Güler, Enver
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Name Variants
G.,Enver
Guler, Enver
G., Enver
E., Güler
E.,Güler
Güler,E.
Enver, Güler
E., Guler
Guler,E.
Enver, Guler
Guler E.
Güler E.
Güler, Enver
E.,Guler
Guler, E.
Guler, Enver
G., Enver
E., Güler
E.,Güler
Güler,E.
Enver, Güler
E., Guler
Guler,E.
Enver, Guler
Guler E.
Güler E.
Güler, Enver
E.,Guler
Guler, E.
Job Title
Doçent Doktor
Email Address
enver.guler@atilim.edu.tr
Main Affiliation
Chemical Engineering
Status
Website
ORCID ID
Scopus Author ID
Turkish CoHE Profile ID
Google Scholar ID
WoS Researcher ID
Scholarly Output
30
Articles
16
Citation Count
167
Supervised Theses
6
5 results
Scholarly Output Search Results
Now showing 1 - 5 of 5
Book Part Citation - Scopus: 2Ion Exchange Membranes in Electrodialysis Process for Wastewater Treatment(Elsevier, 2023) Altıok,E.; Cihanoğlu,A.; Güler,E.; Kabay,N.; Chemical EngineeringWater is the most important natural resource on earth. Survival without water is impossible and industries cannot operate without water as well. Availability of safe and reliable source of water is therefore essential. Different practical solutions are needed for sustainable preservation of water resources as freshwater resources are limited in terms of technical and economical aspects. Membrane technologies can be applied to water and wastewater treatment for removal of various unwanted substances from water. Recently, the utilization of membrane technologies in the water purification sector has grown exponentially. Compared to conventional reclamation methods, membrane technologies are much more efficient for removal of various contaminants and they are able to overcome more stringent water regulations. Membrane separation processes employed for water treatment include reverse osmosis, nanofiltration, ultrafiltration, microfiltration, and electrodialysis (ED). In this chapter, we reviewed the basic principles of electromembrane processes, such as ED, electrodeionization, electrodialysis reversal, and bipolar membrane ED based on ion exchange membranes (IEMs) along with few examples of the use of these processes in water and wastewater treatment. In addition, fouling of IEMs is also discussed. © 2024 Elsevier Inc. All rights reserved.Book Part Citation - Scopus: 0Application of Nanofiltration for Reclamation and Reuse of Wastewater and Spent Geothermal Fluid(CRC Press, 2023) Jarma,Y.A.; Cihanoğlu,A.; Güler,E.; Tomaszewska,B.; Kasztelewicz,A.; Baba,A.; Kabay,N.; Chemical EngineeringAfter the extraction of energy from the geothermal fluid, the consumed geothermal water can be considered as a potential water resource for agricultural and industrial purposes. The used geothermal water can also be used as a source of drinking water, which could reduce the pressure on the current clean water resources. On the other hand, geothermal fluids brought to the surface need to be treated in the most economical way before discharge into the surface environment or aquifer. Several processes have shown promising results for the treatment of geothermal water. Membrane processes such as nanofiltration (NF) and reverse osmosis (RO) can be considered as a technology for obtaining good quality irrigation water from geothermal water. This chapter summarizes the application of NF for the recovery and reuse of wastewater and spent geothermal water. © 2024 selection and editorial matter, Abdul Wahab Mohammad, Teow Yeit Haan and Nidal Hidal; individual chapters, the contributors.Book Part Citation - Scopus: 2Green Energy Generation Using Membrane Technologies Based on Salinity Gradient(Elsevier, 2023) Güler,E.; Cihanoğlu,A.; Altıok,E.; Kaya,T.Z.; Eti,M.; Kabay,N.; Chemical EngineeringElectrical energy can be extracted from salinity gradients, often represented by two aqueous solutions with different salinities. This becomes very interesting when sustainable and practical electromembrane processes can be applied to convert the salinity gradient power into electric power. Reverse electrodialysis (RED), in this context, has gained much interest in the last few years. In addition to many operational and design parameters affecting the process output, ion exchange membranes (IEMs) represent core elements in RED. In this chapter, it is aimed to introduce and discuss the current trend of IEMs as well as vital operational parameters and fouling affecting the RED performance. © 2023 Elsevier Inc. All rights reserved.Book Part Citation - Scopus: 12Water Flux and Reverse Salt Flux(Elsevier, 2018) Koseoglu,H.; Guler,E.; Harman,B.I.; Gonulsuz,E.; Chemical EngineeringFollowing the increase in the world population and the demand for economic development, the need for energy has increased day by day. Rapidly increasing global energy consumption is supplied mainly by fossil fuels bearing the risk of exhaustion with decreasing reserves, which now have the effect of carbon emissions and greenhouse gases. These concerns lead humanity to significantly reduce the use of fossil fuels. Salinity gradient energy (SGP), a type of hydroelectric energy, also has a high potential to displace fossil fuels. SGP is less periodic than sources like wind and solar energy. The osmotic pressure gradient energy uses the released energy during mixing of the water currents with different salinity The Gibbs free energy from mixing two solutions of different concentrations is an unnoticed source of energy. Salinity gradient energy, also referred to as osmotic energy or blue energy, can be derived from natural sources such as clean river water, salt water, and desalination of seawater. Various approaches have been developed to capture salinity gradient energy, but the most promising are pressure-retarded osmosis (PRO), reverse electrodialysis (RED) and forward osmosis (FO) processes. In this chapter theoretical approaches derived from the current literature is presented for the deep conceptual understanding of the water flux and reverse salt flux issues. © 2018 Elsevier B.V. All rights reserved.Book Part Citation - Scopus: 0Current Status of Ion Exchange Membranes for Electrodialysis/Reverse Electrodialysis and Membrane Capacitive Deionization/Capacitive Mixing(Elsevier, 2022) Kabay,N.; Güler,E.; Smolinska-Kempisty,K.; Bryjak,M.; Chemical EngineeringThe world is facing several critical problems, which were integrated by the United Nation into the 17 Sustainable Development Goals (SDGs). Adopted by all the U.N. member states, the SDGs provide goals for attaining a common welfare by 2030. Among these goals, access to clean water and green energy are the most important challenges. The use of ion exchange membranes for the production of safe water and harvesting renewable energy seem to meet these challenges. This chapter will present the history and perspectives of the use of ion exchange membranes for these struggles. © 2022 Elsevier Inc. All rights reserved.
