Scopus İndeksli Yayınlar Koleksiyonu / Scopus Indexed Publications Collection

Permanent URI for this collectionhttps://hdl.handle.net/11147/7148

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Now showing 1 - 7 of 7
  • Book Part
    Citation - Scopus: 5
    Scaling Problem of the Geothermal System in Turkey
    (CRC Press, 2014) Doğan,I.; Demir,M.M.; Baba,A.
    [No abstract available]
  • Book Part
    Citation - Scopus: 12
    Green electrospinning
    (De Gruyter, 2019) Horzum,N.; Muñoz-Espí,R.; Hood,M.A.; Demir,M.M.; Crespy,D.
    In the last two decades, electrospinning has grown in popularity; however, the majority of the setups are based on solution processing from toxic organic solvents. As green processing and environmental stewardship have also become important in recent years, for political and economic reasons, the subsequent increase in demand for the scaling up of electrospinning requires that an environmentally toxin-free process be championed. This book comprehensively addresses clean and safe electrospinning for the fabrication of green nanofibers and evaluates their potential applications. © 2019 Walter de Gruyter GmbH, Berlin/Boston. All rights reserved.
  • Book Part
    Citation - Scopus: 4
    Pressure Sensors Based on Ipmc Actuator
    (Springer Science and Business Media B.V., 2019) Topcu,G.; Guner,T.; Demir,M.M.
    Pressure sensors provide information regarding with the magnitude and distribution of force along the interface. To characterize the force as a measurand, pressure sensors convert the force into especially electrical signals. Ionic polymer-metal composites have received great interest in pressure sensor technology apart from soft biomimetic actuator applications. In this chapter, we provide further insight into the IPMC materials in pressure sensor applications in terms of system design, working principle, and preparation. In addition, the current status of applications and markets of pressure sensors is described with reference to some published patents. Moreover, their historical evolution, various designs, and classification are also discussed. © 2019, Springer Nature Switzerland AG.
  • Book
    Citation - Scopus: 6
    Green electrospinning
    (De Gruyter, 2019) Horzum,N.; Muñoz-Espí,R.; Demir,M.M.; Crespy,D.
    The last two decades have seen electrospinning of nanofibers performed mainly from solutions of toxic organic solvents. The increase in demand for scaling up electrospinning in recent years therefore requires an environmentally friendly process free of organic solvents. This book addresses techniques for clean and safe electrospinning in the fabrication of green nanofibers and their potential applications. © 2019 Walter de Gruyter GmbH, Berlin/Boston. All rights reserved.
  • Book Part
    Citation - Scopus: 4
    Green Processes and Green Fibers
    (De Gruyter, 2019) Horzum,N.; Muñoz-Espí,R.; Hood,M.A.; Demir,M.M.; Crespy,D.
    "Green Electrospinning" not from only non-toxic solvents but also from biopolymer solutions has become popular in recent years. Green fibers are particularly interesting for biomedical applications such as tissue engineering, drug delivery, biocompatible scaffolds, biosensors, and for photovoltaics, supercapacitors, fuel cells, battery components as energy fields, and for filtration membranes as environmental applications. In this chapter, we classified green electrospinning into two groups: (i) green processes as polymer free, solvent free, solution, and colloid electrospinning, (ii) green fibers from natural polymers and blends. © 2019 Walter de Gruyter GmbH, Berlin/Boston. All rights reserved.
  • Article
    Citation - WoS: 4
    Citation - Scopus: 3
    Ligand Engineering for Improving the Stability and Optical Properties of Cspbi3 Perovskite Nanocrystals
    (Elsevier B.V., 2024) Yuce Cakir,H.; Yalcinkaya,Y.; Demir,M.M.
    Inorganic lead halide perovskite nanocrystals (NCs) have recently become one of the research topics for optoelectronic applications due to their excellent photophysical properties. Despite their notable thermal stability over organic-inorganic halide perovskites, CsPbI3 NCs suffer from the phase instability of α-CsPbI3 phase at room temperature and under ambient conditions. Here, the effects of 4-Hydroxybenzoic acid (4-HBA) as an additive to standard oleic acid – oleylamine pair on the stability and optical properties of CsPbI3 perovskite NCs are discussed. 4-HBA addition into perovskite NC systems causes a compressive strain on perovskite lattice, which leads to the formation of a mixed phase α- and γ-CsPbI3 phases while pristine perovskite has α-CsPbI3 phase. Time-dependent stability of the perovskite NCs was tested under an ethanol (EtOH) medium. After EtOH exposure of the perovskite NCs, CsPbI3 NCs transformed to non-perovskite phase in 1 h while 4-HBA added CsPbI3 NCs still have perovskite phase after 48 h. In addition to the improved optical properties of the perovskite NCs, 4-HBA addition remarkably improves CsPbI3 perovskite stability. © 2024 Elsevier B.V.
  • Article
    Citation - WoS: 21
    Citation - Scopus: 23
    Lithium: an Energy Transition Element, Its Role in the Future Energy Demand and Carbon Emissions Mitigation Strategy
    (Elsevier Ltd, 2024) Chandrasekharam,D.; Şener,M.F.; Recepoğlu,Y.K.; Isık,T.; Demir,M.M.; Baba,A.
    Energy transition elements (Li, Ni, Co, Fe, Cu) are gaining importance due to their ability to provide energy and play an important role as primary energy sources. Because of the energy density and power density, Li-ion batteries have the edge over other batteries. Li is distributed in various rock-forming minerals and brines, and geothermal waters. Though lithium-bearing minerals are spread over a broad geographic region, these minerals are confined to certain countries with substantial economic potential. Li is extensively used in batteries, and battery-driven vehicles are growing exponentially to meet the carbon reduction goal of the Paris agreement in 2015 and signed by more than 50 percent of the countries. Nearly 55 million cars supported by Li batteries are expected to roll out by 2030. While this is the demand, its occurrence and concentration/extraction processes are not keeping pace with this demand. The extraction of Li from its ore is an energy-intensive process involving many fossil fuel-based energies. To recover one ton of Li metal, nearly 5 to 6 tons of CO2 is emitted. The CO2 emissions of 28 kWh LFP, NMC, and LMO batteries vary from 5600 to 2705 kg CO2-eq. The end-of-life emissions of an internal combustion engine (ICE) vehicle are 400 kg CO2/vehicle, while Li Battery supports 500 kg/vehicle. The quantity of Li required for a 24 kWh average capacity leaf battery is about 137 g/kWh. While emissions are associated with the manufacturing of the batteries, emissions are also associated with a way that while they are recharged as the recharging source is fossil fuel-based energy. The best option to meet zero net carbon emissions by 2050, as envisaged by International Energy Agency (IEA), is to recover Li from geothermal brines and use geothermal energy for recharging. While hydrothermal energy sources are site-specific, enhanced geothermal system (EGS) based geothermal energy is not site-specific and is found wherever high radiogenic granites are available. High radiogenic granites are widely distributed, and heat recovered from EGS sources can provide clean energy and heat. Extraction of lithium from geothermal waters and using geothermal energy for recharging the batteries will drastically reduce CO2 emissions. It will drive the world towards Net Zero Emissions (NZE) scenario in the future. This is being practiced in Turkey. Future research should develop technology to recover Li from geothermal fluids with low concentration and support EGS development. © 2024 Elsevier Ltd