| People | Locations | Statistics |
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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Lundström, Mari
Aalto University
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (41/41 displayed)
- 2024Graphite recovery from waste Li-ion battery black mass for direct re-usecitations
- 2023Recent developments of electrodeposition-redox replacement in metal recovery and functional materials: A reviewcitations
- 2023Assessment of environmental sustainability of nickel required for mobility transitioncitations
- 2023Assessment of environmental sustainability of nickel required for mobility transitioncitations
- 2023Flowsheet design and environmental impacts of cobalt co-product recovery from complex Au-Co orescitations
- 2023Emeraldine Salt-Nanocarbon Composites as a Material for Copper Recovery from Industrial Wastewaters
- 2022Carbon Nanotube-Based Thermoelectric Modules Enhanced by ZnO Nanowirescitations
- 2022Electrochemical Growth of Ag/Zn Alloys from Zinc Process Solutions and Their Dealloying Behaviorcitations
- 2022A New Hydrometallurgical Process for Metal Extraction from Electric Arc Furnace Dust Using Ionic Liquidscitations
- 2022Green and Controllable Preparation of Cu/Zn Alloys Using Combined Electrodeposition and Redox Replacementcitations
- 2022Targeted surface modification of Cu/Zn/Ag coatings and Ag/Cu particles based on sacrificial element selection by electrodeposition and redox replacementcitations
- 2021Cyclic voltammetry and potentiodynamic polarization studies of chalcopyrite concentrate in glycine mediumcitations
- 2021Performance-Based Selection of the Cathode Material for the Electrodeposition-Redox Replacement Process of Gold Recovery from Chloride Solutionscitations
- 2021Copper cathode contamination by nickel in copper electrorefiningcitations
- 2021Biopolymeric Anticorrosion Coatings from Cellulose Nanofibrils and Colloidal Lignin Particlescitations
- 2021Copper recovery from industrial wastewater - Synergistic electrodeposition onto nanocarbon materialscitations
- 2020Mechanism of selective gold extraction from multi-metal chloride solutions by electrodeposition-redox replacementcitations
- 2020Mechanism of selective gold extraction from multi-metal chloride solutions by electrodeposition-redox replacementcitations
- 2020A sustainable two-layer lignin-anodized composite coating for the corrosion protection of high-strength low-alloy steelcitations
- 2020Transformation of industrial wastewater into copper–nickel nanowire composites : straightforward recycling of heavy metals to obtain products of high added valuecitations
- 2020Investigation of the anticorrosion performance of lignin coatings after crosslinking with triethyl phosphate and their adhesion to a polyurethane topcoat
- 2019Energy efficient copper electrowinning and direct deposition on carbon nanotube film from industrial wastewaterscitations
- 2019Sulfation Roasting Mechanism for Spent Lithium-Ion Battery Metal Oxides Under SO2-O2-Ar Atmospherecitations
- 2019Modelling of silver anode dissolution and the effect of gold as impurity under simulated industrial silver electrorefining conditionscitations
- 2018A Sustainable Methodology for Recycling Electric Arc Furnace Dustcitations
- 2018Structural distinction due to deposition method in ultrathin films of cellulose nanofibrescitations
- 2018From waste to valuable resource: Lignin as a sustainable anti-corrosion coatingcitations
- 2018A direct synthesis of platinum/nickel co-catalysts on titanium dioxide nanotube surface from hydrometallurgical-type process streamscitations
- 2018Corrosion behaviour of cast and deformed copper-carbon nanotube composite wires in chloride mediacitations
- 2018Selective reductive leaching of cobalt and lithium from industrially crushed waste Li-ion batteries in sulfuric acid systemcitations
- 2018Kinetic study and modelling of silver dissolution in synthetic industrial silver electrolyte as a function of electrolyte composition and temperaturecitations
- 2018Carbon Nanotube Fiber Pretreatments for Electrodeposition of Coppercitations
- 2018Jarogain Process:A Hydrometallurgical Option to Recover Metal Values from RLE Zinc Residue and Steel Dust
- 2018Hydrometallurgical approach for leaching of metals from copper rich side stream originating from base metal productioncitations
- 2018Platinum recovery from Industrial Process Solutions by Electrodepo-sition-Redox Replacement
- 2017Designing gold extraction processes:Performance study of a case-based reasoning systemcitations
- 2017Designing gold extraction processes: performance study of a case-based reasoning systemcitations
- 2017Leaching of Sb from TROF furnace Doré slagcitations
- 2017Simulation of electrochemical processes during oxygen evolution on Pb-MnO2 composite electrodescitations
- 2017Primary Copper Smelter and Refinery as a Recycling Plant—A System Integrated Approach to Estimate Secondary Raw Material Tolerancecitations
- 2016Carbon nanotube-copper composites by electrodeposition on carbon nanotube fiberscitations
Places of action
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article
Emeraldine Salt-Nanocarbon Composites as a Material for Copper Recovery from Industrial Wastewaters
Abstract
<jats:p>Nanocarbon films are characterized by high surface area<jats:sup>[1]</jats:sup>, appreciable electrical conductivity<jats:sup>[2]</jats:sup>, and good mechanical properties<jats:sup>[3]</jats:sup>. These properties make them suitable for application as electrode materials in various electrochemical processes. For instance, nanocarbon electrodes can be used for selective deposition of metals onto their surface<jats:sup>[4]</jats:sup>. In particular, it is beneficial to accumulate Cu atoms on the surface of carbon nanomaterials as such composite exhibits much improved electrical conductivity and strength. To make this process as efficient as possible, functional groups containing oxygen or nitrogen are attached to the nanocarbon surface, prior to electrodeposition, but their presence may deteriorate the capabilities of material for charge propagation.</jats:p><jats:p>Alternatively, conductive polymers such as polyaniline (PANI) can be physically attached to carbon to improve their electrochemical properties<jats:sup>[5]</jats:sup>, without introducing defects in the structure that negatively affect the electrical properties of the material. Different forms of PANI have substantial effects on the properties of composites, emeraldine salts (ES) have been chosen based upon their higher electrical properties. ES are characterized by the highest increase in electrical and mechanical properties of composites.</jats:p><jats:p>Our research focused on the selective deposition of metals onto</jats:p><jats:p> ES-nanocarbon composites from industrial wastewaters, which contained such metals as magnesium, iron, nickel, and copper. Aniline was electropolymerized onto the nanocarbon surface by cyclic voltammetry to make the material more suitable for recovery of metals from such source. The process of copper recovery was highly selective, which was confirmed by characterization of the surface by EDX mapping. Despite the trace amounts of copper (428 ppm) in the used industrial wastewater, Cu nanoparticles were highly visible on the PANI-nanocarbon surface after just one hour of the process. Analogously, nickel has also been recovered by this method, which demonstrates that the presented approach may be tuned for deposition of various metals onto nanocarbon to make previously unreported nanocarbon-metal composites.</jats:p><jats:p><jats:italic>P.S. would like to thank the Ministry of Education and Science (MEiN/2022/DIR/3086) of Poland for financial support, which enabled the attendance to the conference. G.S. and P.S. would like to thank the Ministry of Education and Science of Poland for financial support of scientific work from budget funds for science in the years 2019–2023 as a research project under the “Diamond Grant” program (grant agreement 0036/DIA/201948). G.S., P.S. and D.J. would like to thank the National Centre for Research and Development, Poland (under the Leader program, grant agreement LIDER/0001/L-8/16/NCBR/2017). P.S. acknowledges the National Agency for Academic Exchange of Poland (NAWA, (under the Academic International Partnerships program, grant agreement PPI/APM/2018/1/00004) for supporting training in the Aalto University, which enabled the execution of the study. GS would like to thank also NAWA (under the Iwanowska program, grant agreement PPN/IWA/2019/1/00017/UO/00001) for financial support during the stay at the University of Pittsburgh in the USA.</jats:italic></jats:p><jats:p><jats:list list-type="roman-lower"><jats:list-item><jats:p>M. Cadek et al, <jats:italic>Nano Letters,</jats:italic> 2004, 4, 2, 353–356</jats:p></jats:list-item><jats:list-item><jats:p>G. Stando et al, <jats:italic>Scientific Reports, 2022,</jats:italic> 12, 4358</jats:p></jats:list-item><jats:list-item><jats:p>J. Salvetat et al. <jats:italic>Appl Phys A, </jats:italic>1999, 69, 255–260</jats:p></jats:list-item><jats:list-item><jats:p>G. Stando et al, <jats:italic>Water Resources and Industry, </jats:italic>2021, 26, 100156</jats:p></jats:list-item><jats:list-item><jats:p>A. Kumar et al, <jats:italic>Polymer-Plastics Technology and Engineering</jats:italic>, 2018, 57, 2, 70-97</jats:p></jats:list-item></jats:list></jats:p>