Browsing by Author "Munir, Mamoona"

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    A Comprehensive Review of the Latest Advancements in Controlling Arsenic Contaminants in Groundwater
    (Multidisciplinary Digital Publishing Institute (MDPI), 2023-02) Dilpazeer, Fariha; Munir, Mamoona; Baloch, Muhammad Yousuf Jat; Shafiq, Iqrash; Iqbal, Javeeria; Saeed, Muhammad; Abbas, Muhammad Mujtaba; Shafique, Sumeer; Aziz, Kosar Hikmat Hama; Mustafa, Ahmad; Mahboob, Iqra
    Water contaminated with arsenic is a worldwide problem. This review presents the arsenic contamination in groundwater, its sources, and possible health risk to humans. Groundwater pollution is the most common route of inorganic arsenic exposure in humans. Arsenic concentrations in different countries were analyzed and projected on a map. Because arsenic is widely spread throughout the Earth’s crust, it is present in trace amounts in practically all waterways. Harmful levels of this toxin have been identified in drinking water in some regions. For drinking purposes, the majority of people use groundwater; excess arsenic levels in groundwater have been linked to a variety of negative health impacts on people. Arsenic exposure is the world’s leading environmental cause of cancer. The main aim of this review is to summarize the effective technologies to remove arsenic from drinking water, such as ion exchange, coagulation/flocculation, and membrane technologies like ultra-filtration and electrodialysis, helping to deal with the adverse effects caused by arsenic exposure. All these technologies present different advantages and disadvantages. Electrocoagulation, adsorption, and phytoremediation are the most efficient and cost-effective technologies. The removal efficiencies of arsenic using these technologies and prospects were also included
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    Eco-friendly isopropyl myristate production in a fixed bed reactor: Leveraging energy-saving enzymatic techniques with a comprehensive evaluation of techno-economic feasibility
    (Elsevier Ltd, 2024-06) Mustafa, Ahmad; Sadek, M. Shaaban; Abou Taleb, Manal F; Munir, Mamoona; Kutlu, Ozben; Pastore, Carlo; Bitonto, Luigi di; Faisal, Shah; Hammad, Hossam; Ibrahim, Mohamed M; Abdellatief, Tamer M.M; Bokhari, Awais; Samuel, Olusegun David; Inayat, Abrar; El-Bahy, Zeinhom M
    This study aims to develop a straightforward, eco-friendly, and energy-saving approach for producing isopropyl myristate (IPM) through lipase-catalyzed esterification in a fixed bed reactor. The reaction between isopropyl alcohol and myristic acid was catalyzed using Novozym 435. Response Surface Methodology (RSM) was utilized to examine the interaction of various reaction parameters on the yield of IPM. The highest observed and predicted conversion rates were 95 % and 94.2 %, respectively. The optimum conditions included a molar ratio of isopropyl alcohol to myristic acid of 15:1, a time of 12 h, and a flow rate of 1.25 ml/min. The synthesized IPM was isolated and comprehensively characterized using GC–MS, FTIR, 1H, and 13C NMR techniques. To further validate the applicability of this method, a Process Simulation Diagram (PSD) was developed using ASPEN PLUS software to simulate IPM production under the optimized conditions. Economic analysis revealed a positive net present value (NPV) of $169,664,820.33 and a return on investment (ROI) of 536.52 %, indicating that this sustainable approach offers low investment risks and high profitability.
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    Has the time finally come for green oleochemicals and biodiesel production using large-scale enzyme technologies? Current status and new developments
    (Elsevier Inc., 2023-10) Mustafa, Ahmad; Faisal, Shah; Ahmed, Inas A; Munir, Mamoona; Cipolatti, Eliane Pereira; Manoel, Evelin Andrade; Pastore, Carlo; di Bitonto, Luigi; Hanelt, Dieter; Nitbani, Febri Odel; El-Bahy, Zeinhom M; Inayat, Abrar; Abdellatief, Tamer M.M; Tonova, Konstantza; Bokhari, Awais; Abomohra, Abdelfatah
    With the growth of the chemical industry over the last decade, the need for cheaper (and more environmentally friendly) alternatives to petrochemicals of ever-increasing cost has grown steadily. Oleochemicals and biodiesel (OC/BD) are considered as green alternatives to petroleum derivatives, because they come from renewable oils and fats. OC/BD are currently produced by the traditional energy intensive chemical catalyzed methods, which have several economic and environmental drawbacks. For these reasons, the enzymatic production of OC/BD has attracted a growing attention for their greener pathway with respect to the chemically catalyzed processes. Lipase-catalyzed processes have a low energy requirement, since reactions are performed under atmospheric pressure and mild temperature and without the creation of side reactions. Furthermore, utilization of enzyme catalysts offers many advantages such as reducing the initial capital investment due to simplified downstream processing steps. Despite all the previous advantages, however, the high cost of lipases restricted their large-scale utilization. In the past decade, efforts have been made to reduce the cost of the enzymatic-catalyzed synthesis of OC/BD. However, most previous studies have studied only the technical feasibility of the lipase-catalyzed re- actions and overlocked the economic viability. This review critically discusses the factors affecting the promotion of the economic feasibility of the enzymatic processes from the lab to large scale. These include reactor configuration, type of feedstock, conditions optimization, immobilization, lipase-producing microorganisms
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    Has the time finally come for green oleochemicals and biodiesel production using large-scale enzyme technologies? Current status and new developments
    (Elsevier Inc, 2023-12) Mustafa, Ahmad; Faisal, Shah; Ahmed, Inas A; Munir, Mamoona; Cipolatti, Eliane Pereira; Manoel, Evelin Andrade; Pastore, Carlo; Bitonto, Luigi di; Hanelt, Dieter; Nitbani, Febri Odel; El-Bahy, Zeinhom M; Inayat, Abrar; Abdellatief, Tamer M.M; Tonova, Konstantza; Bokhari, Awais; Abomohra, Abdelfatah
    With the growth of the chemical industry over the last decade, the need for cheaper (and more environmentally friendly) alternatives to petrochemicals of ever-increasing cost has grown steadily. Oleochemicals and biodiesel (OC/BD) are considered as green alternatives to petroleum derivatives, because they come from renewable oils and fats. OC/BD are currently produced by the traditional energy intensive chemical catalyzed methods, which have several economic and environmental drawbacks. For these reasons, the enzymatic production of OC/BD has attracted a growing attention for their greener pathway with respect to the chemically catalyzed processes. Lipase-catalyzed processes have a low energy requirement, since reactions are performed under atmospheric pressure and mild temperature and without the creation of side reactions. Furthermore, utilization of enzyme catalysts offers many advantages such as reducing the initial capital investment due to simplified downstream processing steps. Despite all the previous advantages, however, the high cost of lipases restricted their large-scale utilization. In the past decade, efforts have been made to reduce the cost of the enzymatic-catalyzed synthesis of OC/BD. However, most previous studies have studied only the technical feasibility of the lipase-catalyzed reactions and overlocked the economic viability. This review critically discusses the factors affecting the promotion of the economic feasibility of the enzymatic processes from the lab to large scale. These include reactor configuration, type of feedstock, conditions optimization, immobilization, lipase-producing microorganisms.
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    Unleashing the power of non-edible oil seeds of Ipomoea cairica for cleaner and sustainable biodiesel production using green Molybdenum Oxide (MoO3) nano catalyst
    (Elsevier Ltd, 2024-04) Chaudhry, Bisha; Ahmad, Mushtaq; Munir, Mamoona; Ramadan, Mohamed Fawzy; Munir, Mumna; Mussagy, Cassamo Ussemane; Faisal, Shah; Abdellatief, Tamer M.M; Mustafa, Ahmad
    This research aims to conduct a thorough analysis of the novel and cost-effective use of Ipomoea cairica L. seeds as a potential feedstock for green energy technologies. Ipomoea cairica L. seeds (42 % oil, 0.67 % free fatty acid content) were used as a promising source for producing sustainable biodiesel using novel green Molybdenum Oxide (MoO3) nanocatalyst. The Ipomoea cairica seeds utilized in this study serve a dual purpose: they provide feedstock for the future energy mix, and their seed shells (considered waste) are used as a starting material for synthesizing green nanocatalysts. The highest biodiesel yield of 95 % was achieved under optimal reaction conditions of 1:15 oil to methanol molar ratio, 50 °C, 120 min, and 0.4 (wt.%) catalyst loading. In order to evaluate the quality and characteristics of the resultant biodiesel and synthesized nanocatalyst, a detailed examination was conducted utilizing analytical techniques such EDX, XRD, FTIR, SEM, NMR (1H, 13C) and GC–MS analysis. The phytofabricated nanocatalyst unveils highest recyclability (up to 5 cycles), reactivity, stability and efficiency during transesterification operations. The produced biodiesel was also optimized using response surface methodology (Box-Behnken Design). When compared to conventional diesel, the biodiesel made from Ipomoea cairica L. seed oil showed better oxidative stability and reduced viscosity, suggesting that it might be a viable replacement for conventional fuel without compromising engine performance. Moreover, using untamed, uncultivated, and non-edible seed plants to produce biodiesel presents a chance to move toward a more sustainable and environmentally friendly energy plan.