Μελέτη της ηλεκτροχημικής ενίσχυσης της αναγωγής του διοξειδίου του άνθρακα σε καταλύτη ρουθηνίου (Ru) υποστηριζόμενου σε πρωτονιακό αγωγό, ΒΖΥ / Study of the electrochemical promotion of CO2 reduction over ruthenium (Ru) catalyst supported on a proton conductor, BZY

Καλαϊτζίδου, Ιωάννα

27 April 2015

Η Υδρογόνωση του Διοξειδίου του Άνθρακα έχει προσελκύσει διεθνώς το ενδιαφέρον της επιστημονικής κοινότητας τόσο ως πιθανή πηγή ανανεώσιμων καυσίμων όσο και ως μέσο μείωσης των εκπομπών του CO2. Στην παρούσα μελέτη χρησιμοποιείται το φαινόμενο της Ηλεκτροχημικής Ενίσχυσης (Η/Ε) της κατάλυσης (EPOC) ή μη- Φαρανταϊκή Ηλεκτροχημική Τροποποίηση της καταλυτικής ενεργότητας (φαινόμενο NEMCA) για την ενίσχυση του ρυθμού και της εκλεκτικότητας της υδρογόνωσης του CO2 σε καταλύτη ρουθηνίου (Ru) υποστηριζόμενου σε πρωτονιακό αγωγό ΒZY. Αρχικά γίνεται μια Εισαγωγή για το Διοξείδιο του Άνθρακα στην οποία και εξηγείται η αναγκαιότητα της περεταίρω μελέτης της αντίδρασης υδρογόνωσης του CO2. Στο Κεφάλαιο 1 γίνεται μια εκτεταμένη αναφορά στους στερεούς ηλεκτρολύτες, με ιδιαίτερη έμφαση στους στερεούς ηλεκτρολύτες πρωτονιακής αγωγιμότητας. Στη συνέχεια στο δεύτερο Κεφάλαιο περιγράφεται το φαινόμενο της Ηλεκτροχημικής Ενίσχυσης της κατάλυσης, γίνεται μια αναφορά των μελετών Η/Ε που έχουν προηγηθεί και παρατίθενται οι κανόνες που διέπουν το συγκεκριμένο φαινόμενο. Στο τρίτο Κεφάλαιο γίνεται βιβλιογραφική ανασκόπηση της συγκεκριμένης αντίδρασης τόσο καταλυτικά όσο και ηλεκτροκαταλυτικά. Στο Κεφάλαιο 4 ακολουθεί η περιγραφή της πειραματικής διάταξης καθώς και ο χαρακτηρισμός του καταλύτη αλλά και τα πειράματα χαρακτηρισμού του ηλεκτρολύτη. Έπειτα, στο Κεφάλαιο 5 παρουσιάζονται τα πειραματικά αποτελέσματα (θερμοκρασιακά, κινητικά, δυναμικής απόκρισης κτλ.), καθώς και μια ποιοτική ανάλυση των παραπάνω αποτελεσμάτων. Και τέλος παρατίθενται τα συνολικά συμπεράσματα της συγκεκριμένης μελέτης. / The Hydrogenation of Carbon Dioxide has attracted international interest in the scientific community as a potential source of renewable fuels and as a means of reducing CO2 emissions. In this study the phenomenon of Electrochemical Promotion of Catalysis (EPOC) or non-Faradaic Electrochemical Modification of Catalytic Activity (NEMCA) is used in order to enhance the rate and selectivity of this reaction on a Ruthenium (Ru) catalyst deposited on a proton conductor (BZY). The electrochemical promotion of the hydrogenation of CO2 on polycrystalline Ru deposited on a BZY (BaZr0.85Y0.15O3 + 1wt% NiO), a proton conductor in wet atmospheres, was investigated at temperatures 250 to 450oC and atmospheric pressure. Methane and CO were the only detectable products. It was found that the selectivity to CH4 is very significantly enhanced by proton removal from the catalyst via electrochemically controlled spillover of atomic H from the catalyst surface to the proton-conducting support. The apparent Faradaic efficiency of the process takes values up to 500 and depends strongly on the porous Ru catalyst film thickness. The results strongly suggest that the observed strong promotional effect is due to the formation and surface migration of a promoting formate anion generated via potential controlled disproportionation of formic acid adsorbed at the catalyst-proton conducting support interface. This is the first successful electrochemical promotion study of a hydrogenation reaction at temperatures as low as 250oC. There is an up to fourfold enhancement in catalytic rate of CH4 formation with concomitant 50% suppression of the CO formation rate which proceeds in a parallel route.

Υδρογόνωση του CO2

Πρωτονιακός αγωγός

Φαινόμενο NEMCA

547.23

CO2 hydrogenation

Proton conductor

NEMCA

Sustainable, energy-efficient hydrogenation processes for selective chemical syntheses.

Yao, Libo

29 July 2021

No description available.

Chemical Engineering

Techno-economic feasibility study of a methanol plant using carbon dioxide and hydrogen

Nyari, Judit

January 2018

In 2015, more than 80% of energy consumption was based on fossil resources. Growing population especially in developing countries fuel the trend in global energy consumption. This constant increase however leads to climate change caused by anthropogenic greenhouse gas (GHG) emissions. GHG, especially CO2 mitigation is one of the top priority challenges in the EU. Amongst the solutions to mitigate future emissions, carbon capture and utilization (CCU) is gaining interest. CO2 is a valuable, abundant and renewable carbon source that can be converted into fuels and chemicals. Methanol (MeOH) is one of the chemicals that can be produced from CO2. It is considered a basic compound in chemical industry as it can be utilised in a versatility of processes. These arguments make methanol and its production from CO2 a current, intriguing topic in climate change mitigation. In this master’s thesis first the applications, production, global demand and market price of methanol were investigated. In the second part of the thesis, a methanol plant producing chemical grade methanol was simulated in Aspen Plus. The studied plants have three different annual capacities: 10 kt/a, 50 kt/a and 250 kt/a. They were compared with the option of buying the CO2 or capturing it directly from flue gases through a carbon capture (CC) unit attached to the methanol plant. The kinetic model considering both CO and CO2 as sources of carbon for methanol formation was described thoroughly, and the main considerations and parameters were introduced for the simulation. The simulation successfully achieved chemical grade methanol production, with a high overall CO2 conversion rate and close to stoichiometric raw material utilization. Heat exchanger network was optimized in Aspen Energy Analyzer which achieved a total of 75% heat duty saving. The estimated levelised cost of methanol (LCOMeOH) ranges between 1130 and 630 €/t which is significantly higher than the current listed market price for fossil methanol at 419 €/t. This high LCOMeOH is mostly due to the high production cost of hydrogen, which corresponds to 72% of LCOMeOH. It was revealed that selling the oxygen by-product from water electrolysis had the most significant effect, reducing the LCOMeOH to 475 €/t. Cost of electricity also has a significant influence on the LCOMeOH, and for a 10 €/MWh change the LCOMeOH changed by 110 €/t. Finally, the estimated LCOMeOH was least sensitive for the change in cost of CO2. When comparing owning a CC plant with purchasing CO2, it was revealed that purchasing option is only beneficial for smaller plants.

methanol

CCU

CO2 hydrogenation

simulation

Aspen

economics

levelised cost

Mechanical Engineering

Maskinteknik

Development of Dendritic Mesoporous Heterogeneous Catalysts for Efficient CO2 Hydrogenation to Methanol

Alabsi, Mohnnad H.

08 1900

In this research we investigated the generation of methanol and the utilization of CO2 using heterogeneous catalysts. Heterogeneous catalysts are frequently used in industry due to their multiple benefits, which include long-term thermal and mechanical stability, as well as reusability. Our research has demonstrated a variety of heterogeneous catalysts for sustainable methanol production and CO2 utilization, including the novel dendritic mesoporous metal oxides support. We have also designed and screened multiple active metals on the dendritic mesoporous metal oxide catalysts, modified active metal dispersion, and further reduced metal oxides to utilize silica-based catalysts, among other things. Comprehensive characterization of the final products was performed using N2 adsorption and desorption, XRD, HR-TEM, SEM, ICP-OES, XPS, H2-TPD, CO2-TPD, Raman spectroscopy, pulse-chemosorption and DRIFT, in order to determine the chemical and physical properties of the catalysts. The catalysts were found to have the following characteristics. We obtained a CO2 conversion of 25.5 % and a MeOH yield of 6.4 % after at least three cycles of usage in an avantium fixed bed reactor system with a PdCu/CZ-3 catalyst. Additionally, continuous methanol production with a higher yield (6.9 %) has been achieved using our PdZn/CZ-3 catalysts, and the best ultra-dispersed Pd nanoparticles over CZZ catalyst produces more than 12 % methanol yield with constant selectivity to methanol even after a lengthy catalytic test (more than 100 h), demonstrating their industrial viability. Additionally, our PdZn/CeTi-DMSN exhibits a high methanol production of up to 10% and better long-term stability with lower metal oxides content. The adsorption and activation of CO2 to react with the spilled over hydrogen to generate methanol has been researched for the CO2 hydrogenation and utilization reaction. Catalysts' redox, acidic, and basic characteristics all play a crucial part in this reaction and in the formation of the various products. With 2.0 percent Pd, the supported dendritic CeZrZn catalyst exhibits the highest catalytic performance (29.1% conversion and 40.6% MeOH selectivity). Comprehensive analysis revealed in this research not only identified effective catalysts with high activity for a variety of applications, but also established a link between catalytic performance and the material's nature. These discoveries may also aid the researcher in the near future in resolving global environmental problems.

Dendritic Mesoporous

Metal Oxides

Ultra-dispersion

Hydrogen dissociation

Oxygen vacancy

CO2 hydrogenation Methanol

Study of shape effect of Pd promoted Ga2O3 nanocatalysts for methanol synthesis and utilization

Zhou, Xiwen

January 2013

The area of methanol synthesis and utilization has been attracting research interests due to its positive impact on the environment and also from energy perspectives. Methanol synthesis from CO₂ hydrogenation not only produces methanol which is a key platform chemical and a clean fuel, but can also recycle CO₂ which is one of the major greenhouse gases causing global warming. As a mobile energy carrier (particularly as a hydrogen carrier), methanol is a versatile molecule which is able to generate H₂ via its decomposition. Catalysis plays a decisive role in the success of both methanol synthesis from CO₂ hydrogenation and its reverse decomposition reaction. Pd/Ga₂O₃ binary catalyst has recently been identified as an active catalyst for the methanol synthesis reaction. In this thesis, it is reported the shape effect of Pd promoted Ga₂O₃ for this reaction. The catalytic H₂ evolution from methanol photodecomposition has also been studied over these catalysts. Three shapes of Ga₂O</sub>3</sub> nanomaterials (i.e. rod and plate β-Ga₂O</sub>3</sub>, and particle γ-Ga₂O₃) have been synthesized, followed by doping with Pd metal to form corresponding Pd/Ga₂O₃ nanocatalysts. It was found that a (002) polar Ga2O3 surface which was dominantly presented on the plate form was unstable, giving a higher degree of oxygen defects and mobile electrons in the conduction band than the other non-polar (111) and (110) surfaces of the rod form. It was shown that a significantly stronger metal support interaction was found between the (002) polar Ga₂O₃ on the plate form and Pd, which gave higher methanol yield and selectivity. For methanol photodecomposition, it was found that, for pure Ga₂O₃ catalysts of different shapes, the plate form with a highest degree of defects (unstable polar surface) could encourage a non-radiative catalytic recombination of electron and hole pairs upon irradiation, hence giving a highest photocatalytic activity for H₂ production. Once Pd was introduced onto these oxide surfaces, it was noted that there was a fast and readily electron transfer from the conduction band of Ga₂O₃ to Pd due to the formation of a Schottky junction between the two materials. This produces metal sites for hydrogen production and further enhances the rate of the photocatalytic reaction over the radiative recombination of excitons. However, it was also found that at higher Pd content (>1%), the significantly shortened exciton lifetimes reduce the catalytic rate hence giving an overall volcanic response of activity to increasing Pd content for each shape of Ga₂O₃. At the higher Pd content, the plate form appeared to sustain a longer lifetime for photocatalysis compared to the other forms at the equivalent Pd loading.

541.395

Direct dimethyl ether synthesis from CO2/H2 / Synthèse directe de diméthyle éther à partir de CO2/H2

Jiang, Qian

28 February 2017

DME est un carburant propre qui contribue à diminuer les émissions de gaz à effet de serre; il est aussi une molécule plate-forme pour le stockage d'énergie. L'objectif de la thèse est le développement de matériaux catalytiques bifonctionnels pour la synthèse directe de DME à partir de CO2/H2 à partir de Cu/ZnO/ZrO2 comme le catalyseur de la synthèse de méthanol à partir de CO2/H2 et Al-TUD-1 comme le catalyseur de déshydratation du méthanol en DME. Dans cette thèse, Al-TUD-1 a été étudiée comme un catalyseur de la déshydratation du méthanol en DME pour la première fois. Son activité en déshydratation du méthanol en DME augmente avec la diminution du rapport Si/Al. Les catalyseurs bifonctionnels ont été préparés par un procédé de dépôt par co-précipitation. Le SMSI a été démontré et était bénéfique pour la dispersion de cuivre métallique, la surface de cuivre métallique augmente avec le rapport Si/Al. Dans le même temps, on a observé le blocage des sites acides d'Al-TUD-1 par le cuivre. Afin d'exposer les sites acides d'Al-TUD-1, la méthode de « core-shell » a été adoptée pour préparer le catalyseur bifonctionnel. Elle aide à libérer la fonction acide en empêchant son blocage par le cuivre. Cette méthode de synthèse a été bénéfique pour la stabilité des particules de cuivre métalliques, mais des faibles conversions de CO2/H2 ont été observées en raison de l'inaccessibilité du noyau. Un autre catalyseur bifonctionnel a été préparé par une méthode de mélange physique pour comparaison. L'optimisation du catalyseur bifonctionnel Cu/ZnO/ZrO2@Al-TUD-1 pour la synthèse directe de DME à partir de CO2/H2 a permis d'éclairer les principaux paramètres affectant le contact intime de deux fonctions catalytiques: surface et dispersion du cuivre, les propriétés acide et basic, la présence d'eau et l'accessibilité des sites actifs pour les réactifs. / DME is a clean fuel that helps to diminish the emissions of green house gases; it is as well a platform molecule for the energy storage. The objective of the thesis is the development of bifunctional catalytic materials for the direct DME synthesis from CO2/H2 based on Cu/ZnO/ZrO2 as the methanol synthesis from CO2/H2 catalyst and Al-TUD-1 as the methanol dehydration to DME catalyst. In this thesis, Al-TUD-1 was investigated as the methanol dehydration to DME catalyst for the first time. The methanol dehydration to DME performance increases with the decrease of Si/Al ratio. The bifunctional catalysts were prepared by co-precipitation deposition method. The SMSI was demonstrated and was beneficial for the metallic copper dispersion, the metallic copper surface area increases with the Si/Al ratio. In the same time the blockage of acid sites of Al-TUD-1 by copper was observed. In order to expose the acid sites of Al-TUD-1, the core shell method was adopted to prepare the bifunctional catalyst. It helps to free the acid function preventing its blockage by copper. This method of synthesis was beneficial for the stability of metallic copper particles, but performed low conversions of CO2/H2 due to the inaccessibility of the core. Another bifunctional catalyst was prepared by physically mixing method for comparison. The optimization of the bifunctional Cu/ZnO/ZrO2@Al-TUD-1 catalyst for the direct DME synthesis from CO2/H2 allowed enlightening the main parameters that affect the intimate contact of two catalytic functions: copper surface area and dispersion, acid and basic properties, water presence and the accessibility of the active sites for the reactants.

DME

Hydrogénation du CO2

Déshydratation du méthanol

Al-TUD-1

DME

CO2 hydrogenation

Methanol dehydration

Al-TUD-1

541.39

CO2-Hydrierung in Aminen

Frölich, Stefan

23 February 2021

Die Verringerung von CO2-Emissionen und die Schaffung eines Kohlenstoffkreislaufs sind Gegenstand vieler Forschungsarbeiten. Mittels Absorption wird CO2 in einem Lösungsmittel (vorrangig Alkoholamine) aus verschiedenen Gasmischungen abgetrennt und anschließend zu Wertstoffen umgesetzt. In der vorliegenden Arbeit war ein kombiniertes Verfahren aus CO2-Absorption und direktem Umsatz von CO2 zu Methanol im Amin zu untersuchen. Die Einsparung des Desorptionsschritts und die Möglichkeit zur Reduzierung der Reaktionstemperatur des exothermen Hydrierprozesses sind wesentliche Vorteile dieser Verfahrensweise. Um dieses Ziel zu erreichen, wurde die Performance verschiedener Amine untersucht und die Reaktionsparameter optimiert. Zur Verhinderung auftretender Nebenreaktionen fällt der Suche nach einem neuartigen Feststoffkatalysator besondere Bedeutung zu. Hierbei konnte ein Katalysatorsystem identifiziert werden, mit dessen Einsatz eine deutlich höhere Methanolausbeute als mit dem Standardkatalysator sowie eine Einschränkung der Nebenreaktionen erreicht wurde.

CO2, Hydrierung, Methanol, Katalyse

CO2, hydrogenation, methanol, catalysis

info:eu-repo/classification/ddc/540

ddc:540

Kohlendioxidemission

Amine

Absorption

Hydrierung

Methanolherstellung

Aktivitätsuntersuchungen und Charakterisierung von heterogenen Katalysatoren zur CO2-Hydrierung

Völs, Pit

29 August 2022

Im Rahmen dieser Dissertation wurden Hydrotalcit-basierte Nickelkatalysatoren zur CO2-Methanisierung synthetisiert, charakterisiert und katalytisch untersucht. Dabei konnten durch mehrere Ansätze deutliche Verbesserungen der katalytischen Aktivität erzielt werden. Einen wesentlichen Effekt zeigte dabei die Kombination der üblicherweise separat durchgeführten Präparationsschritte der Calcination und der Reduktion. Dadurch ließ sich die notwendige Reduktionstemperatur senken, was zum Erhalt einer größeren Katalysatoroberfläche führte. Zusätzlich wurde eine Vielzahl von Promotoren in Hydrotalcit-basierten Nickelkatalysatoren systematisch und vergleichend untersucht. Eine solche Untersuchung lässt sich in der Literatur bisher nicht finden. Dabei kristallisierte sich insbesondere Mangan als vielversprechender Promotor heraus. Spektroskopische Untersuchungen zum Einfluss des Mangans zeigten, dass Mangan die Bindungsstärke des Kohlenstoffdioxids am Katalysator erhöht. Durch Variation des Mangangehaltes ließ sich entsprechend die Bindungsstärke einstellen und somit die Katalysatoraktivität optimieren.

info:eu-repo/classification/ddc/540

ddc:540

Kohlendioxid

Hydrierung

Katalysator

Methan

Katalyse

Nickel

[pt] HIDROGENAÇÃO DE CO2 PARA METANOL: O PAPEL DAS VACÂNCIAS DE OXIGÊNIO NA SÍNTESE DE METANOL EMPREGANDO OS CATALISADORES DE CU/ZNO/AL E AS MISTURAS FÍSICAS A BASE DE IN2O3 / [en] HYDROGENATION OF CO2 TO METHANOL: THE ROLE OF OXYGEN VACANCIES IN METHANOL SYNTHESIS USING CU/ZNO/AL CATALYSTS AND IN2O3-BASED PHYSICAL MIXTURES

BRUNA JULIANA DA SILVA BRONSATO

04 January 2024

[pt] Esta tese investigou a síntese de metanol via hidrogenação do CO2 empregando dois conjuntos de catalisadores. O primeiro é composto pelos tradicionais catalisadores de Cu/ZnO/Al e o segundo aborda os catalisadores de In2O3 e ZrO2. Com relação ao Cu/ZnO/Al, foram preparados quatro amostras via coprecipitação. Os resultados mostraram que há um teor ótimo (3,8 por cento at.) de Al para a qual se observa uma maior taxa de formação de metanol. Os catalisadores foram caracterizados por fisissorção de N2, titulação com N2O,espectroscopia de absorção atômica, ICP, DRX, XPS, TPD-(CO2,NH3 e H2O), TPSR-CO2/H2, TEM/HRTEM/EDS. Uma correlação entre a taxa de formação de metanol e a quantidade de vacâncias de oxigênio superficiais do catalisador foi observada. Foi verificado que o Al atua como um promotor na geração de vacâncias de oxigênio. Com relação aos sistemas de In2O3, foi realizado um screening e selecionado nove catalisadores. Esses sólidos foram caracterizados pelas seguintes técnicas: DRX, TPD-NH3, TPD-CO2, TPR-H2 e TPSR-CO2/H2. Foi realizado um estudo em dinâmica molecular clássica investigando os efeitos da dopagem do In2O3 e da interação entre o In2O3 e o ZrO2 e relacionando os resultados com a performance dos catalisadores. O melhor desempenho catalítico foi obtido para o inédito catalisador de 0,6Pt-In2O3+6ZnZrO2, sendo esse desempenho associado à presença de vacâncias. Além disso, pelos cálculos teóricos de dinâmica molecular foi verificado que tanto a mistura física quanto a dopagem do In2O3 podem promovem a mobilidade de oxigênio da rede dos óxidos, o que facilita a formação de vacâncias de oxigênio. Sendo assim, os dois conjuntos de catalisadores estudados mostram que as vacâncias de oxigênio têm papel central na formação do metanol a partir da hidrogenação do CO2. As informações geradas neste trabalho contribuirão para o desenvolvimento de catalisadores promissores para a futura exploração industrial da geração de metanol a partir de CO2. / [en] This thesis investigated methanol synthesis via CO2 hydrogenation using two sets of catalysts. The first set consists of the traditional Cu/ZnO/Al catalysts and the second set involves In2O3 and ZrO2 catalysts. Concerning Cu/ZnO/Al, four samples were prepared via coprecipitation. The results showed that there is an optimum Al content (3.8 percent at.) for which a higher methanol formation rate is observed. The catalysts were characterized by N2 physisorption, titration with N2O, atomic absorption spectroscopy, ICP, XRD, XPS (CO2,NH3 and H2O)-TPD, CO2/H2-TPSR, TEM/HRTEM/EDS. A correlation was observed between the rate of methanol formation and the amount of surface oxygen vacancies on the catalyst. It was found that Al acts as a promoter in the generation of oxygen vacancies. Regarding the In2O3 systems, a screening was carried out and nine catalysts were selected. These solids were characterized using the following techniques: XRD, NH3- TPD, CO2-TPD, TPR-H2 and CO2/H2-TPSR. A classical molecular dynamics study was carried out investigating the effects of doping In2O3 and the interaction between In2O3 and ZrO2 and relating the results to the performance of the catalysts. The best catalytic performance was obtained for the new 0,6Pt-In2O3+6ZnZrO2 catalyst, and this performance was associated with the presence of vacancies. In addition, molecular dynamics calculations showed that both the physical mixture and the doping of In2O3 can promote the mobility of oxygen in the oxide lattice, facilitating the formation of oxygen vacancies. Thus, the two sets of catalysts studied show that oxygen vacancies play a central role in the formation of methanol from the hydrogenation of CO2. The information generated in this work will contribute to the development of promising catalysts for the future industrial exploitation of methanol generation from CO2.

[pt] CATALISE

[pt] IN2O3

[pt] CU ZNO AL

[pt] HIDROGENACAO DO CO2

[pt] VACANCIAS DE OXIGENIO

[en] CATALYSIS

[en] IN2O3

[en] CU ZNO AL

[en] CO2 HYDROGENATION

[en] OXYGEN VACANCIES

Untersuchungen zur katalytischen CO2-Hydrierung in Dreiphasensystemen

Lange, Christine Juliana Thoma

02 June 2023

Zur Entwicklung eines effizienten Verfahrens zur CO2-Hydierung im Dreiphasensystem erfolgten in dieser Arbeit Untersuchungen zur Optimierung des Katalysatorsystems, zum Screening nach neuen geeigneten Lösungsmitteln und zum Einfluss der Prozessführung. Durch Variieren des Trägersystems und der Präparationsmethode ergaben sich sieben Kupferkatalysatoren, welche sich in ihren Eigenschaften und ihrer katalytischen Aktivität unterschieden. Zudem gelang die Immobilisierung von Kupferkatalysatoren auf Aluminiumoxid und auf Glas. Es wurde eine kontinuierliche Anlage mit Rieselbettreaktor entwickelt und in Betrieb genommen, welche die Durchführung der CO2-Hydrierung in Gasphase und im Dreiphasensystem bei bis zu 90 bar ermöglicht. Im Batchversuch zeigte sich der Einfluss der Lösungsmittel auf die Effizienz des Katalysators. Vielversprechende Lösungsmittel wurden dann zur Methanolsynthese im kontinuierlichen Prozess eingesetzt, um den Einfluss der Prozessbedingungen zu untersuchen.

info:eu-repo/classification/ddc/540

ddc:540

Hydrierung

Katalyse

Kohlendioxid

Kupfer

Katalysator

Immobilisierung

Glas

Aluminiumoxide

Rieselreaktor