Chitosan coated cotton cloth supported zero-valent nanoparticles: Simple but economically viable, efficient and easily retrievable catalysts

A simple, economically viable and fast method has been utilized for the preparation of highly active metal nanoparticles (MNPs) in coating layer of chitosan (CH) over cellulose microfibers of cotton cloth (CC). 2 wt% of CH solution was used for the coating of CC strips (CC-CH), and were kept in aqueous solutions of metal salts to adsorb metal ions. The CC-CH templated with metal ions were then treated with aqueous solution of NaBH4 to reduce the metal ions into zero-valent metal nanoparticles (M0). The CC-CH strips loaded with M0 were characterized by XRD, XPS, ATR-FTIR, FE-SEM and TGA, which indicates the successful synthesis of MNPs by this method. The M0/CC-CH strips were used as an efficient catalyst for the model reduction reaction of nitrophenol and toxic organic dyes. Among all the prepaped samples, Fe/CC-CH showed good catalytic activity for 4-NP and Rh-B dye reduction in the presence of NaBH4 with rate constants of 0.2937 min−1 and 0.3804 min−1, respectively. Moreover Fe/CC-CH has good catalytic reduction ability for MO and MB having rate constants equal to 0.1698 and 0.2802 min−1, respectively. Beside the good catalytic ability, it could be easily recoverable as compared to other available techniques. The recovery was completed by simply pulling the strip from the reaction matrix after completion of the reaction and can be used several times.

1. The yellowish chitosan (CH) solution was prepared by dissolving 2% w/v of CH in dilute acetic acid aqueous solution (20%v/v) by stirring overnight at room temperature. It was then coated on cotton cloth (CC) by dipping the rectangular pieces (0.4 × 2 cm 2 ) of CC in this solution for 10 min. The excess solution was wiped out from the pieces of CC and kept for drying. 2. MNPs were synthesized inside CH layer on CC by adsorption of metal ions followed by their reduction with NaBH 4 . As mentioned above that pieces of CC were treated with CH solution to form CC-CH strips. Then CC-CH strips were kept in separate aqueous solutions of metal salts of FeSO 4 .7H 2 O, NiSO 4 .7H 2 O, CuSO 4 .5H 2 O, CoCl 2 .6H 2 O and AgNO 3 for 4 hours, which turned the white CC-CH strips to yellowish, greenish, irish blueish, reddish and brownish respectively. The strips were then gently washed with deionized water, and introduced into 100 mL of 0.1 M NaBH 4 aqueous solution. The black color was observed as soon as these strips were introduced into NaBH 4 aqueous solution. The strips were remaining dipped for 30 min in NaBH 4 solution to completely reduce the metal ions into zero-valent metal nanoparticles (M 0 ). The strips of CC-CH loaded with MNPs (M 0 /CC-CH) were washed with deionized water after this step, and freshly used in further analysis. 50 mA, and data were recorded at a scan rate of 2° 2θ min −1 . The crystallinity percentage (Cr%) were calculated from the XRD patterns of pure CC, CC-CH, and MNPs loaded on CC-CH samples, using the following equation (1) (200) where I amorphous , and I (200) represent the intensity of the amorphous halo and the intensity of the (200) peak, respectively. For the cellulose I, the at 2θ = 18° in the diffraction pattern was chosen as I amorphous . Crystallite size of the loaded MNPs were calculated using scherrer equation as given below in Eq. (2), where τ is the crystallite size, λ wavelength of X-rays, β full width of the peak at half minimum (FWHM) and θ is the scattering angle of the peak. XRD patterns were analyzed by Fityk software to calculate the FWHM values from the XRD patterns. Fourier transform infrared (FTIR) spectra of the samples were recorded in the range of 700-4000 cm −1 using PerkinElmer (spectrum100) ATR-FTIR spectrometer. X-ray photoelectron spectroscopy (XPS) Thermo Scientific K-Alpha KA1066 spectrometer (Germany) in the range of 200 to 1350 eV was investigated for the elemental analysis as well as for the determination of binding energy in the respective catalyst. The morphology of the samples was examined by field emission scanning electron microscope (FESEM) with a JEOL JSM-7600F, Japan. Energy dispersive X-ray spectrometry (EDS) of the samples was performed for the elemental analysis by using the Oxford-EDS system. Thermogravimetric analysis of 10 mg sample was performed by using TGA Q500 instrument. The samples were put in the aluminum pans and the autosampler stage of the instrument was kept on. Their weight lost against temperature under nitrogen atmosphere was recorded with a heating rate of 10 °C/min upto 700 °C. The residual concentration of nitrophenol and azo dyes was monitored and recorded by using Thermo scientific, Evolution 300 UV-visible spectrophotometer.
Evaluation of catalytic activity. The catalytic activities of M 0 /CC-CH was evaluated in the reduction of nitrophenol (4-NP) and azo dye (Rh-B) by NaBH 4 . We used quartz UV cuvette cell as reaction vessel. We prepared three solutions of NaBH 4 , 4-NP and Rh-B with concentration of 0.1 M, 0.1 mM and 0.05 mM respectively, in DI water. As an example, we explain the typical procedure adopted for the conversion of 4-nitrophenol to 4-aminophenol by NaBH 4 using the prepared catalyst. To UV cuvette, 3 mL of 4-NP and 0.5 mL of NaBH4 solution were added, and place in UV-visible spectrophotometer to record the UV-visible spectra. After this, the M 0 /CC-CH strip was added to this cuvette in such a way that UV-visible light can easily pass through it. The reduction reaction was started as soon as the catalytic strip was added and continuously recorded the absorption spectra. The recorded variation in the absorbance value of 4-NP at 400 nm was plotted and compared with the calibration curve. The catalytic strip was easily removed from the reaction vessel by just pulling the strip from cuvette and used it again for 4-NP conversion. The recyclability of the catalyst was performed after washing the catalytic strip with DI water and used again for 4-NP conversion reaction. The same procedure was implemented for the reduction reaction of Rh-B dye.
For sake of comparison, the catalytic activity of the bare CC and CC-CH was also tested. The catalytic efficiency of Fe/CC-CH for 4-NP and Rh-B was high as compared to other loaded MNPs, therefor we also investigated its activity towards other dyes like MB and MO. The concentration of these dyes was 0.05 mM. In all reaction, we used fresh catalytic strips except the recyclability experiments where same strip was used. Figure 1 shows the steps involved in the preparation of M 0 /CC-CH catalytic strips. CC coating by CH resulted in mechanically strong and slightly brittle CC-CH as compare to the pure CC because the individual cellulose microfibers was connected by CH polymer. Then color of the CC-CH strips was change from white to yellowish, irish blueish, reddish, brownish and greenish after treating with aqueous solution of metal salt Fe, Cu, Co, Ag and Ni, respectively. The color change confirmed the uptake of metal ions by -NH 2 and -OH groups present in CH layers of CC-CH strips. The formation of M 0 was carried out by dipping the CC-CH loaded with metal ions in the aqueous solution of NaBH 4 followed by color change to black. The color change took just few seconds, which indicates that the reaction of NaBH 4 with metal ions was quite fast. The chemical reactions during this process are proposed as follow in Eq. (3-7):   The successful synthesis of Co 0 , Cu 0 , Ag 0 , Ni 0 and Fe 0 nanoparticles depends on the water quality. In previous reports, water in NaBH 4 aqueous solution was deoxygenated by using nitrogen or other inert gases to avoid metal oxide formation 33,34 . The M 0 were also protected from their oxidation by the hydrogen gas release in the above reaction 7 . However, we used freshly prepared DI water for NaBH 4 solution, where chances for dissolved oxygen was low. The prepared CC-CH strips loaded with different M 0 were then tested in the reduction reactions of nitrophenol and dyes solutions.

Results and Discussion
Crystal structure and morphology. XRD. Figure 2 shows the XRD patterns of the bare CC, and the loaded CC-CH with Fe, Cu, Ag, Co and Ni nanoparticles. All the patterns have diffraction peaks at 14.9°,16.7°, 22.9° and 34.7° can be observed which correspond to (110), (110), (200) and (004) planes of cellulose 1. The XRD pattern of the loaded CC-CH with Fe, Cu, Ag, Co and Ni were identical to the bare CC, which suggest that crystalline cellulose content was present in all samples and CH was only amorphously adsorbed on the CC. The crystallinity of all the samples were in the range of 70 to 77%, and the crystallite size was about 6.92 to 7.03 nm. The cellulose crystallinity and crystallite size of the MNPs loaded CC-CH were almost similar to the bare CC. These observations manifested that cellulose reserved its structure after processing with CH for the preparation of MNPs, which is of intense need for its mechanical properties. In addition to amorphous and crystalline peaks of cellulose fibers of CC, the sharpest peak of Fe nanoparticles was also observed at 2θ = 43.7°, corresponding to (400) plane of Fe nanoparticles according to JCPDS no 98-000-0064, which is in line with other reported literature 35 . Cu nanoparticles has a sharpest peak at 2θ = 43.72° corresponding to (111) reflection, according to the JCPDS card # 04-0836, which can be observed in the XRD pattern of Cu/CC-CH. Similarly, in the XRD pattern of Ag/CC-CH, we can observe the peaks at 2θ = 38 and 43.8°, corresponding to the (111) and (200) reflection planes and were in good agreement with previous reports 36,37 . Moreover, according to JCDPS, card no 15-0806, Co nanoparticles has a diffraction peak at 43.8° corresponding to (111) crystal plane, which was observed here in Co/CC-CH indicating the preparation of cubic crystalline cobalt. Actually two modification of Co coexist at room temperature, which is face-center cubic (FCC) and hexagonal close-packed (HCP), and are often difficult to separate 38 . Here, the prepared Co nanoparticles were determined to be FCC by JCPDS database, since in the reported pattern the FCC crystal structure was dominant. Also, no cobalt oxide or carbide phase was observed in the reported pattern, since their peaks are at 2θ = 42.4° (JCPDS card no. 09-0402) and 47.57° (JCPDS card no. 05-0727), respectively. In the Ni/CC-CH diffraction pattern, the peak at 2θ = 44° confirms the presence Ni nanoparticles of (111) plane (according to JCPDS file no. 04-0850), in addition to the cellulose peaks. Since, in all XRD patterns of MNPs loaded on CC-CH, no other peaks related to their oxide or hydroxide was observed, which suggest the successful synthesis of zero-valent MNPs in the layers of CH on CC.
FTIR. Figure 3a,b shows the FTIR spectra of all the samples (bare CC and CC-CH and loaded with MNPs) recorded in the range between 700 cm −1 and 4000 cm −1 . This figure suggests that all the other spectra were identical to those of pure CC spectrum. All the spectra exhibited a typical cellulose FTIR, which was widely described in previous literature 39,40 . Also, its peaks at are well assigned and discussed in previous reports 41,42 . FTIR analysis suggests that no interaction occur between oxygenated functional groups of CC, CH amino and oxygenated groups, and MNPs because in all spectra the peaks were located on the same position. The interaction of CH and MNPs with CC in low extent might be due to low content of CH and MNPs in the samples. XPS. The XPS analysis of MNPs located on CC-CH surface in comparison with unloaded CC-CH is manifested in Fig. 4a-e. The valence state of the metals on the CC-CH surface is in the reduced form. For instance, Fig. 4a show the XPS Cu 2p 3/2 survey, presenting a photoelectron peak, this peak is selected to the chemically reduced Cu 0 , based on the additional Auger line survey. However, for the survey of Co/CC-CH, our XPS analysis did not confirm that loaded Co nanoparticles was present in its zero-valent form. Rendering to this analysis, the recorded Co 2p 3/2 peaks were positioned at 781 ± 0.3 eV and towards the high binding energy side. This value happens in between the earlier reported values correspond to Co 2+ in Co(OH) 2 (782 ± 0.1 eV for the 2p 3/2 line) 43 and to Co 2+ in CoO (780 ± 0.2 eV for the 2p 3/2 line) 44 . This line is very closer to the corresponding metallic cobalt, Co 0 (778 ± 0.2 eV for the Co 2p 3/2 line) 45 . Based on this, it could be proposed that Co 2+ ions were simply precipitated on surface of CC-CH in the form of Co(OH) 2 or fixed by the hydroxyl groups at that surface. Nevertheless, the XPS survey of Ag 3d 5/2 , has exposed only  one valence state on the surface, which represent the reduced MNP, i.e., Ag 0 (Fig. 4c). Thus, Ag 0 nanoparticles are reserved on the CC-CH surface by chemical reduction and precipitation. For the survey of Fe 2p core levels (Fig. 4d), the photoelectron peaks at 711 eV, 719 eV and 725 eV epitomize the binding energies of Fe(2p 3/2 ), shake-up satellite 2p 3/2 and 2p 1/2 , respectively. These three main peaks of Fe suggest that the surface CC-CH strip mainly consist of iron nanoparticles 46,47 . Furthermore, a small shoulder at around 706.98 eV suggesting the 2p 3/2 peaks of zero-valent iron (Fe 0 ). The Ni 2p 3/2 survey offers a small shoulder peak at 852 and another peak at 855 eV. That is, both Ni 0 (852 eV) and Ni(II) (855 eV) are present on the CC-CH surface 47 . The presence of both the zero-valent and their oxidized form of nanoparticles might be due to exposure for long time to air atmosphere during XPS analysis.

FE-SEM and EDX.
We used FE-SEM to analyze the morphologies of CC, CC-CH and Fe/CC-CH. Figure 5a-c exhibits the SEM images of all the samples. The left side images in (a-c) low magnification and the right side (a'c') exhibits high magnification. The FE-SEM image of CC was composed of microfibers as manifested in (Fig. 5a). The original morphology of CC upon treating with 5 wt% CH solution did not change (Fig. 5b). CC-CH was morphologically identical to the untreated CC and there were micropores in it. Initially, individual microfibers of CC are covered by a thin CH layer, as reveals by the images in (aa') and (bb'). The CH thin layer are partly connecting the fibers, however, some of the fibers are separated from each other, which pointing to the fact that this layer might be wrapping these fibers. This result suggests that CH was adsorbed in the form of thin layer around the CC microfibers. In case of Fe/CC-CH, a significant morphological changes can be observed at micrometer scale. From Fig. 5c plenty of small spots can be observed on microfibers, which indicate that Fe nanoparticles have been successfully formed on the surface of CC-CH, as already confirmed by XRD analysis. Some aggregates were also observed in the SEM image at high resolution (Fig. 5c'). Beside some aggregation most of the CC fibers surface was covered with well separated and uniform Fe nanoparticles. The successful synthesis of Fe nanoparticles on CH layer over CC microfibers was also confirmed by EDS analysis (Fig. 6a-c). The elemental Fe can be clearly observed in the EDX spectrum of Fe/CC-CH (Fig. 6c). Other elements carbon and oxygen observed in EDS analysis were mostly due to the presence of various functional groups in CC and CH. TGA. TGA thermograms of CC, CC-CH and Fe/CC-CH were elaborated in Fig. 7. All the sample lost around 10% of their original weight while increasing the temperature to 100 °C. The initial weight loss was due to the abolition of moisture from the samples. Moreover, an apparent and huge weight loss can be observed between 260 °C and 360 °C. This reduction of weight was due to oxidation, depolymerization and evolution of gases from cellulose and CH main organic portions. In contrast to other reports on addition of nanomaterial to polymer matrices, which increases the degradation temperature of polymer, a lowering in thermal stability of Fe/CC-CH was observed, which might be due to the catalytic nature of Fe nanoparticles. Usually nanoparticles increase the depolymerization and decreases the activation energy during thermal process 29,48,49 . Thermal decomposition temperature data obtained from TGA spectrum of CC, CC-CH and Fe/CC-CH are manifested in Table 1. In this table, (T onset ) is the initiation of the thermal decomposition temperature at which cellulose microfibers start to decompose, (T max ) is the maximum degradation rate temperature and (T end ) is the decomposition end temperature. From Table 1, it is clear that T onset , T max and T end were slightly lower for Fe/CC-CH and CC-CH than CC. Another objective of TGA analysis was to determine the amount of Fe nanoparticles in Fe/CC-CH strip. The difference between Fe/CC-CH and CC-CH thermogram at 700 °C at 7.77%, which suggest that the strip of almost 10 mg of Fe/CC-CH contain 0.7 ± 0.5 mg of Fe nanoparticles.     53,54 . Besides, it is reported that 4-AP is less toxic than nitroaromatic compounds and can be easily mineralized and removed from the environment 55,56 . Therefore, catalytic conversion of 4-NP to 4-AP is an efficient process and when analysis of catalytic activity of catalyst is required this reaction is often chosen as a model reaction.
A CC strip of dimension 0.4 × 2 cm 2 was introduced in UV cuvette containing 3 mL of 4-NP aqueous solution and 0.5 mL of NaBH 4 . No change in color of the solution was observed. Moreover, by analyzing UV-visible spectral data before and after 26 min insertion of CC, a slight decrease in the intensity was observed at 400 nm (main broad peak) (Fig. 8a). Similarly, the incorporation of CC-CH, slightly changes the color of 4-NP and its UV-visible spectra (Fig. 8b). Such a slight decrease in intensity might be due to the physical adsorption of 4-NP by CC or CH, which also indicates that pure CC and CC-CH have no catalytic property. Contrary to bare CC and CC-CH strips, when M 0 loaded strips were introduced to the reaction matrix of same conditions, the disappearance of color of the solution was observed as shown in Fig. SI 1. The intensity of the peak at 400 nm was gradually disappeared and completely vanished after 10, 12, 16, 18 and 26 min, respectively in the presence of CC-CH loaded with zero-valent Fe, Cu, Ag, Ni and Co nanoparticles (Fig. 8c and Fig. SI 2a-d). In this catalytic reduction reaction of 4-NP, the resulted increase in a new absorption band at 300 nm is recognized as the formation of 4-AP. Probably, the mechanism of this reaction remains the topic of discussion because it may involve complicated intermediates located on the surface of the NPs 57,58 . However, the isosbestic point approximately at wavelength of 320 nm exhibits the complete conversion 4-NP to 4-AP without side reaction 58,59 . The CC loaded with Fe, Cu, Ag, Ni and Co nanoparticles took 28, 32, 34, 34 and 38 min for complete reduction of 4-NP aqueous solution (Fig. 8f). In comparison of percent remaining concentration (%C t /C 0 ) of nitrophenol versus time in the presence of CC and CC-CH loaded with different M 0 , it can be observed that Fe/CC-CH exhibited good catalytic efficiency ( Fig. 8d and f), which suggests that Fe-NPs are more active towards nitrophenols reduction. These results strongly support the superior and excellent catalytic activity of the Fe nanoparticles template in thin CH layers over CC. A small induction period can be revealed over all catalytic strips. Generally, it is considered that the induction period is due to the diffusion of 4-nitrophenolate ions onto the surface of catalyst to be adsorbed prior to the start of the reaction 60 .
The 4-NP reductive conversion to 4-AP in the presence of strong reducing agent NaBH 4 , is six electron conversion process 32,50 . The conversion of 4-NP to 4-AP is thermodynamically favorable in the presence of NaBH 4 , because their standard electrode potential is greater than zero, i.e 0.67 V 32,61 . However, this conversion reaction is kinetically unfavorable in the absence of suitable and efficient catalyst as evidenced experimentally by the use of CC and CC-CH strips. The kinetic barrier can be by-passed through the placement of suitable catalyst like in the present case demonstrated as supported MNPs. It was previously demonstrated that introduction of NaBH 4 in nitrophenols produce nitrophenolate ions, the borohydrides ions (BH 4 − ) and nitrophenolate ions get adsorbed on the surface of the catalyst for transfer of electrons. Most of the time, these reduction reactions proceed with pseudo-first-order kinetics, provided that NaBH 4 is used in excess amount 32,60 . The natural log of absorbance ratios (ln(C/C 0 )) of the peak at 400 nm was plotted against time for 4-NP aqueous solution (Fig. 8d), where CC, CC-CH and Fe/CC-CH were used as a catalyst. All the data in the figure of Ln(C/C 0 ) vs time followed linear equation, which suggests that the reaction progressed with pseudo-first-order kinetics. The rates of reaction were 0.0007, 0.0051 and 0.2937 min −1 for CC, CC-CH and Fe/CC-CH.
Although metal nanoparticles were reported as an effective catalyst for the conversion of 4-NP to 4-AP, but they are difficult to separate from reaction matrix and to re-use for next cycle. Therefore, for reusability purpose the preparation of easy separable catalyst is rather essential. The M 0 /CC-CH catalytic strip can be easily pulled out from the reaction matrix. After one time use of the catalytic strip of Fe/CC-CH in 4-NP to 4-AP reaction, the same strip was washed with DI water and used in new reaction of 4-NP. The plot of (%) C t /C 0 as function of time, while using the same strip of Fe/CC-CH for 4-NP reduction is manifested in Fig. 9a. It can be observed that more than 95% of 4-NP was transformed into 4-AP during three time use of the same catalytic strip. The time taken by re-using the same catalytic strip of Fe/CC-CH for 70% reduction of 4-NP can be seen from Fig. 9b. The increase in reduction time was observed using the same catalytic strip, which indicated the diminution in catalytic performance. Such a decrease in the catalytic performance might be due to the oxidation of Fe nanoparticles during handling and their slight release to the solution matrix.
Rhodamine-B reduction. Same procedure was applied for Rh-B reduction as applied for 4-NP. Rh-B is one of the important xanthene dye and famous for its stability, which is widely utilized as a colorant in textiles and food stuffs 62,63 . It is harmful to human beings and causes irritation of the eyes, skin and respiratory tract. The reproductive and developmental toxicity, carcinogenicity, chronic toxicity and neurotoxicity have been experimentally proven toward humans and animals 64,65 . Keeping the harmful effects and hazardous nature of Rh-B in view, many As was expected, a slight decrease was observed in the intensity at 552 nm for the bare CC and CC-CH in 28 min (Fig. 10a,b). Besides, the CC-CH loaded with M 0 show catalytic efficiency toward Rh-B. The time taken for complete reduction of Rh-B was 18, 16 and 14 min in presence of CC-CH loaded with Co, Ni and Ag nanoparticles, while it took 9 and 6 min for Cu and Fe nanoparticles respectively. Inducing period existed in the presence of all catalyst for reduction reaction of Rh-B by NaBH 4 . However, the inducing periods were not identical, which show the difference in catalytic approach by different metal nanoparticles. The remaining percent of Rh-B was plotted against time in presence of various MNPs templated on CC-CH (Fig. 10d). It can be observed that Fe/CC-CH strip has high catalytic efficiency as compared to other loaded nanoparticles, which show the superior catalytic activity of Fe 0 nanoparticles towards Rh-B.
MO and MB reduction. Beside Rh-B dye, we also investigated the catalytic affinity of Fe/CC-CH on other organic dyes like MO and MB in the above NaBH 4 system. In the UV-vis absorption spectra of these dyes, the highest absorption peaks were observed at 464 for MO and 664 for MB. After adding NaBH 4 solution in the cuvette containing dyes solution, the site of the absorption peak and intensity did not change, implying that between dyes and NaBH 4 no reductive reaction took place. However, the peak intensities gradually decreased with time by introducing Fe/CC-CH strip to the above dye-NaBH 4 system (Fig. 11a,b). Similar to the reduction of Rh-B, these dyes reduction was at slower rate in the start of the reaction called as incubation/inducing period. Obviously, the different change trend under the same reaction conditions should originates from difference in molecular structure of the dyes. In general, the electron transfer from the BH 4 − ions onto the dyes molecules are responsible for the reduction of dyes, which take place with assistance of catalyst (here Fe/CC-CH) 69,70 . The overall process can be explained with electron relay system. The catalytic reduction started by Fe nanoparticles by transmitting electrons from the donor NaBH 4 to the dye molecule. Actually, when NaBH 4 was added to the reaction matrix, the Fe nanoparticles may be trapped by the hydride from BH 4 − ions and adsorbed on the surface of Fe/CC-CH strip and transfer its electron to the Fe nanoparticles. After the electron transfer to the Fe nanoparticles from BH 4 − ions the hydrogen atom formed, which subsequently attack a nearby dye molecule. Then spontaneously hydrogenation of the dye occurs by the transfer of these electrons to dye molecule. In other words, a negatively charges Fe nanoparticles (having excess of electrons), finally released electrons to an electron acceptor (here dye molecule), producing their reduced form (leuco Rh-B, leuco MB and hydrazine derivate for MO) as shown by the appearance of the new peaks around 250 nm in their time dependent UV-absorption spectra (Figs 10c,11a,b and 12). The cationic dyes (Rh-B and MB) reduced first followed by anionic dye MO. The nature of a dye (via., charge, presence of S/N donor atoms, hydrophobicity) may affect its rate of reduction 71,72 . In general, cationic dyes like Rh-B and MB have a high catalytic reaction rate then anionic dyes like MO, because of electrostatic interactions. It is clear that upon introduction of Fe/CC-CH catalytic strip in various dyes solution, the reduction reaction completed about 6, 9 and 12 min for RB, MB and MO, respectively. These suggests that Fe/ CC-CH is responsible for the possible cleavage of -N = N-double bond in azo dye structure and thus decolorizing the solutions 73 . Also, the appearance of new peaks in the UV-vis absorption spectra indicated the formation of new products. From Fig. 11c, it can be clearly observed that Fe/CC-CH has high catalytic efficiency of reduction towards Rh-B. More detailed information was deduced from the kinetics of reduction reactions. In these experiments, the concentration of NaBH 4 was much higher than dyes and could be consider as constant during the reaction kinetics. The order of the reaction was determined by pseudo first order kinetic equation, Ln(C/C 0 ) = −kt. The  values of Ln(C/C 0 ) versus time was plotted as shown in Fig. 11d. The values in the presence of Fe/CC-CH, didn't follow fully linearity of the equation might be due to the inducing period in the start of the reaction and also the bubble formation in the cuvette during the reaction. The rate of reactions calculated after deducing the inducing periods were 0.00283, 0.00467 and 0.00634 sec −1 for MO, MB and Rh-B, respectively. The high rate constant value deduced the high catalytic nature of Fe/CC-CH strip toward Rh-B, which is much higher than the reported literatures 71,74 . Comparison of our work with literature for the reduction of 4-NP and azo dyes is manifested in Table 2.

Conclusion
In summary, we present a simple method for the preparation of MNPs in the CH coating layer over cotton cloth for catalytic purpose. FTIR, XRD, XPS and TGA analysis confirmed that other properties of the cellulose fibers and CH did not change during the process. FESEM and EDX analysis exposed that the Fe nanoparticles were synthesized on CC-CH strips. Bare CC and CC-CH loaded with different MNPs were investigated for catalytic reduction of 4-NP and Rh-B by NaBH 4 . We showed that Fe/CC-CH strips have good catalytic activity for 4-NP and Rh-B as well as for MO and MB dyes reduction. The reduction reaction for 4-NP, Rh-B, MO and MB by NaBH 4 in presence of Fe/CC-CH strip were accomplished within 10, 6, 12 and 9 min, respectively. The Fe/CC-CH was re-used for three time in the reduction reaction of 4-NP, where more than 90% reduction was achieved in 15 min. The separation of the catalytic strip was nicely done by simply pulling the strip from the reaction matrix.