification
++
+ ++ +
7
O
O
O
Gas inlet
Vacuum pump
Microwave generator2.45 GHz
PET
Tunable power(0-600 W) Excited gas species:
•Atoms•Molecules•Ions•Photons•Electrons•Free radicals•metastables
P-P-P-P P-P-
P-P-P-P- P-P-P
P-P-P-P P-P-P-P
P-P P
P-P-P-P
M M M
Crosslinking Etching (degradation) Functionalization
P : polymer chain
Plasma prePlasma pre‐‐treatmenttreatment
PET Surface Properties affected by low temperature plasma modification
8
Plasma power[W]
Plasma exposure time[s]
C [at %] O [at %]
0 0 69.68 25.76
100 15 63.66 34.32
100 30 57.58 38.89
300 15 61.92 36.03
300 30 57.12 39.25
XPS AnalysisXPS Analysis
PET Surface Properties affected by low temperature plasma modification
9
n ] [
280
O 1s
C 1s
1000 800 600 400 200 0Binding energy [eV]
Si 2sSi 2p
O 2s
a)
b)
O KLL
c)
300 290 280285295Binding energy [eV]
y
Hx
C
C-O-O=C
O-CC-O-CO=
π π*
H-O-CO=
H-O-CO=
CO=
CO=
Untreated PET
Plasma treated at 300 W 15 s
CC
OO
OCH2CH2O
PET Surface Properties affected by low temperature plasma modification
Plasma treated at 100 W 15 s
XPS AnalysisXPS Analysis
10
A possible mechanism of plasma functionalization for PET fiberA possible mechanism of plasma functionalization for PET fiber
Active plasma species
O O
O
OCC
O O
CC O
O
(I) (II)1 2
O
(III)(IV)O O
OCC
Active plasma species
H (I)
C
O
C HOCH2CH2O
(I)O2
O CH2 CH2 O OCO
C O
H
CO
C OOCH2CH2O OH
CO
C OOCH2CH2O
CO
C OHOCH2CH2O
H
(II)-H
CH OCH2O
(IV)
CH2CH2O OH
OH
A.Perwuelz, J. Adhesion Sci.Technol ., Vol.20, No. 9, PP.939 ( 2006)
PET Surface Properties affected by low temperature plasma modification
11
ZetaZeta--Potential (Potential (ζ)
Presentation of the electrochemical double layer according to the Gouy-Chapman-Stern-Grahame (GCSG) model
C.Werner, H.J. Jacobasch, J.Biomater. Sci. Polym.Edn 7 (1995) 1.
INLET OUTLET
Fabric sample 1
Fabric sample 2
Streaming channel
ElectrodeElectrode
PTFE foilLower part
Lower part
Zeta-potential measuring cell for fabrics
+-
-
- +
+
-
distance z
surfaceImmobile layer
mobile layer
Hydrated cation
Hydrated anion
OHPIHP
Shear plane
0
ζ
IHPΨ
OHPΨ
PET Surface Properties affected by low temperature plasma modification
IEP= pH|ζ=0
Q RUs∆P
ηεεo
L 1ζ =
Smoluchowski equation :
H.J.Jacobasch, F.Simon, C.Bellmann, Techn.Messen Sensoren Geräte syst. 63, 447 (1996)
O
O
O
O
OHO
OH
-
ZetaZeta--Potential (Potential (ζ)
PET Surface Properties affected by low temperature plasma modification 12
13
Wettability measurments on fabricsWettability measurments on fabrics
Water Uptake Water drop absorption timeWeight
TimeWetting
Capillarity
1
2
Typical wetting curve
Liquid
Textile sample
F
PET Surface Properties affected by low temperature plasma modification
14
Water drop absorption time
T
abs
> 600 s
Untreated PET
Plasma Pre-treated PET
T
abs
= 0.039 -
0.024 s
PET Surface Properties affected by low temperature plasma modification
15
Roughness measurmentsRoughness measurments
Untreated PET Plasma treated 300 W, 30 s
Ra
= 24,8 µm Ra
= 27,3 µm
PET Surface Properties affected by low temperature plasma modification
16
O
OHO
OH
Subsequent treatment with polyelectrolytesSubsequent treatment with polyelectrolytes
OHOO
NH2
OH
OO
OH
O
HO NH
COCH3
O
H2N
OH
HO
O
NH2
NH2
Chitosan
1. Adsorption2. Dryeing3. Annealing
NH2NH2
NH2
COO COONH3
NH3
NHC O
NH2
NH3
PET Surface Properties affected by low temperature plasma modification
17
NH2
NH2NH2NH2
NH2
O
O
O
O
OHO
OH
ZetaZeta--Potential (Potential (ζ)
PET Surface Properties affected by low temperature plasma modification
18
Plasma power[W]
Plasma exposure time
[s]C [at %] O [at %] N [at %]
0 0 69.68 25.76 ----
300 30 57.12 39.25 ----
XPS AnalysisXPS Analysis
Chitosan treated 62.23 33.06 2.65
PET Surface Properties affected by low temperature plasma modification
19
O
O
N
N
SO 3N a
SO 3N a
H
H
NH2
NH2NH2NH2
NH2
Textile Textile printingprinting
H+
+ +++
+ + +
D
SO3-
D
SO3-
D
SO3-
Wave length
(nm)
K/S
Untreated
PET+Chitosan
Plasma treated
PET+ChitosanC.I. Acid Blue 80
PET Surface Properties affected by low temperature plasma modification
20
OutlookOutlook
1.Oxygen
plasma
pre-treatment
confer
wettability
properties
to the
PET fabric.
2.XPS, Zeta
potential, and wettability
measurements
results
evidence
that the
formation
of new
functional
groups
on the
PET surface
could
be
attributed
to the
oxidation
of the
poly(ethylene
terephthalate) forming fibre.
3. Polar functional
groups, introduced
during
plasma
pre-treatment, were considered
as anchor
groups
for
adsorption
of chitosan, and its
further
grafting
through
the
heat-induced
reactions.
4. Significant
changes
in PET surface
properties
after
chitosan
coating formation
were
detected
by
the
increase
the
colour
strength
after
printing
with
acid
dye
and electrokinetic
measurement, which
showed
that
the modified
PET had
isoelectric
point shifted
to higher
pH
(7.7)
PET Surface Properties affected by low temperature plasma modification
21
Acknowledgement
1. Dr.Frank
Simon2. Dr.Mirko
Nitschke
3. Dr.Rolf-Dieter
Hund 4.Mr. Dieter Pleul5.Mr. Alfredo Clavimontes6.Mrs.Steffi Uhlmann7.Mrs.Anja Caspari8.Mrs.Katharina Fink
Leibniz Institute for Polymer Research-Dresden e.V. (Germany)Cultural
Affairs & Mission sector
–
Minstry
of higher
education
( Egypt)
PET Surface Properties affected by low temperature plasma modification
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