TY - JOUR A1 - Hwang, Jongkook A1 - Walczak, Ralf A1 - Oschatz, Martin A1 - Tarakina, Nadezda A1 - Schmidt, Bernhard V. K. J. T1 - Micro-Blooming: Hierarchically Porous Nitrogen-Doped Carbon Flowers Derived from Metal-Organic Mesocrystals JF - Small N2 - Synthesis of 3D flower-like zinc-nitrilotriacetic acid (ZnNTA) mesocrystals and their conformal transformation to hierarchically porous N-doped carbon superstructures is reported. During the solvothermal reaction, 2D nanosheet primary building blocks undergo oriented attachment and mesoscale assembly forming stacked layers. The secondary nucleation and growth preferentially occurs at the edges and defects of the layers, leading to formation of 3D flower-like mesocrystals comprised of interconnected 2D micropetals. By simply varying the pyrolysis temperature (550-1000 degrees C) and the removal method of in the situ-generated Zn species, nonporous parent mesocrystals are transformed to hierarchically porous carbon flowers with controllable surface area (970-1605 m(2) g(-1)), nitrogen content (3.4-14.1 at%), pore volume (0.95-2.19 cm(3) g(-1)), as well as pore diameter and structures. The carbon flowers prepared at 550 degrees C show high CO2/N-2 selectivity due to the high nitrogen content and the large fraction of (ultra)micropores, which can greatly increase the CO2 affinity. The results show that the physicochemical properties of carbons are highly dependent on the thermal transformation and associated pore formation process, rather than directly inherited from parent precursors. The present strategy demonstrates metal-organic mesocrystals as a facile and versatile means toward 3D hierarchical carbon superstructures that are attractive for a number of potential applications. KW - 3D flower superstructures KW - hierarchically porous carbon KW - metal-organic mesocrystals KW - thermal transformation mechanism Y1 - 2019 U6 - https://doi.org/10.1002/smll.201901986 SN - 1613-6810 SN - 1613-6829 VL - 15 IS - 37 PB - Wiley-VCH CY - Weinheim ER - TY - JOUR A1 - Qin, Qing A1 - Zhao, Yun A1 - Schmallegger, Max A1 - Heil, Tobias A1 - Schmidt, Johannes A1 - Walczak, Ralf A1 - Gescheidt-Demner, Georg A1 - Jiao, Haijun A1 - Oschatz, Martin T1 - Enhanced Electrocatalytic N-2 Reduction via Partial Anion Substitution in Titanium Oxide-Carbon Composites JF - Angewandte Chemie : a journal of the Gesellschaft Deutscher Chemiker ; International edition N2 - The electrochemical conversion of N-2 at ambient conditions using renewably generated electricity is an attractive approach for sustainable ammonia (NH3) production. Considering the chemical inertness of N-2, rational design of efficient and stable catalysts is required. Therefore, in this work, it is demonstrated that a C-doped TiO2/C (C-TixOy/C) material derived from the metal-organic framework (MOF) MIL-125(Ti) can achieve a high Faradaic efficiency (FE) of 17.8 %, which even surpasses most of the established noble metal-based catalysts. On the basis of the experimental results and theoretical calculations, the remarkable properties of the catalysts can be attributed to the doping of carbon atoms into oxygen vacancies (OVs) and the formation of Ti-C bonds in C-TixOy. This binding motive is found to be energetically more favorable for N-2 activation compared to the non-substituted OVs in TiO2. This work elucidates that electrochemical N-2 reduction reaction (NRR) performance can be largely improved by creating catalytically active centers through rational substitution of anions into metal oxides. KW - ammonia synthesis KW - anion substitution KW - MOF-derived catalysts KW - N-2 fixation KW - non-noble metal catalysts Y1 - 2019 U6 - https://doi.org/10.1002/anie.201906056 SN - 1433-7851 SN - 1521-3773 VL - 58 IS - 37 SP - 13101 EP - 13106 PB - Wiley-VCH CY - Weinheim ER - TY - JOUR A1 - Yan, Runyu A1 - Josef, Elinor A1 - Huang, Haijian A1 - Leus, Karen A1 - Niederberger, Markus A1 - Hofmann, Jan P. A1 - Walczak, Ralf A1 - Antonietti, Markus A1 - Oschatz, Martin T1 - Understanding the charge storage mechanism to achieve high capacity and fast ion storage in sodium-ion capacitor anodes by using electrospun nitrogen-doped carbon fibers JF - Advanced functional materials N2 - Microporous nitrogen-rich carbon fibers (HAT-CNFs) are produced by electrospinning a mixture of hexaazatriphenylene-hexacarbonitrile (HAT-CN) and polyvinylpyrrolidone and subsequent thermal condensation. Bonding motives, electronic structure, content of nitrogen heteroatoms, porosity, and degree of carbon stacking can be controlled by the condensation temperature due to the use of the HAT-CN with predefined nitrogen binding motives. The HAT-CNFs show remarkable reversible capacities (395 mAh g(-1) at 0.1 A g(-1)) and rate capabilities (106 mAh g(-1) at 10 A g(-1)) as an anode material for sodium storage, resulting from the abundant heteroatoms, enhanced electrical conductivity, and rapid charge carrier transport in the nanoporous structure of the 1D fibers. HAT-CNFs also serve as a series of model compounds for the investigation of the contribution of sodium storage by intercalation and reversible binding on nitrogen sites at different rates. There is an increasing contribution of intercalation to the charge storage with increasing condensation temperature which becomes less active at high rates. A hybrid sodium-ion capacitor full cell combining HAT-CNF as the anode and salt-templated porous carbon as the cathode provides remarkable performance in the voltage range of 0.5-4.0 V (95 Wh kg(-1) at 0.19 kW kg(-1) and 18 Wh kg(-1) at 13 kW kg(-1)). KW - carbon fibers KW - nitrogen-doped carbon KW - sodium-ion capacitors KW - sodium storage mechanism Y1 - 2019 U6 - https://doi.org/10.1002/adfm.201902858 SN - 1616-301X SN - 1616-3028 VL - 29 IS - 26 PB - Wiley-VCH CY - Weinheim ER - TY - THES A1 - Walczak, Ralf T1 - Molecular design of nitrogen-doped nanoporous noble carbon materials for gas adsorption T1 - Molekulares Design Stickstoffdotierter, Nanoporöser, und Edler Kohlenstoffmaterialien für Gasadsorption N2 - In den modernen Gesellschaften führt ein stetig steigender Energiebedarf zu dem zunehmenden Verbrauch fossiler Brennstoffe wie Kohle, Öl, und Gas. Die Verbrennung dieser kohlenstoffbasierten Brennstoffe führt unweigerlich zur Freisetzung von Treibhausgasen, vor allem von CO2. Die CO2 Aufnahme unmittelbar bei den Verbrennungsanlagen oder direkt aus der Luft, zusammen mit Regulierung von CO2 produzierenden Energiesektoren (z.B. Kühlanlagen), können den CO2 Ausstoß reduzieren. Allerdings führen insbesondere bei der CO2 Aufnahme die geringen CO2 Konzentrationen und die Aufnahme konkurrierender Gase zu niedrigen CO2 Kapazitäten und Selektivitäten. Das Zusammenspiel der Gastmoleküle mit porösen Materialien ist dabei essentiell. Poröse Kohlenstoffmaterialien besitzen attraktive Eigenschaften, unter anderem elektrische Leitfähigkeit, einstellbare Porosität, als auch chemische und thermische Stabilität. Allerdings führt die zu geringe Polarisierbarkeit dieser Materialien zu einer geringen Affinität zu polaren Molekülen (z.B. CO2, H2O, oder NH3). Diese Affinität kann durch den Einbau von Stickstoff erhöht werden. Solche Materialien sind oft „edler“ als reine Kohlenstoffe, dies bedeutet, dass sie eher oxidierend wirken, als selbst oxidiert zu werden. Die Problematik besteht darin, einen hohen und gleichmäßig verteilten Stickstoffgehalt in das Kohlenstoffgerüst einzubauen. Die Zielsetzung dieser Dissertation ist die Erforschung neuer Synthesewege für stickstoffdotierte edle Kohlenstoffmaterialien und die Entwicklung eines grundlegenden Verständnisses für deren Anwendung in Gasadsorption und elektrochemischer Energiespeicherung. Es wurde eine templatfreie Synthese für stickstoffreiche, edle, und mikroporöse Kohlenstoffmaterialien durch direkte Kondensation eines stickstoffreichen organischen Moleküls als Vorläufer erarbeitet. Dadurch konnten Materialien mit hohen Adsorptionskapazitäten für H2O und CO2 bei niedrigen Konzentrationen und moderate CO2/N2 Selektivitäten erzielt werden. Um die CO2/N2 Selektivitäten zu verbessern, wurden mittels der Einstellung des Kondensationsgrades die molekulare Struktur und Porosität der Kohlenstoffmaterialien kontrolliert. Diese Materialien besitzen die Eigenschaften eines molekularen Siebs für CO2 über N2, das zu herausragenden CO2/N2 Selektivitäten führt. Der ultrahydrophile Charakter der Porenoberflächen und die kleinen Mikroporen dieser Kohlenstoffmaterialien ermöglichen grundlegende Untersuchungen für die Wechselwirkungen mit Molekülen die polarer sind als CO2, nämlich H2O und NH3. Eine weitere Reihe stickstoffdotierter Kohlenstoffmaterialien wurde durch Kondensation eines konjugierten mikroporösen Polymers synthetisiert und deren strukturelle Besonderheiten als Anodenmaterial für die Natriumionen Batterie untersucht. Diese Dissertation leistet einen Beitrag zur Erforschung stickstoffdotierter Kohlenstoffmaterialien und deren Wechselwirkungen mit verschiedenen Gastmolekülen. N2 - The growing energy demand of the modern economies leads to the increased consumption of fossil fuels in form of coal, oil, and natural gases, as the mains sources. The combustion of these carbon-based fossil fuels is inevitably producing greenhouse gases, especially CO2. Approaches to tackle the CO2 problem are to capture it from the combustion sources or directly from air, as well as to avoid CO2 production in energy consuming sources (e.g., in the refrigeration sector). In the former, relatively low CO2 concentrations and competitive adsorption of other gases is often leading to low CO2 capacities and selectivities. In both approaches, the interaction of gas molecules with porous materials plays a key role. Porous carbon materials possess unique properties including electric conductivity, tunable porosity, as well as thermal and chemical stability. Nevertheless, pristine carbon materials offer weak polarity and thus low CO2 affinity. This can be overcome by nitrogen doping, which enhances the affinity of carbon materials towards acidic or polar guest molecules (e.g., CO2, H2O, or NH3). In contrast to heteroatom-free materials, such carbon materials are in most cases “noble”, that is, they oxidize other matter rather than being oxidized due to the very positive working potential of their electrons. The challenging task here is to achieve homogenous distribution of significant nitrogen content with similar bonding motives throughout the carbon framework and a uniform pore size/distribution to maximize host-guest interactions. The aim of this thesis is the development of novel synthesis pathways towards nitrogen-doped nanoporous noble carbon materials with precise design on a molecular level and understanding of their structure-related performance in energy and environmental applications, namely gas adsorption and electrochemical energy storage. A template-free synthesis approach towards nitrogen-doped noble microporous carbon materials with high pyrazinic nitrogen content and C2N-type stoichiometry was established via thermal condensation of a hexaazatriphenylene derivative. The materials exhibited high uptake of guest molecules, such as H2O and CO2 at low concentrations, as well as moderate CO2/N2 selectivities. In the following step, the CO2/N2 selectivity was enhanced towards molecular sieving of CO2 via kinetic size exclusion of N2. The precise control over the condensation degree, and thus, atomic construction and porosity of the resulting materials led to remarkable CO2/N2 selectivities, CO2 capacities, and heat of CO2 adsorption. The ultrahydrophilic nature of the pore walls and the narrow microporosity of these carbon materials served as ideal basis for the investigation of interface effects with more polar guest molecules than CO2, namely H2O and NH3. H2O vapor physisorption measurements, as well as NH3-temperature programmed desorption and thermal response measurements showed exceptionally high affinity towards H2O vapor and NH3 gas. Another series of nitrogen-doped carbon materials was synthesized by direct condensation of a pyrazine-fused conjugated microporous polymer and their structure-related performance in electrochemical energy storage, namely as anode materials for sodium-ion battery, was investigated. All in all, the findings in this thesis exemplify the value of molecularly designed nitrogen-doped carbon materials with remarkable heteroatom content implemented as well-defined structure motives. The simultaneous adjustment of the porosity renders these materials suitable candidates for fundamental studies about the interactions between nitrogen-doped carbon materials and different guest species. KW - carbon materials KW - nitrogen-doped KW - gas adsorption KW - porosity KW - Porösität KW - Gasadsorption KW - Stickstoffdotiert KW - Kohlenstoffmaterialien Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-435241 ER - TY - JOUR A1 - Walczak, Ralf A1 - Savateev, Aleksandr A1 - Heske, Julian A1 - Tarakina, Nadezda V. A1 - Sahoo, Sudhir A1 - Epping, Jan D. A1 - Kuehne, Thomas D. A1 - Kurpil, Bogdan A1 - Antonietti, Markus A1 - Oschatz, Martin T1 - Controlling the strength of interaction between carbon dioxide and nitrogen-rich carbon materials by molecular design JF - Sustainable energy & fuels N2 - Thermal treatment of hexaazatriphenylene-hexacarbonitrile (HAT-CN) in the temperature range from 500 degrees C to 700 degrees C leads to precise control over the degree of condensation, and thus atomic construction and porosity of the resulting C2N-type materials. Depending on the condensation temperature of HAT-CN, nitrogen contents of more than 30 at% can be reached. In general, these carbons show adsorption properties which are comparable to those known for zeolites but their pore size can be adjusted over a wider range. At condensation temperatures of 525 degrees C and below, the uptake of nitrogen gas remains negligible due to size exclusion, but the internal pores are large and polarizing enough that CO2 can still adsorb on part of the internal surface. This leads to surprisingly high CO2 adsorption capacities and isosteric heat of adsorption of up to 52 kJ mol(-1). Theoretical calculations show that this high binding enthalpy arises from collective stabilization effects from the nitrogen atoms in the C2N layers surrounding the carbon atom in the CO2 molecule and from the electron acceptor properties of the carbon atoms from C2N which are in close proximity to the oxygen atoms in CO2. A true CO2 molecular sieving effect is achieved for the first time in such a metal-free organic material with zeolite-like properties, showing an IAST CO2/N-2 selectivity of up to 121 at 298 K and a N-2/CO2 ratio of 90/10 without notable changes in the CO2 adsorption properities over 80 cycles. Y1 - 2019 U6 - https://doi.org/10.1039/c9se00486f SN - 2398-4902 VL - 3 IS - 10 SP - 2819 EP - 2827 PB - Royal Society of Chemistry CY - Cambridge ER -