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The 6th Conference on Emerging Materials and Processes (CEMP 2023) was held on November 22–23, 2023, at the School of Chemical and Materials Engineering (SCME), National University of Sciences
[...] Read more.The 6th Conference on Emerging Materials and Processes (CEMP 2023) was held on November 22–23, 2023, at the School of Chemical and Materials Engineering (SCME), National University of Sciences and Technology (NUST), Pakistan. This conference brought together scientists and engineers from academia and industry to share ideas, problems, and their solutions. High profile international researchers participated from South Korea, China, Japan, UK, Denmark, Finland, Poland, Ireland, and France. Their invaluable contributions significantly enriched the quality and depth of the discussions. The materials design and analysis aspect of CEMP-23 was covered by sessions on materials informatics, polymer and composite materials, etc. The innovation in manufacturing processes was covered in sessions on alternative technologies in green engineering, and modeling and simulation in the process industry.
Water is a crucial component of human existence. The earth’s hydrosphere is composed mostly of saline water. Membrane distillation is a process that ensures desalination as a low-pollution and resource-stable technique. Traditional techniques such as reverse osmosis and thermal evaporation are energy intensive
[...] Read more.
Water is a crucial component of human existence. The earth’s hydrosphere is composed mostly of saline water. Membrane distillation is a process that ensures desalination as a low-pollution and resource-stable technique. Traditional techniques such as reverse osmosis and thermal evaporation are energy intensive and require expensive raw materials. In this work, geopolymer membranes were fabricated from metakaolin and coated with methyltrichlorosilane (MTCS). The coating agent improved the hydrophobicity of the membrane from 28° to 136.5°. A permeation experiment (duration: 3 h) via direct contact membrane distillation (DCMD) was conducted for the MTCS-coated membrane, which showed a water vapor flux of 11 kg/m2.h. The development of a hydrophobic geopolymer membrane is an exciting advancement for desalination. Overall, this work represents a promising step forward towards the development of a novel eco-friendly technique for processing saline water.
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(This article belongs to the Proceedings of CEMP 2023)
Sulfur recovery units are integral to the oil and gas industry, addressing the release of hazardous gases, particularly hydrogen sulfide. These units facilitate the conversion of H2S into elemental sulfur, aligning with stringent environmental regulations. This study employs a machine learning
[...] Read more.
Sulfur recovery units are integral to the oil and gas industry, addressing the release of hazardous gases, particularly hydrogen sulfide. These units facilitate the conversion of H2S into elemental sulfur, aligning with stringent environmental regulations. This study employs a machine learning algorithm to predict sulfur recovery efficiency under uncertain conditions. An industrial sulfur recovery unit was simulated in Aspen HYSYS and validated using real-world industrial data. The simulation incorporated artificial uncertainties (±5%) in key process parameters, including acid gas flow rate, acid gas temperature, air flow rate, air temperature, and Claus reactor inlet temperature. The generated data were utilized to train a Gaussian process regression model, assessed through R2 and RMSE values during validation, achieving a high predictive accuracy with an R2 value of 0.993 and RMSE value of 0.0709. In the next step, the Gaussian process regression model served as a surrogate for fitness function evaluations within a particle swarm optimization framework. The application of a hybrid optimization methodology resulted in the optimal parameter values, leading to a notable 3% increase in sulfur recovery efficiency. This study establishes the foundation for applying industry 4.0 principles to augment predictive capabilities in sulfur recovery units, thereby laying the groundwork for the development of digital twins.
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(This article belongs to the Proceedings of CEMP 2023)
Phase change materials, such as paraffin waxes, have recently been introduced in surface science. Paraffin-based slippery liquid-infused porous surfaces (P-SLIPSs) provide switchable wettability and various adhesion states. Herein, P-SLIPSs were fabricated on copper plates. To study condensation heat transfer, two condensation rigs were
[...] Read more.
Phase change materials, such as paraffin waxes, have recently been introduced in surface science. Paraffin-based slippery liquid-infused porous surfaces (P-SLIPSs) provide switchable wettability and various adhesion states. Herein, P-SLIPSs were fabricated on copper plates. To study condensation heat transfer, two condensation rigs were fabricated and optimized via a comparison between the experimental and theoretical heat transfer coefficients, finding a good agreement in the short cold-finger-assisted rig. The condensation mode on P-SLIPSs is dropwise mode. Consequently, the condensation heat transfer coefficients on P-SLIPSs were found to be higher compared with that of pristine copper plates.
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(This article belongs to the Proceedings of CEMP 2023)
In this current work, we assume the mathematical modelling of non-Newtonian time-dependent hybrid nanoparticles via a cylindrical stenosis artery. In this work, blood is used as a base fluid, and the nanoparticles (copper and aluminum oxide) of cylindrical shape are inserted inside the
[...] Read more.
In this current work, we assume the mathematical modelling of non-Newtonian time-dependent hybrid nanoparticles via a cylindrical stenosis artery. In this work, blood is used as a base fluid, and the nanoparticles (copper and aluminum oxide) of cylindrical shape are inserted inside the artery to combine with blood to form hybrid nanofluid (HNF). The homotopy analysis method (HAM) is deployed for the solution of nonlinear resulting equations. For the validation of this current work, the results of the existing work have been compared with our proposed model results. A comparison of key profiles like velocity, temperature, wall shear stress, and flow rate is also performed at a specific critical height of the stenosis. It is also observed that the thermal conductance of hybrid nanofluids is greater than that of nanofluids. Including the hybrid nanoparticles (copper and aluminum oxide) inside the blood enhances the blood axial velocity. These simulations are applicable to the magnetic targeting treatment of stenosed artery disorders and the diffusion of nanodrugs.
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To enhance the overall performance of perovskite solar cells, the quality of the electron transport layer (ETL) held significant importance. Zinc oxide (ZnO) emerged as highly promising due to its exceptional optical and electrical characteristics. This study included the incorporation of lanthanum (La
[...] Read more.
To enhance the overall performance of perovskite solar cells, the quality of the electron transport layer (ETL) held significant importance. Zinc oxide (ZnO) emerged as highly promising due to its exceptional optical and electrical characteristics. This study included the incorporation of lanthanum (La III) into the ZnO lattice to improve its optoelectronic properties. All the produced thin films were crystallized at low annealing temperatures. Through careful analysis, it was observed that the inclusion of doping with 4% La (III) resulted in increased crystallinity, leading to low surface roughness. Additionally, this doping strategy facilitated enhanced mobility of charge carriers and conductivity.
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(This article belongs to the Proceedings of CEMP 2023)
Global demand for cumene is rising day by day due to its broad applications in the production of numerous types of polymers like nylon-6, epoxy resins, and polycarbonates. Efforts to enhance process design and operation efficiency are ongoing. However, addressing process uncertainties remains
[...] Read more.
Global demand for cumene is rising day by day due to its broad applications in the production of numerous types of polymers like nylon-6, epoxy resins, and polycarbonates. Efforts to enhance process design and operation efficiency are ongoing. However, addressing process uncertainties remains a significant challenge for stable process industry operations. Artificial neural networks (ANNs) have proven to be powerful tools for modelling and predicting complex chemical processes, offering substantial potential for improving the quality and quantity of cumene production. In the present study, a data-based model was used for the prediction of the molar flow and mole fraction of cumene in the final product stream. A steady-state Aspen plus model was set to a dynamic mode by deliberately introducing ±10% variability in process conditions. This dynamic model served as the foundation for generating a comprehensive dataset. Two ANN models were developed using the dataset for the prediction of the molar flow and mole fraction of cumene. During the rigorous testing phase, the models demonstrated outstanding performance, as evidenced by their correlation coefficient values of 0.99216 and 0.99412 for the molar flow and mole fraction of cumene, respectively. These high correlation coefficients provide compelling evidence of the models’ robust and precise predictive capabilities, highlighting their potential for real-world application. This study paves the way for Al integration in the process industry, making a significant step toward embracing industry 4.0.
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(This article belongs to the Proceedings of CEMP 2023)
Heat carried upward by atmospheric convection produces mechanical energy. An atmospheric vortex engine (AVE) uses a synthetic tornado-like vortex to capture mechanical energy from upward heat convection. The vortex is created by tangentially introducing warm or humid air into a circular wall base.
[...] Read more.
Heat carried upward by atmospheric convection produces mechanical energy. An atmospheric vortex engine (AVE) uses a synthetic tornado-like vortex to capture mechanical energy from upward heat convection. The vortex is created by tangentially introducing warm or humid air into a circular wall base. Heat sources include solar energy, warm sea water, warm, humid air, and industrial waste. Earth’s natural surface collects heat, eliminating the need for solar collectors. The AVE uses the same thermodynamic principles as the solar chimney, but it uses centrifugal force in a vortex instead of a chimney and the earth’s surface instead of a collector. Turbogenerators nearby generate mechanical energy. Since the AVE uses less fuel to generate the same amount of electricity, it could reduce global warming. An AVE increases thermal power plant efficiency by lowering its cold-source temperature from the base of the troposphere to the tropopause. The AVE process could reduce global warming by lifting heat above greenhouse gases to radiate toward space. Since Pakistan is most affected by climate change and has many energy crises, this study aims to change engineers’ mindsets from inefficient conventional energy sources to more efficient non-conventional, cleaner energy sources.
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(This article belongs to the Proceedings of CEMP 2023)
This study investigates the flow of a magnetohydrodynamic (MHD) Maxwell fluid over a stretching sheet using a Darcy-Forchheimer (DF) model. We employ numerical analysis with a copper (Cu) nanofluid suspended in water, considering Cattaneo–Christov heat flow, viscous dissipation, and joule heating. Nonlinear ordinary
[...] Read more.
This study investigates the flow of a magnetohydrodynamic (MHD) Maxwell fluid over a stretching sheet using a Darcy-Forchheimer (DF) model. We employ numerical analysis with a copper (Cu) nanofluid suspended in water, considering Cattaneo–Christov heat flow, viscous dissipation, and joule heating. Nonlinear ordinary differential equations (ODEs) are solved using the bvp4c method in Matlab and we examine the normalized shear stress, temperature profile, and heat flux rate. Our findings reveal insights for practical applications, showing how parameters such as the relaxation Prandtl number, magnetic parameter, Eckert number parameter, and radiation parameter impact system behaviour.
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(This article belongs to the Proceedings of CEMP 2023)
Life on Earth is being affected daily by the enormous amounts of greenhouse gas emissions, due to the utilization of fossil fuels to produce energy for almost everything. Many researchers have been working for the development of new clean and sustainable energy sources
[...] Read more.
Life on Earth is being affected daily by the enormous amounts of greenhouse gas emissions, due to the utilization of fossil fuels to produce energy for almost everything. Many researchers have been working for the development of new clean and sustainable energy sources such as solar and wind energies. Hydrogen, being a clean fuel having very high calorific value, can be used as a storage medium for these renewable energy sources and can be used efficiently in fuel cells, as well as in combustion engines. This research is focused on the investigation of hydrogen production through the electrolysis of water. An Aspen Plus-based model for the electrolysis process has been designed and validated and its exergy analysis has been conducted. Also, the improvement potential of all the equipment has been reported.
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(This article belongs to the Proceedings of CEMP 2023)
Photosensitizers have been used for years to treat or diagnose several oncological diseases. In this research, we evaluate Rhodamine (Rh-640 perchlorate), a second-generation photosensitizer’s mediated preliminary photodynamic effects. To investigate these preliminary dose–response effects on the Rhabdomyosarcoma cancer cell line, the UV absorption
[...] Read more.
Photosensitizers have been used for years to treat or diagnose several oncological diseases. In this research, we evaluate Rhodamine (Rh-640 perchlorate), a second-generation photosensitizer’s mediated preliminary photodynamic effects. To investigate these preliminary dose–response effects on the Rhabdomyosarcoma cancer cell line, the UV absorption spectra, standard curve, and cytotoxic analysis of Rh-640 perchlorate are demonstrated. The absorption spectra suggest that longer wavelengths of light like yellow-red light are best used for light irradiation. Different concentrations are used to evaluate absorbance and cytotoxic response. The results suggest that Rh-640 perchlorate may be used for the selective destruction of cancer cells without imposing any toxicity on normal cells in the dark. This research finding also suggests that its efficiency may also be evaluated on other cancer cell lines.
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(This article belongs to the Proceedings of CEMP 2023)
Reducing greenhouse gas (GHG) emissions through carbon capture and conversion to fuel and other useful products is a focus of recent research. Among all fuels, CO2 to methanol stands out for its efficiency and promise. To make the CO2-to-methanol (CTM)
[...] Read more.
Reducing greenhouse gas (GHG) emissions through carbon capture and conversion to fuel and other useful products is a focus of recent research. Among all fuels, CO2 to methanol stands out for its efficiency and promise. To make the CO2-to-methanol (CTM) process sustainable and efficient, it needs to be analyzed with respect to its thermodynamic potential. Conventionally, energy analysis was used, but exergy analysis is an advanced tool used for this purpose. In this study, the Aspen Plus-based CTM model was developed, and its exergy analysis was carried out. Physical exergy data are taken from Aspen Plus V.11, while an interface between Aspen Plus and Excel was used to calculate the exergy destruction, exergy efficiency, and the improvement potential of the process. All three sections of the CTM model were compared and it was observed that the separation section has the highest exergy destruction of 37,225.89 KW with an exergy efficiency and exergetic improvement potential of 76.17% and 8870.75 KW, respectively.
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(This article belongs to the Proceedings of CEMP 2023)
Organic solar cells (OSCs) have the potential to generate electricity under sunlight at a low cost. In this study, the influence of active layer thickness, defect density, temperature and the presence of reflective coating is studied for the structure ITO/PTAA/PBDB-T: ITIC-OE/PDINO/Ag, by applying
[...] Read more.
Organic solar cells (OSCs) have the potential to generate electricity under sunlight at a low cost. In this study, the influence of active layer thickness, defect density, temperature and the presence of reflective coating is studied for the structure ITO/PTAA/PBDB-T: ITIC-OE/PDINO/Ag, by applying PTAA as a hole transport layer (HTL), while the blend of PBDB-T: ITIC-OE is used as an active layer and PDINO is applied as electron transport layer (ETL), respectively. Solar capacitance simulator one-dimensional (SCAPS—1D) software is used to optimize different parameters, which affect the performance of OSCs. By introducing backside reflective coating, the efficiency increases by 2.5%. In the future, this study can be used for the power conversion efficiency (PCE) enhancement of OSCs.
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(This article belongs to the Proceedings of CEMP 2023)
Due to growing industrialization and population increase, water scarcity is becoming a major global concern. Desalination is often regarded as a potential solution to the worldwide water crisis; however, due to rising prices and energy usage, desalination has remained a research focus. Traditionally,
[...] Read more.
Due to growing industrialization and population increase, water scarcity is becoming a major global concern. Desalination is often regarded as a potential solution to the worldwide water crisis; however, due to rising prices and energy usage, desalination has remained a research focus. Traditionally, specific energy consumption (SEC) kWh/m3 for seawater desalination has been calculated using a hybrid approach that ignores membrane design attributes and operational parameters. The current study constructed a mathematical framework based on well-established theory to quantify and compare the energy consumption of pressure-driven and osmotic-driven membrane separation processes by incorporating the necessary membrane design and operational parameters into the model framework. The model results were compared to the literature data and found to be in good agreement. The findings of this study show a non-linear relationship between the membrane flowrate factor and the energy needs of reverse osmosis RO, with the effect being more obvious at low values of Kf < 50 L/h.bar, where Kf is equal to the product of membrane permeability and membrane area. The results also showed that the lowest SEC was obtained at 60–65% recovery, and, from model testing, the energy consumption was 3.65 kWh/m3 and 3.88 kWh/m3 for the RO and FO–RO processes, respectively. Additionally, the hybrid process demands more membrane area, which further raises the cost of desalination. The mathematical framework developed in this work will act as a prediction design tool for membrane plant designers to check and compare the feasibility of these processes before experimental work to save money and time.
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(This article belongs to the Proceedings of CEMP 2023)
Energy is the primary concern of the modern era and the requirement of energy is being increased day by day; energy resources are not sufficiently available for sustainable development. It is crucial to generate affordable and pollution-free sources of energy to meet this
[...] Read more.
Energy is the primary concern of the modern era and the requirement of energy is being increased day by day; energy resources are not sufficiently available for sustainable development. It is crucial to generate affordable and pollution-free sources of energy to meet this required demand. Walking is a common daily activity for humans; the kinetic energy from walking is converted into mechanical energy. Moreover, this energy is converted into electrical power using a rack-and-pinion mechanism which is simply a non-conventional method of producing electric current. In this research study, a simple and low-cost rack-and-pinion mechanism with a flywheel is introduced to enhance the performance and efficiency of energy conversion from kinetic energy to mechanical energy and subsequently into electrical energy. The results showed that the proposed footstep floor tile generated an average power of 3 watts for a 0.5 s duration with a peak load of 60 kg. The electrical energy produced per step was noted as 1.8 Joules. A percentage of 75% of the total potential energy theoretically accessible was transmitted by the energy-harvesting paver, and 50% of it was successfully converted into electricity. The generated energy is stored in a backup battery bank system and can be used to charge smart devices, providing a cost-effective and pollution-free solution.
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(This article belongs to the Proceedings of CEMP 2023)
All inorganic perovskite colloidal nano crystals are an emerging class of optoelectronic materials. However, their colloidal and structural stability during isolation and washing are major hurdles for their commercial application. Their intrinsic chemical instability and optical stability are directly related to the bonding
[...] Read more.
All inorganic perovskite colloidal nano crystals are an emerging class of optoelectronic materials. However, their colloidal and structural stability during isolation and washing are major hurdles for their commercial application. Their intrinsic chemical instability and optical stability are directly related to the bonding nature of the nanocrystals’ surface and organic capping agents that passivate the surface of nanocrystals. We studied the surface ligand properties of CsPbBr3 prepared by the conventional hot injection method and their washing with varying polarity antisolvent. We observed changes in electrical and optical properties through experimental studies. The study was mainly done by optical and electronic measurements. We determined a facile nanocrystal washing protocol and observed a considerable improvement in the optoelectronic properties of the all-inorganic perovskite colloidal nanocrystals.
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(This article belongs to the Proceedings of CEMP 2023)
Herein, two commercially available spiral-wound nanofiltration (NF) and reverse-osmosis (RO) membrane elements were tested for aqueous ammonium nitrate salt separation. The effect of feed concentration and salt rejection as a function of transmembrane pressure were evaluated. NF and RO membranes exhibited 60% and
[...] Read more.
Herein, two commercially available spiral-wound nanofiltration (NF) and reverse-osmosis (RO) membrane elements were tested for aqueous ammonium nitrate salt separation. The effect of feed concentration and salt rejection as a function of transmembrane pressure were evaluated. NF and RO membranes exhibited 60% and 92% ammonium nitrate salt rejection, respectively, upon the initial feed concentration of 0.1 wt% at a seven-bar operating pressure. High ammonium nitrate salt rejection by the RO membrane was owing to its relatively small pore size compared to the NF membrane. It was found experimentally that the commercially available RO and NF membrane elements can be used for ammonium nitrate salt rejections from industrial effluents at ambient conditions.
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(This article belongs to the Proceedings of CEMP 2023)
Nuclear power plays a significant role in fulfilling the energy needs of Pakistan and its share in the total energy mix has increased from 4.7% to 8.8% in the past seven years. As per the Pakistan energy outlook report (2021–2030), this share is
[...] Read more.
Nuclear power plays a significant role in fulfilling the energy needs of Pakistan and its share in the total energy mix has increased from 4.7% to 8.8% in the past seven years. As per the Pakistan energy outlook report (2021–2030), this share is hypothesized to increase to 10.82% by the year 2030, which will alleviate the energy shortage problem and, at same time, reduce carbon emissions. Like all thermal power plants, it is also necessary for nuclear plants to operate at optimum efficiency. This study is based on the thermodynamic analysis of the conventional side of an advanced HPR-1000 (PWR) nuclear power plant. In this paper, a comparison of indigenously developed model results is made, with vendor-provided sea water temperatures and power curves for year-long sea water temperature variation. Firstly, a computational model is developed using Engineering Equation Solver (EES) software to evaluate the performance of the secondary side of the plant and is validated based on the designer-provided heat balance analysis for full power mode. Then, the condenser heat balance is performed for different cooling medium inlet temperatures and terminal temperature differences to study the relationship of condenser performance, thermal efficiency, and output power. Initial results reveal that sea water temperature varies at the condenser inlet from 5 to 35 °C, the power output of the unit decreases by 54 MW, and the thermodynamic efficiency drops by 1.79%. Thus, this paper highlights the impact of sea water temperature on plant performance and the need to devise more effective techniques to approach the plant’s optimum efficiency.
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(This article belongs to the Proceedings of CEMP 2023)
This study presents a solar-powered parabolic dish desalination system with a solar tracking system and conical receiver. It efficiently transforms solar radiation into heat and evaporates saltwater, producing fresh water. The system is sustainable and affordable, making it a viable solution for water
[...] Read more.
This study presents a solar-powered parabolic dish desalination system with a solar tracking system and conical receiver. It efficiently transforms solar radiation into heat and evaporates saltwater, producing fresh water. The system is sustainable and affordable, making it a viable solution for water desalination in areas with limited access to fresh water. It achieves a high conversion rate from saltwater to fresh water, while consuming minimal energy. The results indicate that the system effectively utilizes solar energy, exhibiting high efficiency levels ranging from 78.56% to 82.77%, with an average efficiency of 80.79%. This system offers an effective solution to meet the growing demand for fresh water in water-scarce regions.
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(This article belongs to the Proceedings of CEMP 2023)
A sustainable alternative to fossil fuels, cow dung is a renewable energy source that might considerably lower carbon emissions. By modifying its characteristics, such as its gross calorific value (GCV), it could be utilized as a flexible and effective fuel for both industrial
[...] Read more.
A sustainable alternative to fossil fuels, cow dung is a renewable energy source that might considerably lower carbon emissions. By modifying its characteristics, such as its gross calorific value (GCV), it could be utilized as a flexible and effective fuel for both industrial and domestic use. To create a fuel composite with a higher heating value, this research examines the heating values and proximate analysis of local cow dung as well as the effects of blending it with agricultural waste. To provide the best heating value, the technique comprises infusing prepared agricultural biomass blends and cow dung at particular ratios. The composite’s quality was enhanced by increasing GCV from 3066 Kcal/kg to 3600 Kcal/kg, increasing volatile matter content, i.e., from 60% to 68%, as well as lowering the ash content of the resultant pellet from 19% to 11%, on average.
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(This article belongs to the Proceedings of CEMP 2023)
The present study was conducted to develop highly ordered facile TiO2 nanotubes (TiNTs) at two different applied voltages using two-step electrochemical anodization for the application in dye-sensitized solar cells (DSSCs). The nanotube fabrication is carried out in an aqueous electrolyte containing ethylene
[...] Read more.
The present study was conducted to develop highly ordered facile TiO2 nanotubes (TiNTs) at two different applied voltages using two-step electrochemical anodization for the application in dye-sensitized solar cells (DSSCs). The nanotube fabrication is carried out in an aqueous electrolyte containing ethylene glycol and ammonium fluoride at 40 V and 60 V fixed applied potentials. Nanotubes synthesized at 40 V are comparatively uniform and smoother, whereas a rough top surface is observed at 60 V. The photovoltaic efficiency achieved for the device based on TiNTs prepared at 40 V is 0.84% which is higher than the efficiency achieved for the 60 V device. This work highlights the importance of ordered nanotubes for efficient devices.
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(This article belongs to the Proceedings of CEMP 2023)
Lignin, a paper and pulp industry waste product, has attracted significant attention in recent years as a promising sustainable material for high-end energy applications. Herein, we examine lignin as a potential material for ionic thermoelectric hydrogels and carbon-based materials. Optimized lignin-derived hydrogels demonstrate
[...] Read more.
Lignin, a paper and pulp industry waste product, has attracted significant attention in recent years as a promising sustainable material for high-end energy applications. Herein, we examine lignin as a potential material for ionic thermoelectric hydrogels and carbon-based materials. Optimized lignin-derived hydrogels demonstrate a remarkable Seebeck coefficient of 3.63 mV/K when subjected to an axial temperature gradient. Furthermore, synthesized lignin-based porous carbon materials exhibit exceptional performance as supercapacitor electrodes, with a superior specific capacitance of 56.3 F/g at 0.5 A/g. Lignin-based hydrogels and porous carbon electrodes offer a promising path towards the development of lignin-derived ionic thermoelectric supercapacitors.
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(This article belongs to the Proceedings of CEMP 2023)
Rare earth elements (REEs) have emerged as strategic elements. Due to their unique electronic and magnetic properties, REEs have extensive applications in modern-day technologies. Two aspects make the supply chain of REEs very critical: first, more than ~85% of the global rare earth
[...] Read more.
Rare earth elements (REEs) have emerged as strategic elements. Due to their unique electronic and magnetic properties, REEs have extensive applications in modern-day technologies. Two aspects make the supply chain of REEs very critical: first, more than ~85% of the global rare earth elements are processed by China alone; second, presently, hardly any substitute materials exist for these elements. The supply chain of these elements is vulnerable because of the Chinese monopoly on rare earth resources. These circumstances drove researchers to explore alternative resources for these elements. This article reviews the prospective alternative resources of REEs. Based on the available resources and technical experience, a road map has also been suggested.
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(This article belongs to the Proceedings of CEMP 2023)
The present work is on the synthesis and investigation of the structural, optical, and optoelectrical properties of NbSe2 as an efficient material for energy conversion applications. The liquid phase exfoliation method was employed for the synthesis of 2D nanosheets from the bulk
[...] Read more.
The present work is on the synthesis and investigation of the structural, optical, and optoelectrical properties of NbSe2 as an efficient material for energy conversion applications. The liquid phase exfoliation method was employed for the synthesis of 2D nanosheets from the bulk NbSe2 at different exfoliation levels. SEM was used to confirm the physical dimensions of the nanosheets, while XRD was used to verify the structural retention of hexagonal nanosheets. The results demonstrate that high-quality, single-crystalline NbSe2 nanosheets with a size of ≈1 μm in the lateral dimension and ≈6–12 nm thick were obtained. The 2D nanosheets will be further explored for energy storage and conversion applications.
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(This article belongs to the Proceedings of CEMP 2023)
Perovskite solar cells (PSCs) have rapidly become a hot area of research in the photovoltaic field due to their (e.g., 26.2%), ease of fabrication, and low cost. Over the last decade the electron transport layer (ETL) has been one of the most critical
[...] Read more.
Perovskite solar cells (PSCs) have rapidly become a hot area of research in the photovoltaic field due to their (e.g., 26.2%), ease of fabrication, and low cost. Over the last decade the electron transport layer (ETL) has been one of the most critical elements in achieving high-performing solar cells, necessitating a higher electron mobility and superior charge extraction ability. Consequently, there is a significant demand for an improved ETL that is not only cost-effective but also exhibits high charge extraction and mobility, particularly in the context of planar solar cell architecture. Tin Oxide (SnO2) has emerged as one of the most promising high-performance inorganic ETLs suitable for PSCs. In this work, we synthesize solution-processed SnO2. The spin-coated SnO2 thin films undergo annealing at relatively low temperatures ranging from 130 °C to 180 °C and various characterization tools are employed for the evaluation of thin films.
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(This article belongs to the Proceedings of CEMP 2023)
This research delves into asymmetric supercapacitor (ASC) design, utilizing activated carbon from bamboo poles (AC) and electrodeposited polyaniline (PANI) on nickel foam (NF) as key active components. The composite electrode formed from AC and PANI exhibited enhanced electrochemical attributes in various electrochemical configurations.
[...] Read more.
This research delves into asymmetric supercapacitor (ASC) design, utilizing activated carbon from bamboo poles (AC) and electrodeposited polyaniline (PANI) on nickel foam (NF) as key active components. The composite electrode formed from AC and PANI exhibited enhanced electrochemical attributes in various electrochemical configurations. The specified ASC, PANI@AC/NF//AC/NF, demonstrated a potential of 1.8 V. Impressively, it reached an areal capacitance measuring 423 mF/cm2, coupled with an energy density of 190 µWh/cm2 at a power density of 900 µW/cm2, and maintained ~82% capacitance after 5000 GCD cycles. Notably, our developed ASC presents outstanding research potential for scholars and scientists.
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(This article belongs to the Proceedings of CEMP 2023)
The demand for energy is gradually increasing; governments are looking for affordable and long-lasting solutions. Hydropower is crucial for addressing this issue. Low-head hydropower stations are necessary in certain regions due to their geographical position. Gravitational water vortex turbines are an alternative for
[...] Read more.
The demand for energy is gradually increasing; governments are looking for affordable and long-lasting solutions. Hydropower is crucial for addressing this issue. Low-head hydropower stations are necessary in certain regions due to their geographical position. Gravitational water vortex turbines are an alternative for these low-head turbines. They use the water’s tangential flow to create a vortex, converting mechanical energy to kinetic energy. The design of turbine blades and basins using SolidWorks and CFD analysis was carried out during this research. CFD investigation showed that the conical basin had a higher exit velocity than the cylindrical basin, indicating a successful design.
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(This article belongs to the Proceedings of CEMP 2023)