Hakimah Osman
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Preferred name
Hakimah Osman
Official Name
Hakimah, Osman
Alternative Name
Osman, Hakimah
Osman, H.
Main Affiliation
Scopus Author ID
7005733143
Researcher ID
AAT-9920-2020

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  • Publication
    Synthesis and Characterization of a Novel Nanosized Polyaniline
    ( 2023-12-01)
    Banjar M.F.
    ;
    Joynal Abedin F.N.
    ;
    Fizal A.N.S.
    ;
    Muhamad Sarih N.
    ;
    Hossain M.S.
    ;
    Hakimah Osman
    ;
    Khalil N.A.
    ;
    Ahmad Yahaya A.N.
    ;
    Zulkifli M.
    Polyaniline (PANI) is a conductive polymer easily converted into a conducting state. However, its limited mechanical properties have generated interest in fabricating PANI composites with other polymeric materials. In this study, a PANI–prevulcanized latex composite film was synthesized and fabricated in two phases following chronological steps. The first phase determined the following optimum parameters for synthesizing nanosized PANI, which were as follows: an initial molar ratio of 1, a stirring speed of 600 rpm, a synthesis temperature of 25 °C, purification via filtration, and washing using dopant acid, acetone, and distilled water. The use of a nonionic surfactant, Triton X-100, at 0.1% concentration favored PANI formation in a smaller particle size of approximately 600 nm and good dispersibility over seven days of observation compared to the use of anionic sodium dodecyl sulfate. Ultraviolet–visible spectroscopy (UV-Vis) showed that the PANI synthesized using a surfactant was in the emeraldine base form, as the washing process tends to decrease the doping level in the PANI backbone. Our scanning electron microscopy analysis showed that the optimized synthesis parameters produced colloidal PANI with an average particle size of 695 nm. This higher aspect ratio explained the higher conductivity of nanosized PANI compared to micron-sized PANI. Following the chronological steps to determine the optimal parameters produced a nanosized PANI powder. The nanosized PANI had higher conductivity than the micron-sized PANI because of its higher aspect ratio. When PANI is synthesized in smaller particle sizes, it has higher conductivity. Atomic force microscopy analysis showed that the current flow is higher across a 5 µm2 scanned area of nanosized PANI because it has a larger surface area. Thus, more sites for the current to flow through were present on the nanosized PANI particles.
  • Publication
    Physical and compressive stress of rice husk ash macroballoons in syntactic foam: Effect of rice husk ash layer
    ( 2024-04-01)
    Zakir N.I.M.
    ;
    Hasbullah S.Z.
    ;
    Zakaria Z.
    ;
    Hakimah Osman
    ;
    Masa A.
    The objective of this study is to investigate the effect of the rice husk ash (RHA) layer on the physical and compression properties of macroballoons in syntactic foam. The epoxy mixture was used to coat the surfaces of the expanded polystyrene (EPS) beads template, and the beads were rolled on the RHA and left at room temperature to produce E1RHAM macroballoon. The procedure was repeated to produce the second layer (E2RHAM) and third layer (E3RHAM) of the RHA macroballoon. The macroballoons were then post-cured in the air-circulating oven to shrink the EPS beads to produce hollow structures. The macroballoons were embedded in the epoxy mixture to produce epoxy syntactic foam. The syntactic foams with E1RHAM, E2RHAM, and E3RHAM were characterized in terms of physical and compression properties, respectively. It was found that E2RHAM exhibited the highest compressive stress and compressive modulus followed by E1RHAM and E3RHAM. The wall thickness of E2RHAM is 1.405 mm followed by E1RHAM at 0.745 mm and E3RHAM at 1.0701 mm. E2RHAM also has compressive strength and compressive modulus at 37.5 MPa and 925.03 MPa respectively followed by E1RHAM at 25 MPa and 642.86 MPa, and E2RHAM at 16 MPa and 168.08 MPa.
  • Publication
    Facile study on molar ratio and the significance of particle effect in polymerization of polyaniline
    ( 2024-03-28)
    Banjar M.F.
    ;
    Suphi H.D.
    ;
    Sarizan M.I.
    ;
    Yaacob S.
    ;
    Rahman A.S.A.
    ;
    Khalil N.A.
    ;
    Sapawe N.
    ;
    Hakimah Osman
    ;
    Jaswan Singh M.S.A.
    ;
    Dulaimi A.
    ;
    Zulkifli M.
    The synthesis of polyaniline in varied conditions or parameters produce different outcomes in term of morphologies and particle size. Well defined theory that clearly illustrate complete morphology spectrum remains scarce. Chemical oxidative polymerization of polyaniline (PANI) to be compounded in prevulcanised latex (PVL) film was produced throughout this work. PANI was prepared using aniline in hydrochloric acidic solution (HCl) with the presence of ammonium persulphate (APS) as the oxidizing agent and sodium dodecyl sulphate (SDS) as surfactant. This work proposes an outcome to reveal the significance of different molar ratio of aniline to oxidant at equimolar (0.2: 0.2 M) and non-equimolar (0.3: 0.1 M) with respect to different preparation process yielded different particle size of polymerized PANI. Analysis of microscopy images and particle size analysis (sonicated and unsonicated) reveal that all samples were highly flocculated with particle size of equimolar ranging between 10.0 to 152.45 µm and non-equimolar with 15.0 to 130.0 µm. After sonication applied, the population of smaller particle increased notably. Both ratio of aniline to oxidant formulation yields flocculated particle and quite consistently similar particle size. Microscopy images are present to support the findings.
  • Publication
    Impact of Mendong fiber–epoxy composite interface properties on electric field frequency exposure
    ( 2023-11-01)
    Suryanto H.
    ;
    Irawan Y.S.
    ;
    Soenoko R.
    ;
    Binoj J.S.
    ;
    Azlin Fazlina Osman
    ;
    Hakimah Osman
    ;
    Maulana J.
    ;
    Ali A.
    This research investigates the effects of the frequency of the external electric field during the curing process on the interfacial properties of epoxy composites reinforced by Mendong fiber. Epoxy was used as a matrix with cycloaliphatic amine as a curing agent. The AC electric field by frequencies of 1, 2, and 3 kHz and strength of 750 V/cm were applied during the curing process. The functional groups, structure, interface properties, and morphology of treated epoxy were observed using Fourier-transform infrared, x-ray diffraction, scanning electron microscope, and pull-out test, respectively. The result indicates that after treatment with an electric field of 1 kHz, new peaks were observed in the epoxy diffractogram at the angle of 6.2° and 12.3°, change in morphology, the wettability properties of epoxy were increased and interface shear strength was improved. Increasing the frequency of electric fields results in more damage to the interface and subsequently reduces the shear strength at the interface. Highlights: Interface properties of the composite after curing in an electric field characterized. Exposure to electric field frequency during curing changed epoxy properties. Shear strength of Mendong fiber/epoxy varied post-exposure to the electric field.
      4  25
  • Publication
    Recycled polyethylene terephthalate blends and composites: Impact of pet waste, engineering design, and their applications
    ( 2023-09-23)
    Zunaida Zakaria
    ;
    Hakimah Osman
    ;
    Nor Azura Abdul Rahim
    ;
    Munusamy Y.
    ;
    Ismail H.
    Polyethylene terephthalate (PET) is one of the major polymers produced and has been widely used in downstream industries, such as the production of textile fibers, packaging bottles, and films. The increased use of PET is associated with its excellent properties, which include thermal resistance, lightweight, high transparency, good impact, and relatively low cost. This indirectly contributes to a large amount of PET solid waste, which is detrimental to human life and exacerbates environmental issues. As a result, conversion to new PET blends and composites is an efficient method to recycle PET and reduce waste. While research in this area is ongoing and improving with the development of new materials for various applications, its commercialization has yet to begin. This chapter focuses on the designation of recycled PET and its performance as new blends and composites. Among the other topics discussed are PET waste sources, recycling methods, and applications, as well as the challenges of recycling PET and converting this solid waste into value-added products. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2023.
      1
  • Publication
    Effect of sulphur vulcanization system on physical, morphological and thermal properties of natural rubber latex foam
    ( 2022-05-18)
    Mohammad Syahrin Smail
    ;
    Zunaida Zakaria
    ;
    Hakimah Osman
    ;
    Syarifah Nuraqmar Syed Mahamud
    ;
    Munusamy Y.
    Recently, several research studies have been implemented using sodium bicarbonate (NaHCO3) as a blowing agent on rubber foams, yet none has been found in natural rubber latex foam (NRLF). The use of NaHCO3 as a blowing agent in NRLF prepared by the Dunlop process can potentially develop greener foaming processes and more environmentally friendly foam in the industry of latex foam. This novel method is designed to manage the reduction of harmful waste disposal associated typically in producing the NRLF product which is useful for industry purposes. Hence, this research is presented to investigate the physical properties of NRLF such as relative foam density, crosslink density, average cell diameter, and thermogravimetric analysis (TGA) based on the influences of different sulphur vulcanization systems via conventional vulcanization (CV) system and efficient vulcanization (EV) system. The relative density and crosslink density were increased with an increase in NaHCO3 concentration with the CV system exhibiting higher value than the EV system. For average cell diameter, the results showed a decrease in both systems with the EV system having higher value than the CV system. Thermal stability from the TGA results was also improved at higher NaHCO3 concentration and for the use of the CV system as a foaming approach, the CV system has higher thermal stability than the EV system.
      1  29
  • Publication
    Plastics in Agricultural Mulch Film
    ( 2022-01-01)
    Hakimah Osman
    Mulching film in agriculture is the practice of covering the soil around plants to improve the growing conditions for the crop through control of weeds and insects, increase soil temperature, moisture retention, reduction of evaporation, prevention of soil erosion, less crop contamination, and improve germination rates. Historically natural mulches such as straw, compost, hay and wood chippings have been used but since 1950s paper and plastics mulching have been tried. Because of its poor wet strength and high price, paper has been found less effective and more costly than plastic, thus plastic mulch film is the primary choice. Most of plastic mulch films such polypropylene (PP), low-density polyethylene (LDPE), high-density polyethylene (HDPE), and poly(vinyl chloride) (PVC) are not biodegradable and are typically removed after each growing season. Recovery of these plastics from the soil is difficult and can affect successive crop yields while causing substantive cost to the environment and farmers. Due to increasingly stringent regulations regarding use of non-degradable plastic in agriculture they are likely to be phased out soon. In the past decades several classes of ‘biodegradable’ materials have been studied but most of these films are reported to be relatively weak in mechanical properties, not efficiently degradable and cost prohibitive compared to conventional plastic mulches. For instance, the standards for degradation in compost (ISO 17088, ASTM D6400) specify that at least 90% of the organic carbon need to be converted to CO2, leaving room for up to 10% of the organic carbon to remain. Because of changes to more stringent regulations, researchers worldwide are now putting extra effort into research on biodegradable polymers from renewable resources. Consequently, biodegradable plastic mulch (BPM) is now being considered as a potential and viable option for the agriculture application in the near future.
      18  1
  • Publication
    Effect of Activating Agent on Porous Activated Carbon in Alginate Macrobeads for Removal of Remazol Red Dye
    ( 2024-06-07)
    Zakir N.I.M.
    ;
    Zunaida Zakaria
    ;
    Hakimah Osman
    ;
    Hafiza Shukor
    ;
    Masa A.
    Alginate macrobeads filled with porous activated carbon (PAC) treated using different types of chemical activating agents were prepared in this study. Rice husk ash (RHA) was treated using five types of chemicals, such as sodium hydroxide (NaOH), potassium hydroxide (KOH), zinc chloride (ZnCl2), hydrochloric acid (HCl) and citric acid, at a low temperature (~80°C) for 2 hours to produce PAC with high porosity and compared to the conventional process using furnace with a high processing temperature. A biopolymer, namely sodium alginate, was used to hold the PAC powder to produce an immobilized structure of PAC in macrobeads form. Adsorption of remazol red (RR) dye using macrobeads was measured using UV-spectrophotometer, while the morphology and composition of PAC were observed using scanning electron microscope (SEM) and energy dispersive X-ray (EDX), respectively. The functional groups of PAC were identified using attenuated total reflection Fourier transform infrared (ATR-FTIR). The results indicated that the alkali treated PAC successfully removed up to ~99% of the dye in 120 minutes, while the acid treated PAC could only remove ~30% the dye at the same time. This demonstrated that alkaline treatment produced PAC with higher porosity structure and the PAC produced using NaOH has high adsorption of RR dye.
      1  26
  • Publication
    The adsorption of remazol red dye using porous activated carbon (PAC) from rice husk ash treated using alkali treatment
    ( 2024-04-01)
    Zakir N.I.M.
    ;
    Zakaria Z.
    ;
    Hakimah Osman
    ;
    Masa A.
    This research investigated the adsorption of 50 mg/L of Remazol Red (RR) dye using porous activated carbon (PAC) prepared from rice husk ash (RHA) via alkali treatment. Two type of alkali were used, namely sodium hydroxide (NaOH) and potassium hydroxide (KOH), with four different concentrations (0.5 M, 1.0 M, 1.5 M and 2.0 M) using without any mechanical agitation. This study is significant as it used shorter processing time and lower temperature during the preparation of PAC compared to conventional treatment using furnace with higher processing temperature and longer time. The PAC was prepared by mixing RHA into the alkali solution (NaOH and KOH) for 2 hours and then washed using distilled water until the pH became neutral. The adsorption test was conducted using RR dye for 6 hours, tested using UV spectrophotometer and characterized using SEM, EDX and FTIR. Results showed that 1.0 Na-PAC had a higher adsorption percentage of 84% dye removal at 360 minutes, while 2.0 K-PAC had79% dye removal. It can be concluded that Na-PAC has a higher removal percentage of RR dye at different concentrations than K-PAC.
      1  12
  • Publication
    Effect of blowing agent on compression and morphological properties of natural rubber latex foam
    ( 2020-09-21)
    Syahrin S.M.
    ;
    Zunaida Zakaria
    ;
    Hakimah Osman
    ;
    Syarifah Nuraqmar Syed Mahamud
    Sodium bicarbonate (NaHCO3) was used as a blowing agent in natural rubber latex foam (NRLF) in this study. At fixed vulcanization temperature and time in an air-circulating oven, the NRLF was prepared via the Dunlop method by whipping until frothing and adding NaHCO3 in latex compounds with different loading (i.e., 0, 3, 9 and 12 phr). An alternative formulation for the inclusion of NaHCO3 in NRLF was used. The effect of different blowing agent loading on the physical characteristics of NRFL such as relative foam density was investigated. Observation of cell diameter was performed using an optical microscope (OM). The result of NRLF's compression strength was also evaluated, which correlated with the foam's physical characteristics. The relative foam density was increased with an increase in the amount of NaHCO3. However, the average cell diameter was shown to decrease as the loading of the blowing agent increased. The outcomes of the NRLF's compression strength were also enhanced as the loading of the blowing agent increased following the physical characteristics of the foam respectively.
      13  26