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HETEROATOM-DOPED NANOPOROUS CARBONS: SYNTHESIS, CHARACTERIZATION AND APPLICATION TO GAS STORAGE AND SEPARATIONAshourirad, Babak 01 January 2015 (has links)
Activated carbons as emerging classes of porous materials have gained tremendous attention because of their versatile applications such as gas storage/separations sorbents, oxygen reduction reaction (ORR) catalysts and supercapacitor electrodes. This diversity originates from fascinating features such as low-cost, lightweight, thermal, chemical and physical stability as well as adjustable textural properties. More interestingly, sole heteroatom or combinations of various elements can be doped into their framework to modify the surface chemistry. Among all dopants, nitrogen as the most frequently used element, induces basicity and charge delocalization into the carbon network and enhances selective adsorption of CO2. Transformation of a task-specific and single source precursor to heteroatom-doped carbon through a one-step activation process is considered a novel and efficient strategy.
With these considerations in mind, we developed multiple series of heteroatom doped porous carbons by using nitrogen containing carbon precursors. Benzimidazole-linked polymers (BILP-5), benzimidazole monomer (BI) and azo-linked polymers (ALP-6) were successfully transformed into heteroatom-doped carbons through chemical activation by potassium hydroxide. Alternative activation by zinc chloride and direct heating was also applied to ALP-6. The controlled activation/carbonization process afforded diverse textural properties, adjustable heteroatom doping levels and remarkable gas sorption properties. Nitrogen isotherms at 77 K revealed that micropores dominate the porous structure of carbons. The highest Brunauer-Emett-Teller (BET) surface area (4171 m2 g-1) and pore volume (2.3 cm3 g-1) were obtained for carbon synthesized by KOH activation of BI at 700 °C. In light of the synergistic effect of basic heteroatoms and fine micropores, all carbons exhibit remarkable gas capture and selectivity. Particularly, BI and BIPL-5 derived carbons feature unprecedented CO2 uptakes of 6.2 mmol g-1 (1 bar) and 2.1 mmol g-1 (0.15 bar) at 298 K, respectively. The ALP-6 derived carbons retained considerable amount of nitrogen dopants (up to 14.4 wt%) after heat treatment owing to the presence of more stable nitrogen-nitrogen bonds compared to nitrogen-carbon bonds in BILP-5 and BI precursors. Subsequently, the highest selectivity of 62 for CO2/N2 and 11 for CO2/CH4 were obtained at 298 K for a carbon prepared by KOH activation of ALP-6 at 500 °C.
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Synthesis and Formation Mechanism of Carbon Materials from Porous Coordination Polymers / 多孔性配位高分子を用いた炭素材料の合成とその形成機構の解明Fujiwara, Yu-ichi 26 March 2018 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第21125号 / 工博第4489号 / 新制||工||1698(附属図書館) / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 杉野目 道紀, 教授 吉田 潤一, 教授 松田 建児 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM
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Tailoring Pore Size and Polarity for Liquid Phase Adsorption by Porous CarbonsHippauf, Felix 29 May 2017 (has links) (PDF)
Adsorption is a versatile purification technique to selectively separate different peptide fractions from a mixture using mild operation conditions. Porous carbons are ideally suited to separate ACE-inhibiting dipeptides by combining tailored size exclusion and polarity selectivity. The desired peptide fraction is mostly hydrophobic and very small and should adsorb inside hydrophobic micropores.
The second topic of this thesis is linked to energy storage. The lithium-sulfur battery is a promising alternative to common lithium-ion batteries with theoretical capacities of up to 1672 mAh g−1 sulfur. The second aim of this thesis is to conduct an in-depth investigation of polysulfides interacting with selected carbon materials in a simplified battery electrolyte environment. The focus of this study is laid on the impact of surface polarity and pore size distribution of the carbon to develop a quantitative correlation between polysulfide retention and porosity metrics.
Both, the enrichment of ACE-inhibitors and the retention of polysulfides rely on liquid phase adsorption in porous materials, linking the above mentioned topics. This thesis not only aims to develop an enrichment process or to find a superior battery cathode but also strives to explore structure-property relationships that are universally valid. Understanding the complex interplay of pore size and polarity leading to selective interactions between pore wall and the adsorbed species is given a high priority.
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Nitrogen-enriched, ordered mesoporous carbons for potential electrochemical energy storageZhu, Jinhui, Yang, Jun, Miao, Rongrong, Zhaoquan, Zhaoquan, Zhuang , Xiaodong, Feng, Xinliang 17 July 2017 (has links) (PDF)
Nitrogen-doped (N-doped) porous carbons have drawn increasing attention due to their high activity for electrochemical catalysis, and high capacity for lithium-ion (Li-ion) batteries and supercapacitors. So far, the controlled synthesis of N-enriched ordered mesoporous carbons (N-OMCs) for Li-ion batteries is rarely reported due to the lack of a reliable nitrogen-doping protocol that maintains the ordered mesoporous structure. In order to realize this, in this work, ordered mesoporous carbons with controllable N contents were successfully prepared by using melamine, F127 and phenolic resin as the N-source, template and carbon-source respectively via a solvent-free ball-milling method. The as-prepared N-OMCs which showed a high N content up to 31.7 wt% were used as anodes for Li-ion batteries. Remarkably, the N-OMCs with an N content of 24.4 wt% exhibit the highest reversible capacity (506 mA h g−1) even after 300 cycles at 300 mA g−1 and a capacity retention of 103.3%. N-OMCs were also used as electrode materials in supercapacitors and a capacity of 150 F g−1 at 0.2 A g−1 with stable cycling up to 2500 times at 1 A g−1 was achieved. These attractive results encourage the design and synthesis of high heteroatom content ordered porous carbons for applications in the field of energy storage and conversion.
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Development of tannin-derived porous carbons with tailored porosity for carbon dioxide adsorptionPHURIRAGPITIKHON, JENJIRA 26 January 2021 (has links)
No description available.
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Polymer-based mesoporous carbons: soft-templating synthesis, adsorption and structural propertiesGorka, Joanna 23 November 2010 (has links)
No description available.
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Cesium-Mediated Porous Carbon Synthesis For Capacitive Energy StorageLi, Jiaxin 08 August 2024 (has links)
Poröse Kohlenstoffe sind aufgrund ihrer großen Oberfläche, ihrer anpassbaren Porengröße und -zusammensetzung, ihrer guten Leitfähigkeit und Stabilität für die kapazitive Energiespeicherung unverzichtbar. Die effiziente Synthese von porösen Kohlenstoffen mit großer Oberfläche und hoher Ausbeute ist für Anwendungen im großen Maßstab von entscheidender Bedeutung. Herkömmliche Aktivierung und Templatisierung sind aufgrund aggressiver Chemikalien und komplexer Prozesse unbefriedigend. Die Selbsttemplatisierung durch direkte Pyrolyse metallischer organischer Salze bietet eine vielversprechende Alternative, führt jedoch zu geringen Ausbeuten (< 4 %) und begrenzten Oberflächen (< 2000 m²/g).
Diese Arbeit untersucht Cäsiumsalze von Carbonsäuren als selbsttemplatierende Vorläufer, um sowohl Ausbeute als auch Oberfläche von porösen Kohlenstoffen zu erhöhen. Die Verwendung von Cäsiumacetat als einzigem Vorläufer führt zu porösen Kohlenstoffen mit großen Oberflächen von bis zu 3000 m²/g und Porenvolumen von bis zu 2 cm³/g. Cäsiummaleate erhöhen die Ausbeute weiter auf 25 %, während Oberflächen von etwa 3000 m²/g erhalten bleiben. Die Interkalation von Cäsiumionen ist der primäre Aktivierungsmechanismus. Durch Anpassen des Massenverhältnisses von Harnsäure zu Cäsiumacetat entstehen poröse Kohlenstoffe mit unterschiedlichen Porengrößen, wobei Zusammensetzung und Oberfläche ähnlich bleiben. Diese porösen Kohlenstoffe weisen eine hohe Kapazität und Zyklenstabilität in Superkondensatoren, Zn-Ionen- oder Na-Ionen-Kondensatoren auf. Supermikroporen sind für eine hohe Kapazität entscheidend, während Mesoporen die Ratenleistung und Zyklenstabilität verbessern. Insgesamt zeigt diese Arbeit, wie Cäsium die Kohlenstoffwissenschaft revolutioniert hat, indem es einen einfachen Syntheseprozess, niedrigere Temperaturen, große Oberflächen und anpassbare Porositäten bietet. / Porous carbons are essential for capacitive energy storage due to their large surface area, tunable pore size and composition, good conductivity, and stability. Efficient synthesis of high surface-area porous carbons with high yield is crucial for large-scale applications. Traditional activation and templating are unsatisfactory due to harsh chemicals and complex processes. Self-templating via direct pyrolysis of metallic organic salts offers a promising alternative, but results in low yields (< 4%) and limited surface areas (< 2000 m²/g).
This thesis explores cesium salts of carboxylic acids as self-templating precursors to enhance both yield and surface area of porous carbons. Using cesium acetate as the sole precursor results in porous carbons with high surface areas up to 3000 m²/g and pore volume up to 2 cm³/g. Cesium maleates further increase yields to 25% while maintaining surface areas around 3000 m²/g. Cesium ion intercalation is the primary activation mechanism. Adjusting the mass ratio of uric acid to cesium acetate yields porous carbons with varying pore sizes, maintaining similar compositions and surface areas. These porous carbons exhibit high capacity and cycling stability in supercapacitor, Zn-ion, or Na-ion capacitors. Supermicropores are crucial for high capacity, while mesopores improve rate performance and cycling stability. Overall, this thesis shows how cesium revolutionize carbon science, offering a facile synthesis process, lower temperatures, large surface areas, and tunable porosities.
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Gels poreux biosourcés : production, caractérisation et applications / Biosourced porous gels : production, characterisation and applicationsAmaral-Labat, Gisèle 08 July 2013 (has links)
Ce travail de recherche présente la préparation et la caractérisation de matériaux monolithiques hautement poreux dérivés majoritairement de ressources naturelles. L'objectif était de préparer de nouveaux gels biosourcés jusqu'à 91%, de proposer des alternatives au séchage supercritique au CO2, et d'étudier quelques propriétés d'intérêt de tels gels après séchage, non seulement à l'état organique mais, dans certains cas, après pyrolyse pour obtenir des gels de carbone. A ces fins, le tannin et le soja ont été testés comme précurseurs, à différentes concentrations et différents pH, et trois voies de séchages ont été utilisées : supercritique, lyophilisation et séchage évaporatif. Les gels obtenus ont été caractérisés en termes de densité, porosité, distributions de tailles de pores et surfaces spécifiques, qu'ils soient sous forme organique ou carbonée selon l'application envisagée ou le type de porosité attendue. Leurs propriétés mécaniques et thermiques ont aussi été mesurées. La très large gamme de textures poreuses obtenues a permis de proposer des applications en tant qu'isolants thermiques, supports de catalyseur, ou électrodes de condensateur électrochimiques, selon les cas / This manuscript presents the preparation and the characterization of highly porous monolithic materials mainly derived from natural resources. The objectives were to: (i) develop new gels, biosourced up to the 91% level; (ii) suggest alternatives to supercritical drying in CO2, and (iii) investigate properties of interest for such gels in the organic state and, in some cases, after pyrolysis for obtaining carbon gels. For those purposes, tannin and soy flour were tested as precursors, at different concentrations and different pH, and three ways of drying were used: supercritical drying, freeze drying and evaporative drying. The obtained gels were characterized in terms of density, porosity, pore size distributions and specific surface area, whether in organic or in carbon form, depending on the intended application or expected type of porosity. Mechanical and thermal properties were also measured. The obtained broad range of porous textures allowed suggesting applications such as thermal insulators, catalyst supports or electrodes for electrochemical capacitors
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Nitrogen-enriched, ordered mesoporous carbons for potential electrochemical energy storageZhu, Jinhui, Yang, Jun, Miao, Rongrong, Zhaoquan, Zhaoquan, Zhuang, Xiaodong, Feng, Xinliang 17 July 2017 (has links)
Nitrogen-doped (N-doped) porous carbons have drawn increasing attention due to their high activity for electrochemical catalysis, and high capacity for lithium-ion (Li-ion) batteries and supercapacitors. So far, the controlled synthesis of N-enriched ordered mesoporous carbons (N-OMCs) for Li-ion batteries is rarely reported due to the lack of a reliable nitrogen-doping protocol that maintains the ordered mesoporous structure. In order to realize this, in this work, ordered mesoporous carbons with controllable N contents were successfully prepared by using melamine, F127 and phenolic resin as the N-source, template and carbon-source respectively via a solvent-free ball-milling method. The as-prepared N-OMCs which showed a high N content up to 31.7 wt% were used as anodes for Li-ion batteries. Remarkably, the N-OMCs with an N content of 24.4 wt% exhibit the highest reversible capacity (506 mA h g−1) even after 300 cycles at 300 mA g−1 and a capacity retention of 103.3%. N-OMCs were also used as electrode materials in supercapacitors and a capacity of 150 F g−1 at 0.2 A g−1 with stable cycling up to 2500 times at 1 A g−1 was achieved. These attractive results encourage the design and synthesis of high heteroatom content ordered porous carbons for applications in the field of energy storage and conversion.
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Tailoring Pore Size and Polarity for Liquid Phase Adsorption by Porous CarbonsHippauf, Felix 28 March 2017 (has links)
Adsorption is a versatile purification technique to selectively separate different peptide fractions from a mixture using mild operation conditions. Porous carbons are ideally suited to separate ACE-inhibiting dipeptides by combining tailored size exclusion and polarity selectivity. The desired peptide fraction is mostly hydrophobic and very small and should adsorb inside hydrophobic micropores.
The second topic of this thesis is linked to energy storage. The lithium-sulfur battery is a promising alternative to common lithium-ion batteries with theoretical capacities of up to 1672 mAh g−1 sulfur. The second aim of this thesis is to conduct an in-depth investigation of polysulfides interacting with selected carbon materials in a simplified battery electrolyte environment. The focus of this study is laid on the impact of surface polarity and pore size distribution of the carbon to develop a quantitative correlation between polysulfide retention and porosity metrics.
Both, the enrichment of ACE-inhibitors and the retention of polysulfides rely on liquid phase adsorption in porous materials, linking the above mentioned topics. This thesis not only aims to develop an enrichment process or to find a superior battery cathode but also strives to explore structure-property relationships that are universally valid. Understanding the complex interplay of pore size and polarity leading to selective interactions between pore wall and the adsorbed species is given a high priority.
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