fastnessUVevis absorption spectra o

fastness
UVevis absorption spectra of EFCS in water were recorded on a
TU-1900 UVevis spectrophotometer. The EFCS solution had
maximum absorption at 295 nm wavelength. It was necessary to
dilute the residual dye solution to the same volume as that of the
initial dye solution. The dye exhaustion was determined by
measuring the absorbance (lmax ¼ 295 nm) of the initial and final
dye solutions. The dye exhaustion percentage E (%) was calculated
through the following equation:
Eð%Þ ¼ ðA0  AÞ=A0  100% (3)
where A0 and A are the absorbance values of dye before and after
dyeing at 295 nm, respectively.
To evaluate the dyeing performance, the color strength (K/S) and
CIELab value of the dyed samples was measured by using a Minolta
Lab Color test cm2300d spectrophotometer with illuminant D65
and 10
observer. This apparatus measures the light reflection
spectrum and converts it into L*, a*, and b* Cartesian coordinates of
a three-dimensional space map of all colors (Beaulieu et al., 2002;
Sarkar and Seal, 2003). The K/S value is calculated through the
KubelkaeMunk equation,
K=S ¼ ð1  RÞ2
.
2R (4)
where R is the reflectance of the dyed fabric sample; K is the absorption
coefficient, which depends on the dye concentration; S is
the scattering coefficient of the dyed substrate.
The total color difference DE* of the dyed flax fabric samples is
calculated through the following formula:
DE* ¼
ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
ðDL*Þ2 þ ðDa*Þ2 þ ðDb*Þ2
q
(5)
The fastness properties of the dyed samples were tested based
on ISO standard methods. Color fastness to rubbing and washing of
the dyed samples were tested according to Chinese National
Standard GB/T 14575-2009, and color fastness to light of samples
was tested according to AATCC Test Method 16-2004.
3. Results and discussion
3.1. Effect of cellulase treatment conditions
Enzymatic hydrolysis is a very complex system with multiple
factors generating heterogeneity in the system. The concentration
of cellulase solution is a factor that determines the rate of enzymatic
hydrolysis of fibers. The effects of the variable on cellulase are
presented in Fig. 1. As the enzyme concentration increased, the
weight loss of samples increased and TS decreased. These trends
may be due to complexation of the cellulase with the fiber surface
at an early stage of hydrocellulose hydrolysis (Shen et al., 2004).
The available surface area of the fibers was limited, so when the
concentration of cellulase bath reached 15 g/L, the rate of weight
loss stopped increasing and the TS dropped to a minimum value.
When the concentration of cellulase increased to 15 g/L, the activity
of acidic cellulase reached a plateau.
The temperature is a very important factor in enzymatic hydrolysis,
as it affects the degradation mechanism of cellulose and
thus determines the finishing effects on the fabric. The activity of
enzyme may be influenced by the bath temperature. Plots of the
weight loss and TS during cellulase treatment are depicted in Fig. 2.
Fig. 4. The effect of time on the weight loss rate and tensile strength.
Fig. 5. The effect of pH on the weight loss rate and tensile strength.
Table 1
Effect of EFCS concentration on color strength (K/S), dye exhaustion rate and
colorimetric data of the dyed flax fabric.
Pigment concentration (g/L) K/S E (%) L* a* b* DE*

Note: liquor ratio of 25:1, salt concentration of 5 g/L, at 95
C for 50 min.
Table 2
Effect of liquor ratio on color strength (K/S), dye exhaustion rate and colorimetric
data of the dyed flax fabric.
L