Your search keyword '"Muhammad Nasir Bashir"' showing total 9 results

1. Frictional stability of pumice-reinforced lightweight magnesium composite in ambient and elevated temperature environments

Author

Venkatesh Chenrayan, Kiran Shahapurkar, Chandru Manivannan, Manzoore Elahi M. Soudagar, Yasser Fouad, M.A. Kalam, Muhammad Mahmood Ali, and Muhammad Nasir Bashir

Subjects

Pumice, Squeeze casting, Adhesive wear, Abrasive wear, Oxide layers, Coefficient of friction, Mining engineering. Metallurgy, TN1-997

Abstract

Lightweight materials with better resistance to sliding wear are prominent candidates for automobile brake drums, clutch pads and cylinder block applications to facilitate fuel economy. This attempt is reserved to cater to materials with higher tribological quality needs. Less dense foamy pumice stone particles were involved in three different percentages (5, 10, and 15 wt%) to reinforce lightweight AZ31 Mg alloy. A stir-assisted squeeze casting technique was pursued to process the composite and refine the grain structure. A phase detection, elemental mapping and microstructure study were done through X-ray diffraction (XRD), energy dispersive spectroscopy (EDS), and scanning electron microscopy (SEM), respectively. An experimental dry sliding wear scrutiny was administered using a pin-on-disc apparatus by considering: (i) ambient and elevated temperature environments and (ii) three different levels of loads. The results reveal a significant drop in wear loss and a frictional coefficient for 15% pumice-loaded composite than the base alloy. Post-wear examination acknowledges the fact that the ambient temperature wear is governed by adhesive-abrasive wear and high temperature is by abrasive wear mechanisms. Worn-out scrutiny authenticates the presence of oxide layers and their role in lubrication. A comparative study with previous works upholds the novel magnesium composite is the right candidate for the mentioned automobile applications.

Published

2024

2. Integrated neural network based simulation of thermo solutal radiative double-diffusive convection of ternary hybrid nanofluid flow in an inclined annulus with thermophoretic particle deposition

Author

B. Shilpa, V. Leela, Irfan Anjum Badruddin, Sarfaraz Kamangar, Muhammad Nasir Bashir, and Muhammad Mahmood Ali

Subjects

Inclined annulus, Ternary hybrid nanofluid, Thermophoretic particle deposition, MHD, Finite difference technique, Artificial neural network model, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Numerical simulation of magnetohydrodynamic radiative double-diffusive convective heat and mass transfer of a ternary hybrid nanofluid with thermophoretic particle deposition in an inclined annulus is studied. Both sides of cylinders are preserved at uniform temperatures, while the remaining sides are thermally insulated. The coupled nonlinear partial differential equations are solved using a finite difference approach. The detailed computational results of heat and mass transfer rate, temperature, concentration and flow fields are presented and discussed for a distinct range of significant physical parameters. The results demonstrated that increasing the angle of the inclination factor increases fluid flow. In light of buoyancy, when the annular cavity is set downward, the enhanced shear velocity is transported upwards, where it reaches its optimal temperature. The higher temperature difference leads to augmented dynamic fluid motion, particularly in the radial direction, as the system seeks to balance the thermal energy through convective transfer. The Brownian motion parameter has abrupt mobility of nanoparticles in liquid, which promotes particle collisions with liquid molecules, yielding kinetic energy. Increased values of thermophoretic parameters augment the thermophoresis force. Thermophoretic particle deposition increases the concentration of nanoparticles in an annulus due to the migration of particles from hot to cold regions under the influence of temperature gradient. The heat and mass transfer characteristics of ternary hybrid nanofluid are forecasted through an artificial neural network-based Levenberg–Marquardt backpropagated algorithm. The built model shows the heat and mass transfer rate root mean squared values through the Levenberg–Marquardt algorithm as one and mean squared error values as 1e-07 and 1e-08 respectively.

Published

2024

3. Studies on adsorption of Brilliant Green from aqueous solution onto nutraceutical industrial pepper seed spent

Author

Razia Sulthana, Syed Noeman Taqui, Rayees Afzal Mir, Akheel Ahmed Syed, M.A. Mujtaba, Mohammed Huzaifa Mulla, Laxmikant D. Jathar, Reji Kumar Rajamony, Yasser Fouad, Sagar Shelare, Muhammad Mahmood Ali, and Muhammad Nasir Bashir

Subjects

Adsorption isotherm models, Brilliant Green, Adsorption kinetics, Nutraceutical industrial pepper seed spent, Valorisation, Chemistry, QD1-999

Abstract

The study proposed the removal of Brilliant Green, a cationic dye, by adsorption process from wastewater solution utilizing a low-cost adsorbent such as Nutraceutical Industrial Pepper Seed Spent (NIPSS). The study comprises an investigation of the parametric influence on the adsorption process. The parameters identified are pH, dye concentration, process temperature, quantity of the adsorbent, and particle size. The study of statistics found from experiments was carried out by incorporating Freundlich, Brouers-Sotolongo, Langmuir, Toth, Sips, Jovanovic, and Redlich-Peterson isotherm models. The adsorption kinetics were determined by implementing pseudo-first-order and second-order models, diffusion film models, and Dumwald-Wagner and Weber-Morris models. The experimental adsorption capacity qe was found to be about 130 mg/g. This value was closest to the maximum adsorption of 144.6mg/g predicted by the Brouers-Sotolongo isotherm which had a correlation coefficient (R2) of 0.998. The adsorption kinetics data was confirmed to be a pseudo-second-order model. The change in free energy, enthalpy change, and entropy change were vital thermodynamic factors in concluding that adsorption is almost spontaneous and endothermic process. Change in enthalpy (ΔH°) reduced value indicates the physical nature of the process. The adsorption of BG dye on the adsorbent surface was authenticated by FTIR spectroscopy and SEM imaging. A Central Composite Design (CCD) Quadratic model under Response Surface Methodology (RSM) was implemented for statistical optimization of adsorption capacity for the five parameters studied, namely, time, temperature, concentration of the dye, weight of the adsorbent, and pH. Software Design Expert 7.0 was used to evaluate 3D contour plots. The process of optimization yielded a value of 350 mg/g. Thus, incrementing the adsorption process by 84.2 %. The study provides insights on various dye and adsorbent interaction possibilities and derives that NIPSS is an efficient adsorbent to extract BG dye from wastewater solutions.

Published

2024

4. Biocrude from hydrothermal liquefaction of indigenous municipal solid waste for green energy generation and contribution towards circular economy: A case study of urban Pakistan

Author

Syed Imran Hussain Shah, Tahir Hussain Seehar, Muhammad Raashid, Rab Nawaz, Zafar Masood, Sara Mukhtar, Thamer Abdulhameed Al Johani, Anthony Doyle, Muhammad Nasir Bashir, Mmuhammad Mahmood Ali, and M.A. Kalam

Subjects

Municipal solid waste, Hydrothermal liquefaction, Biocrude, Circular economy, Energy recovery, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

In this study, biocrude was successfully produced by the hydrothermal liquefaction of municipal solid waste collected from the landfill site of Lahore, the capital of Punjab, Pakistan, boasting a population of 12 million and an annual waste collection of 10 million tons. The hydrothermal liquefaction process was performed at reaction parameters of 350 °C and 165 bars with 15 min of residence time. The solid waste was found to have 78 % dry matter, 22 % moisture contents, 22.2 % ash, 22.69 MJ/kg higher heating value, 52.062 % C, 8.007 % H, 0.764 % N, and 39.164 % O. Non-catalytic process only produced 10.57 % oil, however when using the catalytic process, the biocrude yield improved to 17.61 %, with 22.61 % energy recovery for biocrude and 12.14 % for solids, when using 2 g dose of K2CO3. The resultant biocrude has a 28.61 MJ/kg higher heating value, having 60.28 % C and 9.28 % H. In contrast, the aqueous phase generated had 4.43 pH, 71.5 g/L TOC, and 1.35 g/L Total Nitrogen. TGA indicated that biocrude contains approximately 80 % of volatile fractions of different fuels. The organic compounds having the six highest peak areas in GC-MS were Ethyl ether 25.74 %, 2-pentanone, 4-hydroxy-4-methyl 9.08 %, 2-propanone, 1,1-dimethoxy 5.62 %, Silane, dimethyl (docosyloxy) butoxy 5.08 %, 1-Hexanol, 2-ethyl 4.53 %, and. Phenol 4.07 %. This work makes the first-ever successful use of indigenous solid waste from a landfill dumping site in Lahore to successfully produce useful biocrude with aims of waste reduction and management, circular economy, and energy recovery.

Published

2024

5. Optimizing friction stir processing parameters for aluminium alloy 2024 reinforced with SiC particles: A taguchi approach of investigation

Author

S. Saravanakumar, K.B. Prakash, D. Dinesh, P. Manoj Kumar, Yasser Fouad, Manzoore Elahi M. Soudagar, Muhammad Mahmood Ali, and Muhammad Nasir Bashir

Subjects

Al MMC, Friction stir processing, Taguchi, SiC particles, Wear, Mining engineering. Metallurgy, TN1-997

Abstract

The present investigation focuses on the microstructural behavior and mechanical properties of Aluminium alloy 2024 reinforced with SiC nanoparticles by applying the Friction Stir Processing (FSP) technique. Taguchi L9 orthogonal array was used to find the optimal process parameters. The experiment used the expected best process parameters, which confirmed the predicted highest value for the mechanical characteristic. Traverse speed, axial load, and rotating speed are the main factors affecting aluminum metal matrix composite. Hence, this experiment examined the effects of five different tool spinning speeds, specifically 800, 900, 1000, 1100, and 1200 rpm. Weld samples are fabricated wherein the stir zone contains SiC nanoparticles. The results of the study indicate that the optimal welding rotational speed of 1000 rpm has a significant impact on the microstructure, wear rate, and microhardness. Specifically, it was observed that the stirred zone exhibited enhanced wear resistance compared to other zones. The study's findings revealed that after implementing friction stir processing (FSP), a well-defined shear zone was observed on the advancing side of the stir zone. Additionally, it is found that the uniform dispersion and strong bonding of SiC particles with an aluminium matrix further enhance wear resistance.

Published

2024

6. Experimental and simulation study of American saffron seed oil blended with diesel

Author

Valiveti Sivaramakrishna, Shaik Hussain, Chintalapudi Ravi Kiran, Jayashri N. Nair, Irfan Anjum Badruddin, Abdul Saddique Shaik, Sarfaraz Kamangar, Muhammad Mahmood Ali, and Muhammad Nasir Bashir

Subjects

American saffron oil methyl ester, DIESEL-RK, Performance, Emission, Diesel engine, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

In a variety of industries, including transportation, agriculture, and manufacturing, diesel engines are often employed. Due of rising prices and environmental concerns, researchers examined whether biodiesels might replace diesel. The current study looks into American Saffron Oil's feasibility as a feedstock for biodiesel production. The transesterification technique is used to extract American saffron oil methyl este(ASOME), which is then examined for its physical and chemical properties in accordance with ASTM standards. Diesel fuel and American Saffron Oil methyl ester are mixed on a volume basis to create a variety of fuel blends, including B20, B40, and B60. The test results showed that the 20 % ASOME mix had better performance and reduced emissions. Also, utilizing DIESEL-RK simulation software, diesel engine tests are conducted for the B20, B40, and B60 under identical operating circumstances. Moreover, diesel engine testing for the B20, B40, and B60 are carried out using DIESEL-RK simulation software under comparable operating circumstances. Results of simulation software tests show improved engine performance and reduced pollutants. When experimental data is compared to DIESEL-RK modeling software, it is found that brake thermal efficiency increased by 5.7 % and emissions of hydrocarbon and carbon monoxide decreased by 2.5 % and 14.3 %, respectively.

Published

2024

7. Folklore use of medicinal plants for the treatment of gynecological diseases in Pakistan-a review

Author

Salihah Khadim, Khafsa Malik, Abeer Kazmi, Tahira Sultana, Amir Ali, Khalid Mehmood, Rizwan Ul Hassan, Muhammad Nasir Bashir, and M. Mahmood Ali

Subjects

Ethnopharmacology, Gynecological diseases medicinal plants, Part used, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Background: Gynecological issues and sexually transmitted infections (STIs) pose significant challenges to women's health, particularly in developing nations. These challenges are exacerbated by limited access to modern reproductive healthcare facilities, economic constraints, and entrenched cultural norms. Consequently, most of the Pakistani population relies on traditional ethno-medicinal healthcare systems. This preference stems from the ease of access, affordability, widespread availability, and inherent trust placed in these alternative healthcare methods. Aim/objective: The inquiry aimed to report details on the application of conventional uses of plants in the health field in rural areas that could contribute to advancing the natural discovery of drugs. The objective of this analysis is to provide researchers with information on conventional and empirical knowledge of plant species concerning women's diseases. Methodology: Information on the common use of medicinal plants in treating women's diseases was gathered from electronic databases. As a keyword for the quest, ethnobotany, and ethnopharmacology were used together with gynecological complications. Result: The work of the current analysis has revealed that 217 plant species belonging to 89 families have been used in Pakistan's rural communities. The majority of plant species belong to the Apiaceae family, followed by the Asteraceae, Fabaceae, Solanaceae, Rosaceae, Lamiaceae, and other families. The biological interpretation of plants used in rural communities of Pakistan revealed that herbs and trees are the dominant forms with 58 % and 23 % respectively while shrubs and sub-shrubs with a low percentage of 17 % and 2 %. In natural preparation, leaves 29 %, flowers 22 %, seeds 14 %, fruits 14 %, roots 13 %, bark 7 %, and stems 5 % were the most used parts respectively and aerial parts, dried pericarp, bulb, bud, berry, latex, wood, rhizome, husk, fruit coat, oil, resins, twigs, and shoot were also used in minimum percentage. A multitude of plant species have found extensive application in the management of diverse women's health issues. These encompass concerns such as fatigue, mood fluctuations attributed to menstrual problems, gonorrhea, complications related to pregnancy, cravings for specific foods, throbbing breast pain, abdominal and pelvic cramps, excessive vaginal discharge, mastitis, irritability, abortion-related matters, headaches, uterine hemorrhage, Menorrhagia, Amenorrhea, Menopause, Vomiting Abortion, infertility and lactation challenges, as well as the regulation of lochia flow. Conclusion: This review provides remarkable information about the use of medicinal plants against women's diseases in the rural communities of Pakistan. It opens the gateway for the discovery of natural drug development.

Published

2024

8. Nanoparticle-enhanced biodiesel blends: A comprehensive review on improving engine performance and emissions

Author

Veeranna Modi, Prasad B. Rampure, Atul Babbar, Raman Kumar, Madeva Nagaral, Abhijit Bhowmik, Shatrudhan Pandey, S.M. Mozammil Hasnain, Muhammad Mahmood Ali, and Muhammad Nasir Bashir

Subjects

Nanoparticles, Biodiesel, Emission control, Combustion efficiency, Environmental impact, Materials of engineering and construction. Mechanics of materials, TA401-492, Energy conservation, TJ163.26-163.5

Abstract

Environmental sustainability concerns have led to exploring alternative fuels like biodiesel in transportation. However, biodiesel engines emit pollutants like NOx, CO, and PM, posing health and environmental risks. This review explores the use of Aluminium Oxide (Al2O3), Ruthenium Oxide (RuO2), Titanium Oxide (TiO2), Cerium Oxide (CeO2), Graphene Oxide, Multi-walled Carbon Nanotubes (CNT) and other nanoparticles, in biodiesel engine. It focuses on their unique properties, characterization, emission control, environmental impact, and engine performance. The study emphasizes the significance of different biodiesel blends, compositions, and nanoparticle additions in determining engine performance and emissions. Results vary based on nanoparticle type, size, concentration, and blend composition. The review examines the impact of nanoparticles on various aspects of biodiesel blends, including density, viscosity, cetane number, calorific value, and flash points. It found that nanoparticle additives significantly influence Brake Thermal Efficiency and combustion efficiency. The study also found that nanoparticle-enhanced biodiesel blends have improved ignition properties, faster evaporation, higher oxygen content, and elevated cetane numbers, leading to cleaner combustion and more environmentally friendly engine operation. The research supports the beneficial effects of nanoparticles on biodiesel characteristics and emissions reduction. The review suggests that nanoparticles in biodiesel engines can improve fuel characteristics, engine performance, and emissions reduction but cautions against potential environmental and health risks. The findings suggest further research and optimization for sustainable and efficient engine performance in pursuing greener transportation fuels, highlighting the potential of nanoparticles in biodiesel blends.

Published

2024

9. Mitigation of bio-corrosion characteristics of coronary artery stent by optimising fs-laser micromachining parameters

Author

Venkatesh Chenrayan, Dhanabal Palanisamy, Kalayarasan Mani, Kiran Shahapurkar, Manzoore Elahi M. Soudagar, Yasser Fouad, M.A. Kalam, Muhammad Mahmood Ali, and Muhammad Nasir Bashir

Subjects

Nitinol, Fs-laser, Surface roughness, Volume ablation, Corrosion, GRA, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Cardiovascular diseases, particularly coronary artery disease, pose big challenges to human life. Deployment of the stent is a preferable treatment for the above-mentioned disease. However, stents are usually made up of shape memory alloy called Nitinol. The poorer surface finish on the machined nitinol stents accelerates the migration of Nickel ions from the implanted nitinol stent, which is considered toxic and can lead to stenosis. The current study deals with controlling surface quality by minimising surface roughness and improving corrosion resistance. Femtosecond laser (fs-laser 10−15 s) micromachining was employed to machine the Nitinol surface to achieve sub-micron surface roughness. The Grey relational analysis (GRA)-coupled design of the experimental technique was implemented to determine optimal levels of four micromachining parameters (laser power, pulse frequency, scanning speed, and scanning pattern) varied at three levels to achieve minimum surface roughness and to maximise the volume ablation. The results show that to yield minimum surface roughness and maximum volume ablation, laser power and scanning speed are in a higher range. In contrast, the pulse frequency is lower, and the scanning pattern is in a zig-zag manner. ANOVA results manifest that scanning speed is the predominant factor in minimising surface roughness, followed by pulse frequency. Furthermore, the corrosion behaviour of the machined nitinol specimens was evaluated, and the results show that specimens with lower surface roughness had lower corrosion rates.

Published

2024