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Effect of Acid Washing on the Oxygen Reduction Reaction Activity of Pt-Cu Aerogel CatalystsHenning, Sebastian, Kühn, Laura, Herranz, Juan, Nachtegaal, Maarten, Hübner, Rene, Werheid, Matthias, Eychmüller, Alexander, Schmidt, Thomas Justus 07 June 2018 (has links)
Developing highly active and durable oxygen reduction reaction (ORR) catalysts is crucial to reduce the cost of polymer electrolyte fuel cells (PEFCs). To meet those requirements, unsupported Pt-Cu alloy nanochains (aerogels) were synthesized by a simple co-reduction route in aqueous solution and their structure was characterized by X-ray absorption spectroscopy and STEM-EDX. These catalysts exceeded the ORR activity of commercial Pt/C catalysts by more than 100 % in RDE experiments and met the US DOE targets, thereby qualifying as very promising materials. The behavior of Pt-Cu aerogels under PEFC operation conditions was mimicked by acid washing experiments which showed that the Cu content in the alloy phase and ORR activity decrease through this step. Comparing composition, structure and ORR activity for various specimens, the Cu content in the alloy phase was identified as the main descriptor of ORR activity. An almost linear correlation was found between those two parameters and complemented by supporting data from the literature.
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3D Assembly of Colloidal Nanoparticles into Gels and Aerogels: Function-led DesignWen, Dan, Eychmüller, Alexander 25 September 2018 (has links)
Gels and aerogels derived from colloidal nanoparticles not only own the advantages of the traditional aerogels like ultra- low density, large surface area and high porosity, but also retain some of the unique properties of the nanoparticles. These characteristics endow such new types of materials with the possibility of promising applications. In this review, we focus on the function-led design of aerogels from the 3D assembly of 0D spherical particles, 1D nanowires, and 2D nanosheets, and especially their applications in catalysis, sensing, optoelectronics, pollutants adsorbent/filtration, and beyond.
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A fast route to modified tin oxide aerogels using hydroxostannate precursorsBeier, Max Gregor, Ziegler, Christoph, Wegner, Karl, Benad, Albrecht, Simon, Frank, Kaskel, Stefan, Eychmüller, Alexander 28 February 2019 (has links)
Nanostructured tin oxide materials with a high specific surface area and porosity are promising for applications such as electrocatalysis, lithium ion batteries or sensors. Here, we present a facile strategy for the synthesis of tin oxide aerogels using inexpensive hexahydroxostannate as tin precursor. This easy and scalable method yields tin oxide aerogels with a high specific surface area and wide pore size distribution. The method can be modified by adding hexahydroxoantimonate to obtain antimony doped tin oxide aerogels that show an electrical conductivity after annealing. A cogelation with other preformed nanoparticles (e.g. Au, Pt) leads to mixed gels. Both modifications do not have a large impact on the porous properties of the obtained aerogels. Tin oxide materials prepared via this route can be tailored to a specific application by versatile modification possibilities.
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Spectroscopic Characterization of Organic and Inorganic Macromolecular MaterialsReinsel, Anna Michele 10 August 2011 (has links)
No description available.
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CELLULOSE NANOCRYSTALS AND RELATED POLYMER NANOCOMPOSITESCudjoe, Elvis 06 September 2017 (has links)
No description available.
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BUILDING BLOCKS AND THEIR EFFECTS ON POLYMER AEROGEL PROPERTIESGu, Senlong 04 October 2016 (has links)
No description available.
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Structural investigations of Au–Ni aerogels: morphology and element distributionKresse, Johannes, Georgi, Maximilian, Hübner, René, Eychmüller, Alexander 07 November 2024 (has links)
The physical properties of nanomaterials are determined by their structural features, making accurate structural control indispensable. This carries over to future applications. In the case of metal aerogels, highly porous networks of aggregated metal nanoparticles, such precise tuning is still largely pending. Although recent improvements in controlling synthesis parameters like electrolytes, reductants, or mechanical stirring, the focus has always been on one particular morphology at a time. Meanwhile, complex factors, such as morphology and element distributions, are studied rather sparsely. We demonstrate the capabilities of precise morphology design by deploying Au–Ni, a novel element combination for metal aerogels in itself, as a model system to combine common aerogel morphologies under one system for the first time. Au–Ni aerogels were synthesized via modified one- and two-step gelation, partially combined with galvanic replacement, to obtain aerogels with alloyed, heterostructural (novel metal aerogel structure of interconnected nanoparticles and nanochains), and hollow spherical building blocks. These differences in morphology are directly reflected in the physisorption behavior, linking the isotherm shape and pore size distribution to the structural features of the aerogels, including a broad-ranging specific surface area (35–65 m² g⁻¹). The aerogels were optimized regarding metal concentration, destabilization, and composition, revealing some delicate structural trends regarding the ligament size and hollow sphere character. Hence, this work significantly improves the structural tailoring of metal aerogels and possible up-scaling. Lastly, preliminary ethanol oxidation tests demonstrated that morphology design extends to the catalytic performance. All in all, this work emphasizes the strengths of morphology design to obtain optimal structures, properties, and (performances) for any material application.
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Partículas e Aerogéis nanoestruturados de SiO2/TiO2 e SiO2/TiO2-Azul da Prússia para aplicação em fotocatálise heterogênea / SiO2/TiO2 and SiO2/TiO2-Prussian Blue nanostructured particles and aerogels for application in heterogeneous photocatalysisFerreira Neto, Elias Paiva 21 May 2018 (has links)
Apesar de a fotocatálise heterogênea ser reconhecida como uma abordagem promissora e sustentável para promover processos de remediação ambiental, aplicações práticas de processos fotocatalíticos ainda são muito limitadas devido à baixa eficiência dos fotocatalisadores existentes. Neste contexto, a pesquisa na interface Química/Ciência dos Materiais é de grande relevância para o desenvolvimento de rotas sintéticas que permitam a obtenção e o controle das propriedades de novos fotocatalisadores multi-componentes visando desempenho fotocatalítico aprimorado. Os trabalhos descritos nesta tese abordam rotas sintéticas desenvolvidas ou aprimoradas para preparação de partículas e aerogéis nanoestruturados baseados na incorporação do fotocatalisador de alta atividade TiO2 em escala nanométrica junto à estruturas de sílica, que atuam como suporte estrutural de alta estabilidade térmica. Adicionalmente, os materiais sintetizados foram modificados com o hexacianometalato Fe4[Fe(CN)6]3, o Azul da Prússia (PB) como tentativa para aumento do desempenho fotocatalítico em reações de redução. A caracterização detalhada dos materiais foi realizada por amplo conjunto de técnicas visando correlacionar atividade fotocatalítica com propriedades físicas e estruturais. Na primeira etapa do trabalho partículas core-shell SiO2@TiO2 foram preparadas pela adsorção e hidrólise controlada do precursor Isopropóxido de Titânio na superfície de partículas submicrométricas de sílica. Variando a composição do solvente (razão isopropanol/etanol) foi possível controlar a cinética de deposição do TiO2, levando à controle sobre composição e morfologia das partículas SiO2@TiO2 sintetizadas. Este material apresentou eficiência de fotodegradação do corante Cristal Violeta superior a do TiO2 não-suportado, assim como elevada estabilidade térmica devido à formação de ligações interfaciais Si-O-Ti. Em uma segunda etapa, novas rotas de preparação de aerogéis de sílica-titânia foram desenvolvidas empregando TiCl4 como precursor alternativo aos alcóxidos de titânio e processamento dos materiais por secagem em CO2 supercrítico. Explorou-se a reação de termo-hidrólise do TiCl4 para promover a deposição termo-induzida de titania em géis monolíticos de sílica, bem como o método de gelificação assistida por epóxido para formação de rede tridimensional porosa de titânia ao redor de partículas de aerogel de sílica, levando à preparação de aerogéis core-shell SiO2@TiO2 e aerogéis nanocompósitos SiO2/TiO2, respectivamente. A estrutura mesoporosa robusta dos aerogéis e a capacidade da sílica de inibir a transformação de fase anatase-rutilo se refletiram em um aumento de atividade fotocatalítica com o aumento da temperatura de calcinação, sendo que os aerogéis de sílica-titânia tratados a 1000ºC apresentaram eficiência fotocatalítica superiores a dos aerogéis de titânia pura e do fotocatalisador comercial P25. Na parte final do trabalho, as partículas e aerogéis de SiO2/TiO2 e TiO2 foram modificados adicionalmente com o PB e com PB/MoS2 por métodos de fotodeposição. Demonstrou-se que o PB pode atuar como co-catalisador na reação de redução fotocatalítica de espécie altamente tóxicas de Cr(VI) em compostos não tóxicos de Cr(III), aumentando substancialmente a eficiência dos materiais baseados em TiO2 sobre radiação UV. Finalmente, a modificação concomitante dos fotocatalisadores com PB e o semicondutor MoS2 levam a aumento sinérgico de atividade redução fotocatalítica de Cr(VI) também sob luz visível. Os materiais desenvolvidos neste trabalho apresentam interessante potencial para aplicações em processos de remediação ambiental e desenvolvimento de revestimentos cerâmicos auto-limpantes. / Despite its potential as a promising and sustainable approach for environmental remediation, heterogeneous photocatalysis still has limited practical applicability due to the low efficiency of the existing photocatalysts. In this context, research on the Chemistry/Materials Science interface is of utmost importance for the development of synthetic routes that allow preparation of novel multi-component photocatalysts with controlled properties and enhanced photocatalytic performance. The studies reported in this thesis describe newly developed or improved synthetic routes for the preparation of nanostructured photocatalysts in the form of particles and aerogels through incorporation of highly photoactive TiO2 nanoparticles in silica materials as thermally stable structural supports. Additionally, the prepared silica-titania photocatalysts were further modified with Prussian Blue (PB), hexacyanometallate Fe4[Fe(CN)6]3, in order to enhance the efficiency of photocatalytic reduction reactions. In order to correlate the observed photocatalytic performance with the physical/structural properties of the photocatalysts, the prepared photocatalysts were characterized using an array of complimentary techniques. In the first part of the study, core-shell SiO2@TiO2 particles were prepared by the adsorption and controlled hydrolysis of titanium isopropoxide precursor on the surface of submicron silica particles. The rate of titania deposition and the resultant particle morphology as well as TiO2 loading could be effectively controlled by changing solvent composition (isopropanol/ethanol ratio). The prepared SiO2@TiO2 core-shell particles showed superior performance for crystal violet dye photodegradation as compared to unsupported TiO2, in addition to their improved thermal stability due to the formation of Si-O-Ti interfacial bonds. In the second part of thesis, new synthetic routes were developed for the preparation of high surface area silica-titania aerogels employing TiCl4 as an alternative titania precursor. We explored the thermohydrolysis of TiCl4 to promote thermo-induced deposition of titania on silica monolithic gels and epoxide-assisted gelation method for formation of titania gel network around silica aerogel particles, thus yielding SiO2@TiO2 core-shell and SiO2/TiO2 composite aerogels, respectively. The prepared silica-titania aerogels displayed remarkable physical properties, including high surface area, large pore volume and outstanding thermal stability of the supported anatase nanoparticles. The robust thermally stable mesoporous structure of the prepared aerogels, coupled with the ability of silica to inhibit anatase-to-rutile transformation, led to the enhancement of photocatalytic activity with an increase in annealing temperature to as high as 1000 ºC. In fact, the photocatalytic activity of silica-titania aerogels annealed at 1000 ºC outperforms that of both pristine titania aerogels and Degussa P25 commercial photocatalyst. In the final part of the study, the prepared TiO2-based particles and aerogels were further modified with PB and PB/MoS2 by photodeposition method. We could demonstrate that PB can act as an efficient co-catalyst for the photocatalytic reduction of highly toxic Cr(VI) species to the non-toxic Cr(III), thus largely improving the photocatalytic performance of TiO2-based photocatalysts under UV illumination. Finally, simultaneous modification of the titania-based photocatalysts with both PB and the visible-light active semiconductor MoS2 lead to a synergistic enhancement of photocatalytic reduction of Cr(VI) under visible-light as well. The photocatalytic materials developed in this study may find useful application in many areas such as environmental remediation, wastewater purification and the development of self-cleaning ceramic coatings.
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Functional nanostructured hydrothermal carbons for sustainable technologies : heteroatom doping and superheated vaporWohlgemuth, Stephanie-Angelika January 2012 (has links)
The underlying motivation for the work carried out for this thesis was the growing need for more sustainable technologies. The aim was to synthesize a “palette” of functional nanomaterials using the established technique of hydrothermal carbonization (HTC). The incredible diversity of HTC was demonstrated together with small but steady advances in how HTC can be manipulated to tailor material properties for specific applications. Two main strategies were used to modify the materials obtained by HTC of glucose, a model precursor representing biomass.
The first approach was the introduction of heteroatoms, or “doping” of the carbon framework. Sulfur was for the first time introduced as a dopant in hydrothermal carbon. The synthesis of sulfur and sulfur/nitrogen doped microspheres was presented whereby it was shown that the binding state of sulfur could be influenced by varying the type of sulfur source. Pyrolysis may additionally be used to tune the heteroatom binding states which move to more stable motifs with increasing pyrolysis temperature. Importantly, the presence of aromatic binding states in the as synthesized hydrothermal carbon allows for higher heteroatom retention levels after pyrolysis and hence more efficient use of dopant sources. In this regard, HTC may be considered as an “intermediate” step in the formation of conductive heteroatom doped carbon. To assess the novel hydrothermal carbons in terms of their potential for electrochemical applications, materials with defined nano-architectures and high surface areas were synthesized via templated, as well as template-free routes. Sulfur and/or nitrogen doped carbon hollow spheres (CHS) were synthesized using a polystyrene hard templating approach and doped carbon aerogels (CA) were synthesized using either the albumin directed or borax-mediated hydrothermal carbonization of glucose. Electrochemical testing showed that S/N dual doped CHS and aerogels derived via the albumin approach exhibited superior catalytic performance compared to solely nitrogen or sulfur doped counterparts in the oxygen reduction reaction (ORR) relevant to fuel cells. Using the borax mediated aerogel formation, nitrogen content and surface area could be tuned and a carbon aerogel was engineered to maximize electrochemical performance. The obtained sample exhibited drastically improved current densities compared to a platinum catalyst (but lower onset potential), as well as excellent long term stability.
In the second approach HTC was carried out at elevated temperatures (550 °C) and pressure (50 bar), corresponding to the superheated vapor regime (htHTC). It was demonstrated that the carbon materials obtained via htHTC are distinct from those obtained via ltHTC and subsequent pyrolysis at 550 °C. No difference in htHTC-derived material properties could be observed between pentoses and hexoses. The material obtained from a polysaccharide exhibited a slightly lower degree of carbonization but was otherwise similar to the monosaccharide derived samples. It was shown that in addition to thermally induced carbonization at 550 °C, the SHV environment exhibits a catalytic effect on the carbonization process. The resulting materials are chemically inert (i.e. they contain a negligible amount of reactive functional groups) and possess low surface area and electronic conductivity which distinguishes them from carbon obtained from pyrolysis. Compared to the materials presented in the previous chapters on chemical modifications of hydrothermal carbon, this makes them ill-suited candidates for electronic applications like lithium ion batteries or electrocatalysts. However, htHTC derived materials could be interesting for applications that require chemical inertness but do not require specific electronic properties. The final section of this thesis therefore revisited the latex hard templating approach to synthesize carbon hollow spheres using htHTC. However, by using htHTC it was possible to carry out template removal in situ because the second heating step at 550 °C was above the polystyrene latex decomposition temperature. Preliminary tests showed that the CHS could be dispersed in an aqueous polystyrene latex without monomer penetrating into the hollow sphere voids. This leaves the stagnant air inside the CHS intact which in turn is promising for their application in heat and sound insulating coatings.
Overall the work carried out in this thesis represents a noteworthy development in demonstrating the great potential of sustainable carbon materials. / Das Ziel der vorgelegten Arbeit war es, mit Hilfe der Hydrothermalen Carbonisierung (HTC) eine Palette an verschiedenen Materialien herzustellen, deren physikalische und chemische Eigenschaften auf spezifische Anwendungen zugeschnitten werden können. Die Motivation hierfür stellt die Notwendigkeit, Alternativen zu Materialien zu finden, die auf fossilen Brennstoffen basieren. Dabei stellen vor allem nachhaltige Energien eine der größten Herausforderungen der Zukunft dar. HTC ist ein mildes, nachhaltiges Syntheseverfahren welches prinzipiell die Nutzung von biologischen Rohstoffen (z. B. landwirtschaftlichen Abfallprodukten) für die Herstellung von wertvollen, Kohlenstoff-basierten Materialien erlaubt. Es wurden zwei verschiedene Ansätze verwendet, um hydrothermalen Kohlenstoff zu modifizieren.
Zum einen wurde HTC unter „normalen“ Bedingungen ausgeführt, d. h. bei 180 °C und einem Druck von etwa 10 bar. Der Zucker Glukose diente in allen Fällen als Kohlenstoff Vorläufer. Durch Zugabe von stickstoff und /oder schwefelhaltigen Additiven konnte dotierte Hydrothermalkohle hergestellt werden. Dotierte Kohlenstoffe sind bereits für ihre positiven Eigenschaften, wie verbesserte Leitfähigkeit oder erhöhte Stabilität, bekannt. Zusätzlich zu Stickstoff dotierter Hydrothermalkohle, die bereits von anderen Gruppen hergestellt werden konnte, wurde in dieser Arbeit zum ersten Mal Schwefel in Hydrothermalkohle eingebaut. Außerdem wurden verschiedene Ansätze verwendet, um Oberfläche und definierte Morphologie der dotierten Materialien zu erzeugen, welche wichtig für elektrochemische Anwendungen sind. Schwefel- und/oder stickstoffdotierte Kohlenstoff Nanohohlkugeln sowie Kohlenstoff Aerogele konnten hergestellt werden. Mit Hilfe von einem zusätzlichen Pyrolyseschritt (d. h. Erhitzen unter Schutzgas) konnte die Leitfähigkeit der Materialien hergestellt werden, die daraufhin als Nichtmetall-Katalysatoren für Wasserstoff-Brennstoffzellen getestet wurden.
Im zweiten Ansatz wurde HTC unter extremen Bedingungen ausgeführt, d. h. bei 550 °C und einem Druck von ca. 50 bar, welches im Wasser Phasendiagram dem Bereich des Heißdampfes entspricht. Es konnte gezeigt werden, dass die so erhaltene Hydrothermalkohle ungewöhnliche Eigenschaften besitzt. So hat die Hochtemperatur-Hydrothermalkohle zwar einen hohen Kohlenstoffgehalt (mehr als 90 Massenprozent), enthält aber auch viele Wasserstoffatome und ist dadurch schlecht leitfähig. Da damit elektrochemische Anwendungen so gut wie ausgeschlossen sind, wurde die Hochtemperatur-Hydrothermalkohle für Anwendungen vorgesehen, welche chemische Stabilität aber keine Leitfähigkeit voraussetzen. So wurden beispielsweise Hochtemperatur-Kohlenstoff-Nanohohlkugeln synthetisiert, die großes Potential als schall- und wärmeisolierende Additive für Beschichtungen darstellen.
Insgesamt konnten erfolgreich verschiedenste Materialien mit Hilfe von HTC hergestellt werden. Es ist zu erwarten, dass sie in Zukunft zu nachhaltigen Technologien und damit zu einem weiteren Schritt weg von fossilen Brennstoffen beitragen werden.
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Darstellung von Edelmetallnanopartikeln und deren Überstrukturen / Synthesis of Noble Metal Nanoparticles and their SuperstructuresBigall, Nadja-Carola 19 February 2009 (has links) (PDF)
Zur Darstellung von Edelmetallnanopartikelüberstrukturen werden zunächst kolloidale Lösungen von Gold, Silber, Platin und Palladium synthetisiert. Dafür wird eine modifizierte Syntheseprozedur für Citrat stabilisierte Goldnanopartikel in wässriger Lösung unter Verwendung gleicher Konzentrationen auf die Systeme Silber, Platin und Palladium übertragen. Die Nanopartikellösungen werden mittels Absorptionsspektroskopie und Elektronenmikroskopie in mittlerer und hoher Auflösung charakterisiert. Die Platinnanopartikel werden verwendet, um mittels Keim vermitteltem Wachstum größere Platinnanopartikel darzustellen. Die resultierenden annähernd sphärischen Partikel haben eine sehr enge Größenverteilung mit einer Standardabweichung von drei bis sieben Prozent. Mit bis zu zwei Schritten des Keim vermittelten Wachstums können Partikel mit einem mittleren Durchmesser im Bereich von 10 bis 100 Nanometern hergestellt werden. Hochauflösende Elektronenmikroskopie zeigt, dass die Oberfläche der Partikel aus Platinkristalliten mit Durchmessern weniger Nanometer besteht, was zu einer Oberflächenrauhigkeit von drei bis zehn Nanometern führt. Mittels eines Kern-Schale-Modells werden Einzelteilchenextinktionsspektren berechnet, welche in sehr guter Übereinstimmung mit den experimentell bestimmten Extinktionsspektren des dispergierten Ensembles sind. Eine über weite Bereiche des sichtbaren Spektralbereichs lineare Abhängigkeit des Extinktionsmaximums vom Partikeldurchmesser wird beobachtet. Dadurch und zusammen mit der Einheitlichkeit der synthetisierten Platinsphären eröffnen sich Anwendungsmöglichkeiten im Bereich der Photonik, der Nanooptik und der oberflächenverstärkten Ramanspektroskopie. Geordnete Überstrukturen der Edelmetallnanopartikel können durch Infiltrieren von Templaten aus Block-Copolymer-Filmen mit wässriger Nanopartikellösung synthetisiert werden. In Abhängigkeit von der Vorbehandlung der Polymerfilme werden entweder zweidimensional periodische Anordnungen mit einer Periodizität von weniger als 30 Nanometern oder Fingerabdruck ähnliche Anordnungen mit einem Rillenabstand im selben Größenbereich hergestellt. Durch Entfernen des Polymers entstehen ein- bzw. zweidimensionale Anordnungen aus Platinnanodrähten bzw. -Nanopartikeln auf einem Siliziumwafer. Diese hochgeordneten Strukturen sind von fundamentalem Interesse für die Entwicklung von nanometerskaligen Schaltkreisen, Sensoren und als Substrate für die oberflächenverstärkte Ramanspektroskopie. Für die Herstellung ungeordneter Überstrukturen werden zwei unterschiedliche Ansätze gewählt: direkte Destabilisierung von Nanopartikellösungen, welche zu Hydrogelen und durch Trocknung zu Aerogelen führt, und Immobilisierung von Nanopartikeln auf einem in die Lösung implantierten Pilzmycel. Aus Gold-, Silber- und Platinnanopartikeln werden monometallische Hydro- und Aerogele synthetisiert. Unterschiedliche Destabilisierungsmittel sowie unterschiedliche Methoden zur Aufkonzentration der Nanopartikellösungen werden getestet. Abhängig von der Methode werden gelartige Überstrukturen mit teilweise komplexen Morphologien aus hierarchischen Anordnungen von Primär-, Sekundär-, Tertiärpartikeln beobachtet. Bimetallische Hydro- und Aerogele können aus Mischungen von Gold- oder Platin- mit Silbernanopartikellösungen hergestellt werden. Hochauflösende TEM-Aufnahmen zeigen ein polykristallines Netzwerk aus 2 bis 10 Nanometer dicken Drähten. Erste BET-Messungen zeigen, dass die Gold-Silber-Netzwerke eine Oberfläche von etwa 48 m2/g besitzen. Diese Systeme aus monometallischen und bimetallischen Nanopartikeln stellen erste Ansätze für hochporöse templatfreie Hydro- und Aerogele dar und besitzen großes Potential für den Einsatz in der heterogenen Gasphasenkatalyse, da fast die gesamte Oberfläche aus Übergangsmetall besteht. Es wird für eine Auswahl an unterschiedlichen Pilzen gezeigt, dass deren Wachstum direkt in den synthetisierten Nanopartikellösungen möglich ist. Ohne weitere Funktionalisierung findet eine Anlagerung von Nanopartikeln auf der Pilzoberfläche statt. Starke Variationen in den Affnitäten verschiedener Pilze zu den unterschiedlichen Metallnanopartikeln werden beobachtet. Auch werden Unterschiede der Nanopartikelaffnität mit Variation der Morphologie innerhalb desselben Hybridsystems beobachtet. Ein Platin-Pilz-Hybrid wird in wässriger Lösung erfolgreich als Katalysator einer Redoxreaktion getestet. Solche Hybridstrukturen besitzen ebenso wie die oben beschriebenen Aerogele großes Potential für den Einsatz in der heterogenen Katalyse, wobei die Verwendung von Pilzmycel als Trägermaterial eine kostengünstige Darstellung größerer Katalysatormengen ermöglichen könnte.
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