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Composites of two-dimensional materials for energy storage
Údaje o názvu Composites of two-dimensional materials for energy storage [rukopis] / Smita Talande Další variantní názvy Composites of two-dimensional materials for energy storage Osobní jméno Talande, Smita, (autor diplomové práce nebo disertace) Překl.náz Composites of two-dimensional materials for energy storage Vyd.údaje 2020 Fyz.popis 88 : grafy, tab. Poznámka Ved. práce Aristeidis Bakandritsos Dal.odpovědnost Bakandritsos, Aristeidis, (školitel) Dal.odpovědnost Univerzita Palackého. Katedra experimentální fyziky (udelovatel akademické hodnosti) Klíč.slova Supercapacitors * transition metal oxides/ sulfides * functionalized graphene * non-aqueous electrolyte * energy density * Supercapacitors * transition metal oxides/ sulfides * functionalized graphene * non-aqueous electrolyte * energy density Forma, žánr disertace dissertations MDT (043.3) Země vyd. Česko Jazyk dok. angličtina Druh dok. PUBLIKAČNÍ ČINNOST Titul Ph.D. Studijní program Doktorský Studijní program Physics Studijní obor Applied Physics kniha
Kvalifikační práce Staženo Velikost datum zpřístupnění 00222734-330751503.pdf 41 5 MB 12.11.2020 Posudek Typ posudku 00222734-opon-712181275.pdf Posudek oponenta 00222734-ved-981582287.pdf Posudek vedoucího 00222734-opon-430624611.pdf Posudek oponenta Průběh obhajoby datum zadání datum odevzdání datum obhajoby přidělená hodnocení typ hodnocení 00222734-prubeh-781753980.pdf 07.09.2016 12.11.2020 16.02.2021 S 2 Ostatní přílohy Velikost Popis 00222734-other-590956210.pdf 6.2 MB
The constant increase in energy demand combined with our non-renewable fossil fuelbased civilization producing a negative environmental impact (CO2 emission) calls for the development of sustainable energy conversion and storage with a small environmental footprint. Electrochemical technologies such as supercapacitors (SCs) and batteries are emerging as important energy storage devices for electronics, electric vehicles, and smart grids. SCs display remarkable advantages over batteries, such as ultrafast charging, high power dissipation, and extralong cyclelife. Furthermore, they are a cheaper and far more sustainable energy storage technology, since they are carbon-based, not requiring lowabundance elements as batteries do (i.e. lithium, cobalt, or nickel). However, stateoftheart SCs materials are lagging behind Li-ion batteries in energy content by order of magnitude. A lot of research effort is thus focused on increasing the energy content of SCs in order to exploit their advantages in applications requiring energy supply for more extended periods. For this purpose, we have studied methods in order to increase the performance of SCs electrode materials via developing hybrids by combining the densely functionalized graphene derivative (Cyanographene, GCN) with ultra-small nanoparticles of -FeOOH and Fe3S4.The constant increase in energy demand combined with our non-renewable fossil fuelbased civilization producing a negative environmental impact (CO2 emission) calls for the development of sustainable energy conversion and storage with a small environmental footprint. Electrochemical technologies such as supercapacitors (SCs) and batteries are emerging as important energy storage devices for electronics, electric vehicles, and smart grids. SCs display remarkable advantages over batteries, such as ultrafast charging, high power dissipation, and extralong cyclelife. Furthermore, they are a cheaper and far more sustainable energy storage technology, since they are carbon-based, not requiring lowabundance elements as batteries do (i.e. lithium, cobalt, or nickel). However, stateoftheart SCs materials are lagging behind Li-ion batteries in energy content by order of magnitude. A lot of research effort is thus focused on increasing the energy content of SCs in order to exploit their advantages in applications requiring energy supply for more extended periods. For this purpose, we have studied methods in order to increase the performance of SCs electrode materials via developing hybrids by combining the densely functionalized graphene derivative (Cyanographene, GCN) with ultra-small nanoparticles of -FeOOH and Fe3S4.
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