S. S. Saravanakumar

Investigation of Physico-Chemical Properties of Alkali-Treated Prosopis juliflora Fibers

There is ever-increasing interest in using natural fibers in polymer composite systems and textile industry. Prosopis juliflora fibers (PJFs) possess ideal characteristics that make them suitable for various applications. Alkali treatment of PJFs was primarily aimed to change their physico-chemical properties; 5% (w/v) NaOH concentration and 60 min of soaking time were found to be optimal. It is intriguing to note that optimally treated PJFs had higher cellulose (72.27 wt.%), lower hemicellulose (4.02 wt.%) and lignin (12.09 wt.%) contents, higher crystallinity index (73%), tensile strength, and thermal stability.

Characterization of New Natural Cellulosic Fiber from Acacia leucophloea Bark

There is a need to explore the possibility of natural fibers as a novel reinforcement to fabricate lightweight composite structures. This investigation was aimed at understanding the characteristics of fiber extracted from the bark of the Acacia leucophloea (AL) plant and its physico-chemical properties. Cellulose content (68.09 wt.%), density (1385 kg/m3), crystallinity index (51%), tensile strength (317–1608 MPa), and Young’s modulus (8.41 − 69.61 GPa) properties were identified in the AL fibers, and thermal studies using TG and DTG analysis revealed that they degraded at a temperature of 220°C with kinetic activation energy of 73.1 kJ/mol.

Physico-chemical properties of new cellulosic fibers from the bark of Acacia planifrons

ABSTRACT Identification of new natural fibers is growing due to their superior properties and the impetus for researchers to develop high-performance composites. This investigation was aimed at understanding the physico-chemical properties of Acacia planifrons fibers (APFs). The crystalline structure of APFs was analyzed by X-ray diffraction, and the crystallinity index (65.38%) was calculated. The chemical functional group of APFs was confirmed by Fourier transform-infrared spectroscopy, the thermal stability measured by thermogravimetric analysis, and surface characterization established by atomic force microscopy. Taken together, all the properties of APFs can play a vital role in establishing APFs as new reinforcement in polymer composites.

Effect of Chemical Treatments on Physicochemical Properties of Prosopis juliflora Fibers

Incompatibility between hydrophilic natural fibers and hydrophobic matrix is known to affect the adhesion of the fiber and matrix. Therefore, it becomes necessary to modify the surface of natural fibers for improved adhesion between the fiber and matrix. Prosopis juliflora fibers (PJFs) are known to possess desirable properties for use as reinforcement in polymer matrices. Using chemical analysis, the optimal condition for alkali treatment of the PJFs was found to be 5% (w/v) of NaOH concentration with 60 min soaking time. Chemical modifications favorably changed the physiochemical properties of PJFs and undoubtedly diminished the amorphous and wax contents.

Characterization of new natural cellulosic fiber from the Perotis indica plant

ABSTRACT This investigation summarizes the characteristics of biofiber extracted from the Perotis indica plant. Cellulose content (68.4 wt%), density (785 kg m−3), crystallinity index (48.3%), tensile strength (317–1,608 MPa), and Young’s modulus (8.41–69.61 GPa) properties were identified in the P. indica fibers (PIFs), and thermal stability was studied using thermal gravimetric analysis and derivative thermogravimetric analysis, which revealed its cellulose degradation at a temperature of 339.1°C. Further, the properties of PIFs ensured that it can play an imperative role as new reinforcement as green composites in the manufacturing industries.

Physico-Chemical Properties of Alkali-Treated Acacia leucophloea Fibers

The attractive properties of raw Acacia leucophloea fibers (ALFs) resulted in this present study evaluating the physio-chemical properties of alkali-treated ALFs. The treatment of raw ALFs with 5% (w/v) sodium hydroxide solution with 45 min soaking time was found to be optimum. It was found that optimally treated ALFs had relatively higher tensile strength (357–1809 MPa), Young’s modulus (10.45–87.57 GPa), and percentage of elongation (1.91–5.88%) and high thermal stability. The optimally treated ALFs had high cellulose (76.69 wt.%) and low hemicellulose (3.81 wt.%) and lignin (13.67 wt.%) contents and higher crystallinity index (74.27%), as evidenced by the results of chemical and X-ray diffraction analyses.

Characterization of New Natural Cellulosic Fiber from Heteropogon Contortus Plant

ABSTRACT Natural fibers are one of effective substitute for switching artificial fiber and concentrating to reinforce polymer matrixes due to their decomposable character. This study was implied to realize physico-chemical properties of bio fiber obtained from Heteropogon contortus (HC) plant. Heteropogon contortus fibers (HCFs) had cellulose (64.87 wt. %), hemicellulose (19.34 wt. %), lignin (13.56 wt. %), and low density (602 kg/m3). The chemical functional group of HCFs was established by Fourier transform infrared spectroscopy, thermal stability of the fiber up to 220°C discovered by thermogravimetric analysis. Further the assets of HCFs proved that it can act as an excellent reinforcement material as a bio composite. Finally, the tensile properties were carried out through single fiber tensile tests, such as tensile strength, tensile modulus and microfibrillar angle.

Physicochemical properties of new cellulosic Artisdita hystrix leaf fiber

ABSTRACT The characterization of new natural fiber is increasing due to its excellent properties. This drives investigators to create high performance composites. The present investigation was designed to study the physicochemical properties of fibers obtained from the leaf of the Artistida hystrix. The Artistida hystrix fibers (AHFs) had crystallinity index (44.85%), cellulose (59.54 wt%), hemicellulose (11.35 wt%), lignin (8.42 wt%), and density (540 kg m−3). The tensile strength of AHFs was 440 ± 13.4 MPa with an average strain rate of 1.57 ± 0.04%. The calculated microfibril angle of AHFs was 12.64 ± 0.45°, which influenced the mechanical properties.

Physicochemical properties of new cellulosic fibers from the bark of Acacia arabica

ABSTRACT With the growing environmental consciousness toward carbon emissions, natural fibers are the best alternative and act as a substitute for synthetic fibers due to their potential properties. New cellulosic fibers were identified from Acacia arabica bark. This study aimed at understanding the characteristics of Acacia arabica fibers (AAFs) extracted from the bark of the A. arabica, and its physicochemical properties were examined by thermal stability analyses, X-ray diffraction, chemical constitutions, and Fourier transform infrared spectroscopy analysis. Cellulose content (68.1 wt%), density (1028 kg m−3), and crystallinity index (51.72%) properties were identified.

Characterization of New Natural Cellulosic Fiber from the Bark of Dichrostachys Cinerea

ABSTRACT The increasing environmental awareness has directed attention of the researchers towards the field of natural fiber composites. The aim of this investigation is to understand the physico-chemical properties of fibers extracted from the bark of the Dichrostachys Cinerea (DC) plant. Dichrostachys Cinerea fibers (DCFs) has cellulose (72.4 wt. %), hemicellulose (13.08 wt. %), lignin (16.89 wt. %), density (1240 kg/m3), crystallinity index (57.82%), and tensile strength (873 ± 14 MPa). Besides the cellulose degradation of DCFs at 359.3° vide by the thermo-gravimetric analysis and chemical groups are identified by Fourier transform analysis. Eventually the characterization results of DCFs strongly show the possibility of reinforcement in polymer matrices.