Nanoparticles of zeolite in surface modification of textile materials.
Markovic, Lea ; Tarbuk, Anita ; Grancaric, Ana Marija 等
Abstract: The new textile applications for achieving the materials
for human performance (medical, protective and sports) is one of nine
themes according the European Technology Platform for the Future of
Textiles. The present paper is an attempt to modify cotton and polyester
fabric surface with addition of natural zeolite nanoparticles for
achieving UV protective textile material. Zeolite in this paper refers
to activated particles of clinoptilolite, with high fraction of
nanoparticles (80%), produced by tribomechanical processing in the
patented machine. The capability of UV protection of the cotton and
polyester fabrics after modification, zeolite and FWA treatment was
determined according to AS/NZS 4399:1996 using transmission
spectrophotometer Cary 50 (Varian). The impact of zeolite on fabric
whiteness was discussed as well.
Key words: zeolite, cotton, polyester, UV protection
1. INTRODUCTION
Materials for human performance, such are medical, protective and
sports, is one of nine themes according to the European Technology
Platform for the Future of Textiles. Textile and clothing is a
human's second skin, therefore it is the most suitable interface
between environment and human body. It is ideal tool for personal
protection and safety (Jayaraman et al., 2006).
A good fabric UV protection is a guaranty that clothing will have
the ability to protect the skin from incident solar energy. In addition
to some beneficial effects of UV radiation (UV-R, from 100 nm to 400 nm)
on skin it may cause skin damage such as sunburn, allergies, skin aging
and even skin cancer especially during the summer time. The UV-C
radiation (from 100 nm to 280 nm) get absorbed by atmosphere, but UV-B
(from 280 nm to 320 nm) and UV-A (from 320 nm to 400 nm) rays reach the
Earth and cause known skin aging and recently the formation of skin
malignant neoplasm. Diminishing of the ozone layer raised this risk,
what have resulted with large investigation of fabric UV protection
(Reinert G. et al. 1997, Grancaric et al. 2006). It is well known that
garment provides some UV protection. Fabric can reflect, absorb and
scatter solar wavelengths, but in the most cases it does not provide
full sun screening properties. UV protection highly depends on a large
number of factors, such are type of fiber, porosity, density, moisture
content, type and conc. of dye, UV-B protective agents, and fluorescence
whitening agents (FWA) in the case of white textiles, if applied (Algaba
I., Riva A., Crews P.C. 2004). Natural zeolites are crystalline
aluminosilicates with unique adsorption, cationexchange, and catalytic
properties.
[FIGURE 1 OMITTED]
It has multiple uses in industry and agriculture. According to
Ivkovic, S et al. (2004) zeolits have also been investigated in a broad
spectrum of medical uses; such are tumor and diabetes mellitus. Due to
its cationexchange ability zeolites were used in water purification and
in detergents for longer time period. Megamin[R] is a natural zeolite
clinoptilolite with enhanced physicochemical properties. It has a
cage-like structure (Fig. 1) consisting of high portion of SiO2
(60-67%). It was produced by tribomechanical processing in the patented
machine. When applied externally in powder form, it has also been found
to quicken the healing of wounds and surgical incisions. It is proven
bactericides and fungicides as well (Ivkovic, S. 2004). In recent
studies, applied to textile material it scatters the light, resulting in
UV protection (Grancaric A.M., Tarbuk, A., Sadikovic M. 2006).
In this paper sun screening properties of cotton (C) and polyester
(poly(ethylene-terephtalate), PET) fabric after standard surface
modifications--cotton mercerization and PET alkaline hydrolysis; and
after treatment with zeolite nanoparticles and FWA's were
investigated.
2. EXPERIMENTAL
2.1 Material
In this paper nanoparticles of zeolite (Z) were applied to cotton
and polyester fabric before and after surface modification for achieving
better UV protection. Cotton fabric used was a plain weave fabric of
100% cotton yarn of 20 tex and surface mass 125 g/[m.sup.2]. Fabric was
chemically bleached in peroxide baths (CB) and mercerized (CBM) in a
bath containing 24% NaOH, 8 g/l anionic surfactant Subitol MLF (Bezema)
in a liquor ratio 1:25, 2 min, at 18[degrees]C, than rinsed and
neutralized. 5 g/l of zeolite nanoparticles were applied to bleached
(CBZ) and mercerized (CBMZ) cotton fabric by impregnation and dryed on
100[degrees]C for 2 min. Uvitex BHT (Ciba), FWA--three stilben derivate was applied in optimal concentration of 6 g/l in process similar for
zeolite.
Polyester fabric (PET) used was poly(ethylene-terephtalate)
previously heat set, having surface mass of 100 g/[m.sup.2]; textured
multifilament yarns in both warp and weft. Alkaline hydrolysis (PETH)
was performed in 1,5 mol/l NaOH with 2 g/l cationic surfactant Lyogen
BPN (Sandoz) as an accelerator by batch wise method for 10 min at
100[degrees]C, in stainless-steel bowls (Linitest, Original-Hanau), than
rinsed and neutralized. 5 g/l of zeolite nanoparticles were dispergated
in bath containing 0,5 g/l CHT dispergator (Bezema) and applied to
untreated (PETZ) and hydrolized (PETHZ) polyester fabric by thermosol
process. Fabric was dryed at 80[degrees]C for 2 min following by setting
at 200[degrees]C for 30 s. Uvitex ERN-P (Ciba), FWA--benzoxazole
derivate was applied in optimal concentration of 6 g/l in similar
thermosol process as zeolite.
2.2 Methods
Remission spectrophotometer SF 600 PLUS CT (Datacolor) was used for
measuring CIE whiteness and Yellowing Index according to DIN 6167
Description of yellowing of practically white or practically colorless
materials. UV protection was determined through Ultraviolet protection
factor (UPF) using transmission spectrophotometer Cary 50 Solarscreen
(Varian) according AS/NZS 4399:1996 Sun Protective Clothing: evaluation
and classification.
3. RESULTS AND DISSCUSSION
This paper investigates the application of nanoparticles of zeolite
on cotton and polyester fabric after well known surface
modifications--cotton mercerization and PET alkaline hydrolysis. The
influence of this application to fabric UV protection, whiteness and
yellowness were determined after treatment with zeolite nanoparticles
and FWA's. Results of UV protection expressed through mean UPF
values are shown on Fig. 2.
UPF indicates how much longer the person can stay in the sun with
the fabric covering the skin as compared with the uncovered skin to
obtain same erythemal response. Fig. 2. indicates that polyester fabric
give off better UV protection than cotton fabric after surface
modification and treatment with nanoparticles of zeolite due to
polyester chemical constitution. Polyester fiber has double bonds in
polymer chain which can absorb small amounts of UV-R. Nevertheless,
small amounts of UV-R are reflected from polyester multifilament. After
FWA treatment it is evident that cotton fabric absorbs higher amounts of
FWA. Bleached cotton is non-rateable for UV protection. Mercerization,
as standard cotton modification, results in higher cotton absorbility
and little increment of UPF, because fabric shrinks. Nanoparticles of
zeolite on fabric surface scatter UV-R resulting in better UV
protection. Additionally, zeolite increase fabric surface area resulting
in higher adsorption of FWA. Therefore, mercerized and zeolite treated
cotton fabrics give off excellent UV protection after FWA. UPF values
for polyester fabric show similar behavior as for cotton fabric.
Modification of polyester fabric results in little better UV protection,
while treatment with nanoparticles of zeolite results in good UV
protection. FWA treatment of polyester results in good protection as
well. Meanwhile, FWA treatment to polyester fabric with zeolite results
in very good UV protection.
[FIGURE 2 OMITTED]
Spectral characteristics of cotton and polyester fabrics were
measured using spectrophotometer Datacolor SF 600 PLUS CT. CIE whiteness
and yellowness index were calculated automatically. Results are
collected in Table 2.
It is evident that high effects in textile cleaning of genetic and
added impurities such are waxes, protein substances, pectin and other
during scouring leads to cotton whitening. Bleaching in peroxide baths
removes pigments resulting in white cotton. Natural zeolites are
yellowish, therefore small lost of fabric whiteness and small yellowing
occurs. Optical brightening results in great increment of cotton fabric
CIE whiteness because fabric is hydrophilic and absorbs high amounts of
FWA. Even zeolites are yellowish, active surface area is higher, what
leads to high CIE whiteness. Polyester fabric adsorbs only small amounts
of optical brightener. Therefore, fabric whiteness slightly increases.
Analogue to whiteness increment, yellowing index decreases.
4. CONCLUSION
Surface modification of textile materials--cotton mercerization and
alkaline polyester hydrolysis slightly increase fabric UV protection.
Nanoparticles of zeolite applied to fabric surface result in good UV
protection. FWA treatment leads to excellent UV protection for cotton
and very good protection for polyester. Even though natural zeolites are
yellowish do not affect fabric whiteness significantly. It is to point
out that nanoparticles of zeolite and FWA give off synergistic effect in
fabric UV protection.
5. REFERENCES
Algaba I., Riva A. and Crews P. C. (2004). Influence of Fiber Type
and Fabric Porosity on the UPF of Summer Fabrics, AATCC Review, Vol. 4,
No. 2, 26-31, ISSN 1532-8813
Grancaric, A.M. et al. (2006). UV Protection of Pretreated
Cotton--Influence of FWA?s Fluorescence, AATCC Review, Vol. 6, No. 4;
40-46, ISSN 1532-8813
Grancaric, A.M., Tarbuk, A., Sadikovic, M. Nanoparticles of Zeolite
in the Future Textile Finishing, Proceedings of Futurotextiles
Conference, Koncar et al. (Eds.), 147-153, ISBN, Lille, Nov 2006,
ENSAIT, Roubaix
Ivkovic, S. et al. (2004). Dietary Supplementation with the
Tribomechanically Activated Zeolite Clinoptilolite in Immunodeficiency:
Effects on the Immune System, Advan. in Therapy, Vol. 21, No. 2,
135-147, ISSN 0741-238X
Jayaraman, S.; Kiekens, P.; Grancaric, A.M. (2006), Preface, In:
Intelligent Textiles for Personal Protection and Safety, Jayaraman, S.;
Kiekens, P.; Grancaric, A.M. (Eds.), I, IOS Press, ISBN 1-58603-599-1,
Amsterdam
Reinert G. et al. (1997). UV Protecting Properties of Textile
Fabrics and their Improvement, Textile Chemists and Colorists, Vol. 29,
No. 12, 36-43, ISSN 0040-490X
MARKOVIC, L[ea]; TARBUK, A[nita] & GRANCARIC, A[na] M[arija] *
Table 1. Fabric labels and treatments
Label Treatment
CB Bleached cotton fabric
CBM Bleached mercerized cotton fabric
CBZ Bleached cotton fabric impregnated with zeolite
CBMZ Bleached mercerized cotton fabric impregnated with zeolite
PET Untreated polyester fabric
PETH Hydrolized polyester fabric
PETZ Polyester fabric impregnated with zeolite
PETHZ Hydrolized polyester fabric impregnated with zeolite
Table 2. CIE whiteness ([W.sub.CIE]) and yellowness index (YI) of
cotton and polyester fabrics after surface modification and treatment
with nanoparticles of zeolite and FWA
After treatment Treatment with FWA
Fabric [W.sub.CIE] YI [W.sub.CIE] YI
CB 75,7 3,4 121,1 -12,5
CBM 72,9 3,9 123,2 -11,7
CBZ 68,6 5,5 122,2 -12,0
CBMZ 67,2 6,4 124,2 -10,9
PET 66,9 6,5 85,8 2,0
PETH 67,3 6,4 81,7 -0,4
PETZ 66,8 6,5 83,3 1,1
PETHZ 64,9 7,1 84,7 0,2
