Synthesis of Carbon Nano Fiber from Organic Waste and Activation of its Surface Area

Carbon Nano fi bers (CNFs) have recently attracted a lot of attention due to their widespread range of technological applications attributed to their unique physical and chemical properties, such as, small size, high strength, high adsorption linked with their large specifi c surface area, high temperature tolerance and corrosion resistance. CNFs have been used in energy conversion and storage, reinforcement of composites and self-sensing devices. The complete removal of entrapped metallic impurities and amorphous carbon incorporated with CNFs has been a long-standing issue. We have developed a new approach for preparing graphitic CNFs and its activation of surface area by purifi cation. This approach entails Thermal Decomposition (TD) based synthesis of CNFs from organic solid waste, such as, stems of rice plants. CNFs are synthesized from organic waste precursor (Rice Stems) at 900 oC under inert atmosphere. The active surface area was measured using a Surface Area Analyzer. Morphology of CNFs was studied with using SEM and XRD. The SEM image shows that the synthesized CNFs have diameter ranging within 45-60 nm.


Introduction
Properties of porous carbon and carbon based nanomaterials strongly depend upon the methods of synthesis employed. Carbon materials have attracted much attention due to their wide range of physical and chemical properties, which lead to broad range of utilities in advanced engineering materials, such as, in aerospace, transportation, actuators, sensors, fuel-cells, radar-absorbing materials, wind-turbine blades, electromagnetic interference shielding, and expensive sporting goods. They also ind applications in catalysis, electronic devices, gas and liquid separation, and memory storage devices [1][2][3].
Carbon ibers and nano ibers are the carbonic materials with high porosity and high speci ic surface area [1]. Carbon Nano Fibers (CNFs) have unique tubular structures with their diameter in nanometer range, and effectively have large speci ic surface area [4]. The basic shape of CNFs is cylinderical, with varying lengths and diameters. CNFs have superior physical and chemical properties, and very high mechanical strength. These unique properties make them suitable for a number of applications, e.g., as sensors and probes, thermal resistance, energy storage, and in many other optical, electronic and medical applications [4].
Vapor-grown CNFs have attracted much interest because they have the potential to provide solutions to many problems in composite applications. Unlike glass ibers, they are electrically conducting and therefore suitable for applications that require the ability to discharge electrostatic potentials, provide suf icient conductivity for electrostatic painting, or even shielding from radio frequency interference or lightning strikes. Moreover, their thermal conductivity is excellent [5,6].
In recent years, nanoparticles have been drawing attention [7] in the composite industry sector as they have the ability of enhancing the mechanical and physical properties of iberreinforced composites synthesized through older methods. Their nanometer size, connecting to high speci ic surface area, combined with extraordinary mechanical, electrical and thermal properties, make CNFs unique nano-illers for structural and multifunctional composites. While there is so much investigation reporting wide range of utilities of carbon nanotubes and CNFs in composites, the potential of these nano-materials to enhance the damping properties of composites still remains relatively less explored [8][9][10].
Numerous research works for the synthesis of Carbon Nano Materials (CNMs) have been carried out using precursors obtained from fossil fuel and petroleum products. The availability of such precursor and its cost are factors that determine the cost-effectivity of inally produced carbon nanomaterials. Hence, there is a need to search for new sources of precursors, which are not fossil-fuel based. Plant derived precursors can yield CNMs of similar, and sometime even better, quality than one would normally get starting with fossil-fuel materials and petroleum [11].
In the present work, we synthesized the CNFs using Stems of Rice plants by the method of Thermal Decomposition (TD). Stems of Rice plants are usually dumped and incinerated by the farmers, which leads to a number of environmental issues. Transformation of such biomass to emerging renewable materials is advantageous compared to the traditional dumping and incineration [9].
Among the various resources available for synthesis of nanostructured materials, plant waste is superior in terms of cost-effectiveness and it is eco-friendly also. Hence, we tried to synthesize the CNFs using plant based biomass through the TD route. The active surface area analysis has been done using Surface Area Analyzer instrument before and after the treatment with 50% Conc. HCl and HNO 3 . Morphology of CNFs was investigated through Scanning Electron Microscopy (SEM), Atomic Force Microscopy (AFM) and X-Ray Diffraction (XRD) analyses.

Materials and Methods
CNFs were synthesized from organic waste precursor, i.e., stems of the rice plant collected from Kalyan, India. The stems of the rice plant were washed with distilled water to remove surface contamination (e.g., dust, pesticide, etc.). It was then soaked in 10% KOH solution for 12 h. The soaked samples were washed with distilled water several times to reach the neutral pH and dried in oven at 120 o C. Finally, the dried stems of rice plant were thermally decomposed at 900 o C under inert atmosphere of hydrogen gas for 2 h in a horizontal furnace. The CNFs were treated with 50% Conc. HCl and HNO 3 to remove the alkali, amorphous carbon and metals present. Finally, the CNFs were iltered and washed with distilled water several times to reach the neutral pH, and inally dried in an oven at 100 o C.

Characterization techniques
FT-IR Spectroscopy: The CNFs was mixed with potassium bromide (KBr) (FTIR grade) in the ratio of 1:2 and pressed with the help of hydro-press to make pellets. The sample pellet was positioned into the sample holder and FTIR spectra were recorded on FTIR-4100 (Jasco). JSM-7600F with SEI Resolution 1.0 nm at 15 kV, 1.5 nm at 1 kV, in GB mode having magni ication as low as 25X to 10,000X to as high as 100X to 1,000,000X with accelerating voltage ranging from 0.1 to 30 kV and probe current ranging from 1 pA to ≥ 200 nA [3].

Raman spectroscopy:
Raman spectroscopy is based on the Raman Effect, which results from interactions of the vibrational modes of molecules with electromagnetic radiation. Raman spectroscopy is well known as a powerful tool for the characterization of carbon structures. The ratio of intensities of the D and G bands, R, gives interesting information on the structure of carbon materials [3]. It was carried out at University of Mumbai, India.
Surface area analysis: Active surface area was analyzed through BET Surface Area Analyzer from Smart Instruments Co. PVT. LTD.

Results and Discussions
In this work we developed easy, reliable and eco-friendly methods for synthesis CNFs. The waste Stems of the rice plant were pyrolysed at 900 o C in an inert atmosphere to get CNFs.

FTIR Spectroscopy
FT-IR analysis (Figure 1) show that synthesized treated CNFs have C-C and C=C stretching which was indicated by peaks at 1595 cm -1 and 1397 cm -1 , 705 cm -1 , 917cm -1 , 993 cm -1 also indicate the C-C binding stretching in inger print region and peak at 3431 cm -1 indicate that presence of amine (NH 2 ) group on the smooth surface of CNFs [8].
Surface morphology: SEM analysis (Figure 2a,b) shows that the average diameter of the CNFs is 40-60 nm and they have smooth surface. Figure 2a shows matrix residue on CNFs Surface, which was removed by treatment with acid as shown in igure 2bc. The EDAX spectra in igure 2d shows the absence of other impurities like metal salts, such as, halides and oxides.

X-Ray diffraction analysis:
The X-Ray Diffraction (XRD) pattern for as synthesized CNFs (Figure 3a) show broadening of spectra as compared to the one shown in igure 3b for puri ied CNFs sample. This indicates the presence of impurities in as synthesized CNFs. Figure 3b further

Raman spectroscopy:
The ratio of the intensities of disorder-induced phonon mode (D-band) and graphite band (G-band) in Raman spectra is a good indicator of the quality of samples. Figure 4 shows the intensities of these Raman bands that indicate a high quantity of structural defects present in the samples [9].
The G-band is visible at 1550-1600 cm −1 , which is produced from the high degree of symmetry and order in carbon materials. The D-band at 1250-1450 cm −1 is related to the disorder-induced phonon mode at the boundaries of Brillouin zone. The second order D-band (also called the D *band), which is related to the boundary point K in Brillouin zone of graphite and depends upon the packing in threedimensional space, is evident around 2500-2900 cm −1 . Moreover, the peaks at 2785 cm −1 and 3111 cm −1 are due to symmetric and asymmetrical C-H stretching vibrations of the CH 3 group, and asymmetrical C-H stretch vibrations of the CH 2 group, respectively. The band at 1600 cm -1 is assigned to the conjugate C=C bond, and the band around 1388 cm -1 is due to the CH 2 twisting.
Atomic Force Microscopy (AFM) analysis: The size and shape of the CNFs were obtained directly from tip-corrected AFM measurements, and the shape of the CNFs is estimated on the basis of AFM images and line scans. Figure 5 show the tube like structure of CNFs with average diameter (inner and outer wall) of 149.4 nm.   Surface area analysis: Surface area of as synthesized CNFs was found to be 106 m 2 /g which increase on treatment with 50% Con. HCl and HNO 3 to be 250 m 2 /g.

Eff ect of acid treatment
Acid treatment is one of important ways to improve the graphitization of CNFs and remove the amorphous carbon. The effects of acid treatment on synthesized CNFs were shown by the increased surface area and the quality of the synthesized CNFs. The surface area of synthesized CNFs from rice stem was about 106 m 2 g and acid treated CNFs have 250 m 2 /g. Clearly the speci ic surface area was found to increase after acid treatment, which may be attributed to more ef icient graphitization of the ibers.

Conclusion
Qualitative CNFs can be synthesized from organic waste precursors, i.e., stems of rice plant. The average diameters of the CNFs synthesized in this investigation were found to be in the range of 40-60 nm. The treatment of CNFs with 50% Conc. HCl and HNO 3 shows that matrix residue on the surface of CNFs was completely removed, and a smooth iber surface was obtained. Acid treatments not only removes the amorphous carbon but also it improved the active surface area. Such CNFs may ind applications in the areas of sports, automotive, construction industries, aerospace, marine, and electrical energy sectors etc.