Journal of Textiles and Engineer Tekstil ve Mühendis

TMMOB Tekstil Mühendisleri Odasý
UCTEA Chamber of Textile Engineers
Tekstil ve Mühendis
Journal of Textiles and Engineer

1 9 9 2

TMMOB

Araþtýrma Makalesi / Research Article 

DETERMINATION AND CHARACTERIZATION OF TRICLOSAN 
ON POLYETHYLENE TEREPHTHALATE FIBERS

Mehmet Orhan*
Uludag University, Textile Engineering, Bursa, Turkey,

ABSTRACT: In this study, in order to investigate the presence of the triclosan on the polyethylene terephthalate (PET) 
fibers after finishing treatments, both triclosan and its derivate solutions were prepared and the presence of triclosan was 
found at retention time of 12.04-12.18 min. by GC-MS. SEM results showed that fiber surface became very smooth and 

-1 bright after coating and the vibrational bands in the region of 722 and 570 cm implied the presence of triclosan on fiber 
surface by FTIR studies. 

Key words: Triclosan, polyethylene terephthalate, SEM, FTIR, characterization

POLÝETÝLEN TEREFTALAT LÝFLERÝNDEKÝ TRÝKLOSANIN 
BELÝRLENMESÝ VE KARAKTERÝZASYONU

 

ÖZET: Bu çalýþmada, bitim iþlemi sonrasýnda polietilen tereftalat liflerinde triklosan varlýðýný incelemek için saf 
triklosan ve ticari bir triklosan çözeltisi kullanýlmýþtýr. GC-MS yardýmýyla 12,04-12,18 dakika zamanlarýnda triklosan 
varlýðý bulunmuþtur. SEM sonuçlarý, uygulamadan sonra lif yüzeyinin daha düzgün ve daha parlak olduðunu ve FTIR 

-1çalýþmalarýndaki 722 ve 570 cm  bölgelerindeki titreþim bantlarý ise, lif yüzeyinde triklosanýn varlýðýný göstermektedir.

Anahtar kelimeler: Triklosan, polietilen  tereftalat, SEM, FTIR, karakterizasyon

*Sorumlu Yazar/Corresponding Author: morhan@uludag.edu.tr
DOI: 10.7216/130075992012198506   www.tekstilvemuhendis.org.tr

Cilt (Vol): 19 - No: 85
SAYFA 27

Yýl (Year) : 2012/1
Cilt (Vol) : 19
Sayý (No) : 85



Journal of Textiles and Engineer Tekstil ve MühendisCilt (Vol): 19 - No: 85
SAYFA 28

1. INTRODUCTION
 

Polychloro phenoxy phenols (polychlorinated phenoxy 
phenols, PCPPs) are a group of organic polyhalogenated 
compounds such as triclosan and predioxins. The chemical 
structures of the PCPP's isomers are presented in Figure 1 
[1-4].

Figure 1. The chemical structures of the PCPP's and triclosan
 

Triclosan (5-chloro-2-(2,4-dichlorophenoxy) phenol) is a 
chlorinated aromatic compound which has functional 
groups representative of both ethers and phenols. It has a 
broad spectrum antibacterial and antifungal activity that's 
why it is used in many consumer and professional 
healthcare products including soaps, lotions and creams, 
toothpastes, deodorants, and also incorporated into 
polymers and textiles fabrics at concentrations that range 
from 0.1 to 1%. Triclosan's hydrolytic and light stability is 
very high, but it is lipophilic and almost insoluble in water 
(0.004%), but soluble in ethanol, diethyl ether, and 
stronger basic solutions such as 1 M sodium hydroxide. 
The use of triclosan in medical applications is limited 
because of its poor aqueous solubility of less than 0.001 
mg/ml. Thus, the formulation of triclosan in different 
products is difficult and these products have less 
antimicrobial activity than expected on the basis of their 
properties [5-9].
 

The aim of this study is to investigate the presence of 
triclosan on PET fibers. It is presented more detailed 
findings on the characteristics of triclosan and its trace on 
PET fibers. SEM results showed that fiber surface became 
very smooth and bright after coating and the vibrational 

-1 bands in the region of 722 and 570 cm implied the 
presence of triclosan on fiber surface.
 

2. EXPERIMENTAL
 

2.1. Materials
 

We used 100% PET fabric (39x28 courses/wales and 
260g/m ) due to their increasing presence in the production 

of medical, healthcare and hygiene materials. Triclosan (5-
choloro-2-(2,4-dicholorophenoxy)phenol, purity, 97%) 
was purchased from Sigma-Aldrich Chemicals and 
triclosan derivative was supplied by Rudolf Chemie.
 

2.2. Treatments
 

Triclosan was applied to PET fabric by laboratory type 
padder through conventional pad-dry process. The fabrics 
were padded through squeeze rollers made by Mathis with 
two dips and two nips, at a setting 0.5 bar to give a wet pick-
up of between 30-35% on weight of fabric. Treatment 
conditions were as follows: 60 g/l of antibacterial 
chemicals, drying at 150 C for 5 min in Mathis oven.

2.3. Measurements
 

2.3.1. GC/MS
 

The chemicals were determined using Agilent 6890N GC 
with 5975C MSD equipped with Agilent Tech 7683B 
Injector automatic liquid sampler and Agilent DB-5 GC 
column (30 m length, 0.25 mm ID, 0.25 μm film 
thickness). Helium was used as the carrier gas, with a 
column flow rate of 1.0 ml/min in constant-flow mode. 
Injections (10μL volume) were made in the splitless mode 

0(splitless time 1 min) and injector temperature was 280 C. 
The GC interface and the ion source temperatures were set 

0 0at 325 C. The GC oven temperature was kept at 80 C for 
0 01min, followed by the first ramp at 20 C /min to 120 C, 

0 0second ramp at 10 C/min to 325 C, and holding for 10 min. 
The mass spectrometer was operated in the electron impact 
ionisation mode (70 eV). MS spectra were recorded in the 
range from 100 to 550m/z units.
 

2.3.2. SEM
 

The surface morphologies of the swatches were observed 
with a JEOL JSM 7000 field emission scanning electron 
microscope (Tokyo, Japan). The standard procedure was 
followed, in which samples were coated with gold for 150 s 
before a scanning electron microscopy examination.
 

2.3.3.FTIR
 

The molecular structure of the untreated and treated 
swatches was analyzed by the attenuated total reflection 
Fourier transforms infrared spectroscopy (ATR-FTIR) and 
spectra were obtained using a Nicolet 6700 FTIR 
spectrometer. The swatches were scanned at frequencies 

-1from 400 to 4000 cm , the number of scan times was 32, 
-1and the resolution was set at 2 cm .

 

3. RESULTS AND DISCUSSION
 

3.1. GC Mass Studies
 

The studied compound structures were determined by 
comparing the GC-MS peaks of the compounds with those 
of the standard solutions. Pure triclosan and its commercial 
derivative were dissolved in 1 ml of methyl alcohol in the 
different concentrations and these mixtures were shaken in 
a test-tube for 2 min. The mass spectra of triclosan and its 
derivate were shown in Figure 2, typical GC-MS 
chromatograms were indicated in Figure 3 and GC-MS 
values were given in Table 1. The range of the retention 
time for the samples was between 12.00-12.18 min. The 
only one sharp peak was obtained 12.02, 12.14, and 12.18 
min. as the main peak of triclosan. Considering triclosan 
derivative, it was found that there were four peaks that 
represented by different compounds in the solution at 
different retention time. The chromatographic peak at 
12.04 min. was detected as the main peak of triclosan. The 
calibration graph was obtained by plotting the 

Mehmet ORHAN
Determination and Characterization of Triclosan On 
Polyethylene Terephthalate Fibers



Mehmet ORHAN
Determination and Characterization of Triclosan On 
Polyethylene Terephthalate Fibers

Journal of Textiles and Engineer Tekstil ve MühendisCilt (Vol): 19 - No: 85
SAYFA 29

concentration ratio against the peak area ratio (peak 
integration). The good linearity was obtained in the 
calibration graphs of different concentrations.

Figure 2. Chromatogram of triclosan (a) and triclosan derivative (b)

 
Figure 3. Spectrum of triclosan (a) and triclosan derivative (b)

Table 1. GC-MS values of triclosan and its derivative

3.2. SEM analysis
 

Surface morphology of PET was analyzed by SEM and 
surface images are shown in Fig.4. The untreated fiber in 
Fig.4(a) had relatively smooth surface, which had poor 
ability to hold water but the some impurities can be seen on 
the fiber surface. Compared with the untreated sample, 
surface in Fig.4(b) was slightly covered by triclosan after 
finishing. It also provided evidence of treatment occurring 
only on the surface of fiber.

Figure 4. SEM micrographs photographs of untreated PET (a) and 
treated with triclosan (b)
 

3.3. FTIR analysis
 

The ATR-FTIR spectra were used to determine the 
chemical changes caused by antibacterial treatments, and 
results are shown in Fig.5. It is well known that the 
existence of an aromatic rings in a structure is normally 
readily determined from the C-H and C=C-C ring-related 

- 1vibrations. The C-H stretching occurs above 3000 cm  and 
is typically exhibited as a multiplicity of weak-to-
moderate bands in Fig.5(a). The other most important set 
of bands are the aromatic ring vibrations centered around 

- 11600 and 1500 cm , which usually appear as a pair of band 
structures. The untreated PET have the following main 

- 1absorption bands at 3424 cm  (C=O, carbonyl overtone), 
- 12967 and 2906 cm  (two strong glycol C-H stretching), 

- 11712 cm  (C=O stretching), 1577 (ring C-C stretching), 
- 11504 cm  (ring C-H in-plane bending, ring C-C 

- 1stretching), 1469 cm  (CH  bending, O-C-H bending), 2
- 11407 cm  (ring C-H in-plane bending, ring C-C 

- 1stretching), 1338 cm  (CH  wagging, O-C-H bending), 2
- 11239 cm  (C(=O)-O stretching, ring ester C-C stretching , 

- 1C=O in-plane bending), 1091 cm  (glycol C-O stretching), 
- 11015 cm  (ring C-C-C bending, ring C-C stretching, ring 

- 1C-H in-plane bending), 967 cm  (O-CH  stretching, 2
- 1C(=O)-O stretching, chain folding), 870 cm  (ring C-H 

Compound

 
Retention time

 

(min)

 Molecular ion

 

(m/z)

 Relative

 

intensity

 Proposed

structure

Triclosan
 

12.02
 

12.14
 

12.18
 

287.9487
 

287.9485
 

287.9152
 

288 / 35.0
 

290 / 43.8
 

288 / 84.6
 

86.4% triclosan

95.3% triclosan

97.0% triclosan

Triclosan 
derivate  

   
12.04 287.9170 288 / 83.8 90.0% triclosan



Mehmet ORHAN
Determination and Characterization of Triclosan On 
Polyethylene Terephthalate Fibers

Journal of Textiles and Engineer Tekstil ve MühendisCilt (Vol): 19 - No: 85
SAYFA 30

guiding. Thanks are also due to Rudolf-Chemie for 
supplying triclosan derivative. The author kindly 
acknowledges the support from Grant TUBITAK BIDEB 
2219 (The Scientific and Technological Research Council 
of Turkey).

REFERENCES

1. Onodera, S., Yamada, K., Yamaji, Y., Ishikura, S. and Suzuki. 
S., (1986), Chemical changes of organic compounds in 
chlorinated water: X. Formation of polychlorinated 
methylphenoxymethylphenols (predioxins) during 
chlorination of methylphenols in dilute aqueous solution. 
Journal of Chromatography A, 354, 293-303.

2. Onodera, S., Ogawa, M., Yamawaki, C., Yamagishi. K. and 
Suzuki, S., (1989), Production of polychlorinated 
phenoxyphenols (predioxins) by aqueous chlorination of 
organic compounds, Chemosphere , 19, 675-680.

3. Onodera, S., Takahashi, M. and Suzuki, S., (1993), Chemical 
Changes of Organic Compounds in Chlorinated Water. XIX. 
Production of Alkylpolychlorinated Phenoxyphenols 
(Predioxins) by Aqueous Chlorination of Alkylphenols, 
Japanese Journal of Toxicology and Environmental Health 39, 
1, 20-28.

4. Onodera, S., Takahashi, T., Takemoto, S., Fujiyama, T., Tai, C. 
and Oh-i, T., (2003), Formation of polyhalogenated 4 
methylphenol dimers (Br/Cl-predioxins) during aqueous 
chlorination of 4 methylphenol in the presence of bromide ion. 
Organohalogen Compounds, 63, 199-202.

5. Onodera, S., Hayashi, T., Fujiyama, T, Fujiwara, M., Oh-i, T., 
Mori, Y., Kuwahara, M., Ezoe, Y., Nakajima, D. and Goto, S. J., 
(2006), TLC Fractionation and Characterization of Ames 
Mutagenic Substances in Chlorine-treated 4-methylphenol 
Solution in the Presence of Bromide Ion, Journal of 
Environmental Chemistry, 16, 2, 229-237.

6. Toprakkaya, D., Orhan, M., Gunesoglu, C. and Ozakin, C., 
(2005), Effects of Environmental Conditions on the 
Antibacterial Activity of the Treated Cotton Knits, AATCC 
Review, 5, 3, 25-28.

7. Orhan, M., Kut D., and Gunesoglu, C., (2007), Use of triclosan 
as antibacterial agent in textiles, Indian Journal of  Fibre and 
Textile Research, 32, 1, 114-118.

8. Orhan, M., Kut D., and Gunesoglu, C., (2009), Improving the 
antibacterial activity of cotton fabrics finished with triclosan 
by the use of 1,2,3,4-butanetetracarboxylic acid and citric 
acid, Journal of Applied Polymer Science, 111, 3, 1344-1352

9. Kuo-Yann Lai, (2005), Liquid detergents, Volume 129 of 
Surfactant science series, 689 pages, CRC Press, ISBN 
0824758358, 9780824758356

10. Donelli I., Freddi G., Nierstrasz VA., Taddei P., (2010), Surface 
structure and properties of poly-(ethylene terephthalate) 
hydrolyzed by alkali and cutinase, Polymer Degradation and 
Stability, 95, 9, 1542-1550.

11. Roberts J.D., Caserio M.C., (1977), Basic Principles of 
Organic Chemistry 2nd ed, Wiley.

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out-of-plane bending, ring ester C-C out-of-plane bending, 
- 1C=O out-of-plane bending, ring torsion), 845 cm  (ring C-

C stretching, C=O in plane bending, C-H  rocking), 791 2
- 1cm  (ring C-H out-of-plane bending, C=O rocking and 

- 1CCO bending), 722 cm  (C=O out-of-plane bending, ring 
torsion, ring C-H out-of-plane bending) [10-11].
 

For triclosan, the strong absorption of halogenated 
hydrocarbons arises from the stretching vibrations of the 
carbon-halogen bond and the most prominent and 
informative bands in the spectra of aromatic compounds 
occur in the low-frequency range between 900 and 670 

- 1cm . After triclosan application, such new bands were 
- 1detected between 3000 and 2800 cm  for aromatic C-H 

- 1stretching bands and 1800-1600 cm  for weak 
combination and overtone bands in Fig.5(b). These strong 
absorption bands result from the out-of-plane bending of 
the ring C-H bonds. In-plane bending bands appeared in the 

- 11300-1000 cm  region. Skeletal vibrations, involving C-C 
stretching within the ring, are absorbed in the 1610-1585 

- 1 and 1500-1400 cm regions. When several chlorine atoms 
are attached to one carbon atom, the band is usually more 
intense and at the high-frequency end of the assigned 
limits. The C-CI absorption bands were observed at 

-1frequencies range of 722-570 cm  and strong CH  wagging 2

bands were observed for the CH CI group in the 1300-1150 2
-1cm  region. We attribute such new bands to coating 

triclosan on surface of PET, which is consistent with the 
SEM pictures [10-13].

Figure 5. FTIR spectra of untreated PET (a) and treated with 
triclosan (b)
 

4. CONCLUSIONS
 

Triclosan has a broad spectrum antimicrobial activity but it 
is lipophilic and the use of triclosan for textile industry is 
also limited because of its poor aqueous solubility. The aim 
of this study is to investigate the presence of triclosan on 
PET fibers. SEM results showed that fiber surface was 
coated by triclosan after treatment and the new vibrational 
bands implied the presence of triclosan on fiber surface.
 

ACKNOWLEDGEMENT

thankful to Dr. Royall M. Broughton and Dr. 
Yonnie Wu from Auburn University for helping and 

 

The author is 



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