TY - THES A1 - Ilic, Ivan T1 - Design of sustainable cathodes for Li-ion batteries T1 - Design nachhaltiger Kathoden für Li-Ionen-Batterien BT - understanding the redox behaviour of guaiacyl and catecholic groups in lithium organic system N2 - In recent years people have realised non-renewability of our modern society which relays on spending huge amounts of energy mostly produced from fosil fuels, such as oil and coal, and the shift towards more sustainable energy sources has started. However, sustainable sources of energy, such as wind-, solar- and hydro-energy, produce primarily electrical energy and can not just be poured in canister like many fosil fuels, creating necessity for rechragable batteries. However, modern Li-ion batteries are made from toxic heavy metals and sustainable alternatives are needed. Here we show that naturally abundant catecholic and guaiacyl groups can be utilised to replace heavy metals in Li-ion batteries. Foremost vanillin, a naturally occurring food additive that can be sustainably synthesised from industrial biowaste, lignin, was utilised to synthesise materials that showed extraordinary performance as cathodes in Li-ion batteries. Furthermore, behaviour of catecholic and guiacyl groups in Li-ion system was compared, confirming usability of guiacayl containing biopolymers as cathodes in Li-ion batteries. Lastly, naturally occurring polyphenol, tannic acid, was incorporated in fully bioderived hybrid material that shows performance comparable to commercial Li-ion batteries and good stability. This thesis presents an important advancement in understanding of biowaste derived cathode materials for Li-ion batteries. Further research should be conducted to better understand behaviour of guaiacyl groups during Li-ion battery cycling. Lastly, challenges of incorporation of lignin, an industrial biowaste, have to be addressed and lignin should be incorporated as a cathode material in Li-ion batteries. N2 - Diese Dissertation untersucht, wie nachhaltige Kathoden (Kathodenmaterialien) für Lithium-Ionen-Batterien aus Holzabfällen hergestellt werden können. In den letzten Jahren hat die Menschheit erkannt, wie wenig nachhaltig unsere moderne Gesellschaft ist und große Mengen an Energie verbraucht, welche zum größten Teil aus fossilen Brennstoffen gewonnen werden. Daher versucht man jetzt die Energie aus hauptsächlich erneuerbaren Quellen wie Sonne und Wind zu gewinnen. Allerdings kann elektrische Energie nicht einfach wie Öl in einen Kanister gegossen werden, sondern muss in wieder aufladbaren Batterien gespeichert werden. In den letzten Jahren wurden Lithium-Ionen-Batterien entwickelt, die leistungsstark und allgegenwärtig sind, da sie zum Beispiel in Handys und sogar Autos Verwendung finden. Lithium-Ionen-Batterien verwenden jedoch Trägermaterialien aus giftigen Schwermetallen, die abgebaut werden müssen, was sich negativ auf die Umwelt auswirkt. In diesem Zusammenhang ist insbesondere das Schwermetall Kobalt zu erwähnen, welches in den meisten modernen Kathoden verwendet wird. Nach dem Bekanntwerden von Sklaverei und Kinderarbeit beim Kobaltabbau im Kongo, folgten große Kontroversen, da Kobalt praktisch in jedem Gerät führender Unternehmen wie zum Beispiel Apple und Microsoft zu finden ist. Idealerweise müssen wir von nicht erneuerbaren Schwermetallen zu erneuerbaren organischen Molekülen wechseln. Daher verwende ich in meiner Forschung Vanillin, ein Molekül, das hinsichtlich der Elektronenspeicherung ähnliche Eigenschaften wie Schwermetalle aufweist, jedoch viele Vorteile bietet. Erstens erkennt man Vanillin am spezifischen Geruch, da es einer der Hauptbestandteile von Vanille und daher ein natürlich vorkommendes Molekül ist. Zweitens kann es aus Holzabfällen oder aus Abfällen vieler Industrien hergestellt werden, die Holz als Rohstoff verwenden, wie beispielsweise der Papierindustrie. Durch milde chemische Reaktionen in Lösemitteln wie Wasser, Essig und Alkohol haben wir Vanillin zu einem Material modifiziert, welches hervorragende Eigenschaften zur Verwendung in Lithium-Ionen-Batterien hat und die bisher verwendeten Schwermetelle ersetzen kann. Diese Batterien wären somit erneuerbar und können uns der nachhaltigen Welt einen Schritt näher bringen. Darüber hinaus wurde Tanninsäure, ein natürlich vorkommendes Polymer in Holzrinde, verwendet, um vollständig aus Bioabfällen bestehende Batterien herzustellen. KW - biomass KW - electrochemistry KW - energy conversion KW - polymers KW - redox chemistry KW - Biomasse KW - Elektrochemie KW - Energieumwandlung KW - Polymere KW - Redoxchemie Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-483689 ER - TY - GEN A1 - Ilic, Ivan K. A1 - Tsouka, Alexandra A1 - Perovic, Milena A1 - Hwang, Jinyeon A1 - Heil, Tobias A1 - Löffler, Felix A1 - Oschatz, Martin A1 - Antonietti, Markus A1 - Liedel, Clemens T1 - Sustainable cathodes for Lithium-ion energy storage devices based on tannic acid-toward ecofriendly energy storage T2 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe N2 - The use of organic materials with reversible redox activity holds enormous potential for next-generation Li-ion energy storage devices. Yet, most candidates are not truly sustainable, i.e., not derived from renewable feedstock or made in benign reactions. Here an attempt is reported to resolve this issue by synthesizing an organic cathode material from tannic acid and microporous carbon derived from biomass. All constituents, including the redox-active material and conductive carbon additive, are made from renewable resources. Using a simple, sustainable fabrication method, a hybrid material is formed. The low cost and ecofriendly material shows outstanding performance with a capacity of 108 mAh g(-1) at 0.1 A g(-1) and low capacity fading, retaining approximately 80% of the maximum capacity after 90 cycles. With approximately 3.4 V versus Li+/Li, the cells also feature one of the highest reversible redox potentials reported for biomolecular cathodes. Finally, the quinone-catecholate redox mechanism responsible for the high capacity of tannic acid is confirmed by electrochemical characterization of a model compound similar to tannic acid but without catecholic groups. T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1366 KW - biomass KW - electrochemistry KW - energy storage KW - redox chemistry KW - sustainability KW - tannic acid Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-570560 SN - 1866-8372 IS - 1 ER - TY - JOUR A1 - Ilic, Ivan K. A1 - Tsouka, Alexandra A1 - Perovic, Milena A1 - Hwang, Jinyeon A1 - Heil, Tobias A1 - Löffler, Felix A1 - Oschatz, Martin A1 - Antonietti, Markus A1 - Liedel, Clemens T1 - Sustainable cathodes for Lithium-ion energy storage devices based on tannic acid-toward ecofriendly energy storage JF - Advanced sustainable systems N2 - The use of organic materials with reversible redox activity holds enormous potential for next-generation Li-ion energy storage devices. Yet, most candidates are not truly sustainable, i.e., not derived from renewable feedstock or made in benign reactions. Here an attempt is reported to resolve this issue by synthesizing an organic cathode material from tannic acid and microporous carbon derived from biomass. All constituents, including the redox-active material and conductive carbon additive, are made from renewable resources. Using a simple, sustainable fabrication method, a hybrid material is formed. The low cost and ecofriendly material shows outstanding performance with a capacity of 108 mAh g(-1) at 0.1 A g(-1) and low capacity fading, retaining approximately 80% of the maximum capacity after 90 cycles. With approximately 3.4 V versus Li+/Li, the cells also feature one of the highest reversible redox potentials reported for biomolecular cathodes. Finally, the quinone-catecholate redox mechanism responsible for the high capacity of tannic acid is confirmed by electrochemical characterization of a model compound similar to tannic acid but without catecholic groups. KW - biomass KW - electrochemistry KW - energy storage KW - redox chemistry KW - sustainability KW - tannic acid Y1 - 2020 U6 - https://doi.org/10.1002/adsu.202000206 SN - 2366-7486 VL - 5 IS - 1 PB - Wiley-VCH CY - Weinheim ER - TY - JOUR A1 - Ilic, Ivan A1 - Schutjajew, Konstantin A1 - Zhang, Wuyong A1 - Oschatz, Martin T1 - Changes of porosity of hard carbons during mechanical treatment and the relevance for sodium-ion anodes JF - Carbon : an international journal sponsored by the American Carbon Society N2 - Lithium-ion batteries have revolutionized battery technology. However, the scarcity of lithium in nature is driving the search for alternatives. For that reason, sodium-ion batteries have attracted increasing attention in recent years. The main obstacle to their development is the anode as, unlike for lithium-ion batteries, graphite cannot be used due to the inability to form stoichiometrically useful intercalation compounds with sodium. A promising candidate for sodium storage is hard carbon a form of nongraphitisable carbon, that can be synthesized from various precursor materials. Processing of hard carbons is often done by using mechanochemical treatments. Although it is generally accepted and often observed that they can influence the porosity of hard carbons, their effect on battery performance not well understood. Here, the changes in porosity occurring during ball milling are elucidated and related to the properties of hard carbons in sodium storage. Analysis by combined gas physisorption and small angle X-ray scattering shows that porosity changes during ball milling with a significant increase of the open porosity, unsuitable for reversible sodium storage, and decrease of the closed porosity, suitable for reversible sodium storage. While pristine hard carbon can store 58.5 mAh g(-1) in the closed pores, upon 5 h of mechanical treatment in a ball mill it can only store 35.5 mAh g(-1). The obtained results are furthermore pointing towards the disputed "intercalation-adsorption" mechanism. KW - Hard carbons KW - Sodium-ion batteries KW - Anodes KW - Microporosity KW - Ball milling Y1 - 2022 U6 - https://doi.org/10.1016/j.carbon.2021.09.063 SN - 0008-6223 SN - 1873-3891 VL - 186 SP - 55 EP - 63 PB - Elsevier Science CY - Amsterdam [u.a.] ER - TY - BOOK A1 - Kuban, Robert A1 - Rotta, Randolf A1 - Nolte, Jörg A1 - Chromik, Jonas A1 - Beilharz, Jossekin Jakob A1 - Pirl, Lukas A1 - Friedrich, Tobias A1 - Lenzner, Pascal A1 - Weyand, Christopher A1 - Juiz, Carlos A1 - Bermejo, Belen A1 - Sauer, Joao A1 - Coelh, Leandro dos Santos A1 - Najafi, Pejman A1 - Pünter, Wenzel A1 - Cheng, Feng A1 - Meinel, Christoph A1 - Sidorova, Julia A1 - Lundberg, Lars A1 - Vogel, Thomas A1 - Tran, Chinh A1 - Moser, Irene A1 - Grunske, Lars A1 - Elsaid, Mohamed Esameldin Mohamed A1 - Abbas, Hazem M. A1 - Rula, Anisa A1 - Sejdiu, Gezim A1 - Maurino, Andrea A1 - Schmidt, Christopher A1 - Hügle, Johannes A1 - Uflacker, Matthias A1 - Nozza, Debora A1 - Messina, Enza A1 - Hoorn, André van A1 - Frank, Markus A1 - Schulz, Henning A1 - Alhosseini Almodarresi Yasin, Seyed Ali A1 - Nowicki, Marek A1 - Muite, Benson K. A1 - Boysan, Mehmet Can A1 - Bianchi, Federico A1 - Cremaschi, Marco A1 - Moussa, Rim A1 - Abdel-Karim, Benjamin M. A1 - Pfeuffer, Nicolas A1 - Hinz, Oliver A1 - Plauth, Max A1 - Polze, Andreas A1 - Huo, Da A1 - Melo, Gerard de A1 - Mendes Soares, Fábio A1 - Oliveira, Roberto Célio Limão de A1 - Benson, Lawrence A1 - Paul, Fabian A1 - Werling, Christian A1 - Windheuser, Fabian A1 - Stojanovic, Dragan A1 - Djordjevic, Igor A1 - Stojanovic, Natalija A1 - Stojnev Ilic, Aleksandra A1 - Weidmann, Vera A1 - Lowitzki, Leon A1 - Wagner, Markus A1 - Ifa, Abdessatar Ben A1 - Arlos, Patrik A1 - Megia, Ana A1 - Vendrell, Joan A1 - Pfitzner, Bjarne A1 - Redondo, Alberto A1 - Ríos Insua, David A1 - Albert, Justin Amadeus A1 - Zhou, Lin A1 - Arnrich, Bert A1 - Szabó, Ildikó A1 - Fodor, Szabina A1 - Ternai, Katalin A1 - Bhowmik, Rajarshi A1 - Campero Durand, Gabriel A1 - Shevchenko, Pavlo A1 - Malysheva, Milena A1 - Prymak, Ivan A1 - Saake, Gunter ED - Meinel, Christoph ED - Polze, Andreas ED - Beins, Karsten ED - Strotmann, Rolf ED - Seibold, Ulrich ED - Rödszus, Kurt ED - Müller, Jürgen T1 - HPI Future SOC Lab – Proceedings 2019 N2 - The “HPI Future SOC Lab” is a cooperation of the Hasso Plattner Institute (HPI) and industry partners. Its mission is to enable and promote exchange and interaction between the research community and the industry partners. The HPI Future SOC Lab provides researchers with free of charge access to a complete infrastructure of state of the art hard and software. This infrastructure includes components, which might be too expensive for an ordinary research environment, such as servers with up to 64 cores and 2 TB main memory. The offerings address researchers particularly from but not limited to the areas of computer science and business information systems. Main areas of research include cloud computing, parallelization, and In-Memory technologies. This technical report presents results of research projects executed in 2019. Selected projects have presented their results on April 9th and November 12th 2019 at the Future SOC Lab Day events. N2 - Das Future SOC Lab am HPI ist eine Kooperation des Hasso-Plattner-Instituts mit verschiedenen Industriepartnern. Seine Aufgabe ist die Ermöglichung und Förderung des Austausches zwischen Forschungsgemeinschaft und Industrie. Am Lab wird interessierten Wissenschaftlern eine Infrastruktur von neuester Hard- und Software kostenfrei für Forschungszwecke zur Verfügung gestellt. Dazu zählen teilweise noch nicht am Markt verfügbare Technologien, die im normalen Hochschulbereich in der Regel nicht zu finanzieren wären, bspw. Server mit bis zu 64 Cores und 2 TB Hauptspeicher. Diese Angebote richten sich insbesondere an Wissenschaftler in den Gebieten Informatik und Wirtschaftsinformatik. Einige der Schwerpunkte sind Cloud Computing, Parallelisierung und In-Memory Technologien. In diesem Technischen Bericht werden die Ergebnisse der Forschungsprojekte des Jahres 2019 vorgestellt. Ausgewählte Projekte stellten ihre Ergebnisse am 09. April und 12. November 2019 im Rahmen des Future SOC Lab Tags vor. T3 - Technische Berichte des Hasso-Plattner-Instituts für Digital Engineering an der Universität Potsdam - 158 KW - Future SOC Lab KW - research projects KW - multicore architectures KW - in-memory technology KW - cloud computing KW - machine learning KW - artifical intelligence KW - Future SOC Lab KW - Forschungsprojekte KW - Multicore Architekturen KW - In-Memory Technologie KW - Cloud Computing KW - maschinelles Lernen KW - künstliche Intelligenz Y1 - 2023 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-597915 SN - 978-3-86956-564-4 SN - 1613-5652 SN - 2191-1665 IS - 158 PB - Universitätsverlag Potsdam CY - Potsdam ER -