Sewage sludge, a continuously available municipal waste, offers a renewable alternative to first-generation biofuels without competing with arable land.However, biocrude derived from the pyrolysis of sewage sludge contains high nitrogen and oxygen levels, making it immiscible with fossil fuels without further upgrading.This study systematically investigates the chem. composition of biocrude (both feeds and hydrotreated products) produced in a catalytic two-reactor system under varying processing conditions.Supercritical fluid chromatog. (SFC) coupled with high-resolution mass spectrometry (HRMS) was employed for chem. characterization, including feature detection, filtering, and statistical anal.Nontarget screening anal. identified compounds and homologous series affected by hydrotreatment, with 44 compounds confirmed using standards, including fatty acid amides (FAA), fatty acids, quinolines, carbolines, indoles, hydroxylated polycyclic aromatic hydrocarbons, imidazoles, and benzimidazoles.At mild conditions (reactor temperatures below 200 °C), fatty acids decreased, while FAA, imidazoles, indoles, quinolines, carbolines, and hydroxylated polycyclic aromatic hydrocarbons remained stable or increased, suggesting intermediate formation or ionization efficiency changes due to matrix effects and ion competition in electrospray ionization.Higher second-reactor temperatures reduced nitrogen, oxygen, and sulfur content and the aforementioned compound groups.However, the reduction of pyridines and anilines required pressures of 120 bar and temperatures of 360 °C.The SFC-HRMS platform, with minimal sample preparation and fast anal. time, provides a powerful tool to monitor the chem. composition of biocrudes under varying hydrotreatment conditions, facilitating the production of compatible biofuels from sewage sludge.

01 Nov 2021·JOURNAL OF CATALYSIS

Single-atom Pt promotion of industrial Co-Mo-S catalysts for ultra-deep hydrodesulfurization

Author: Weise, Christian Frederik ; Moses, Poul Georg ; Falsig, Hanne ; Brorson, Michael ; Helveg, Stig ; Hansen, Lars Pilsgaard

We introduce a tertiary transition metal sulfide nanostructure, Pt-Co-Mo-S, for catalytic hydrodesulfurization (HDS) of sulfur-containing mols. in crude oil distillates with the aim to produce ultra-low sulfur transport fuels.The addition of ppm-levels of Pt to a standard industrial Co-Mo-S catalyst boosts the HDS activity by up to 46%.The promotional effect is examined by combining at.-resolution Scanning Transmission Electron Microscopy (STEM), Energy Dispersive X-ray Spectroscopy (EDX), X-ray Absorption Near Edge Spectroscopy (XANES) and D. Functional Theory (DFT).It is shown that the Pt-Co-Mo-S catalyst contains predominantly single-layer MoS₂ nanocrystals with Co atoms fully covering the S-edge terminations and Pt atoms uniquely attached to corner and edge sites in a platinum(IV) sulfide-like structural motif.Platinum is suggested to reduce the sulfur binding energy and increase the abundance of coordinately undersaturated sites (CUS) and not necessarily changing the reactivity towards 4,6-DMDBT mols., although more elaborate studies are needed to address this in detail.

01 Mar 2021·Emission Control Science and Technology

Modeling and Optimization of Multi-functional Ammonia Slip Catalysts for Diesel Exhaust Aftertreatment

Author: Jensen, Anker Degn ; Janssens, Ton V. W. ; Vennestroem, Peter N. R. ; Torp, Thomas Klint ; Hansen, Brian Brun

Ammonia slip catalysts (ASC) are used downstream of the NH3-selective catalytic NOx reduction (SCR) system, to minimize ammonia slip from transport sector SCR units.The ASC may consist of an SCR active layer for NOx control, a layer with oxidation functionality for ammonia conversion, or a combination thereof, either as individual layers or as a single mixed layer.Math. models of such systems involve flow and mass transfer in the monolithic channels as well as coupled reaction/diffusion processes in the catalytic layers.In this work, we develop a single-channel 1D-1D (pseudo 2D) steady-state tank-in-series math. model for monolithic ammonia slip catalysts with up to two layers.Kinetics of relevant reactions over the Cu-Beta zeolite and the Pt/TiO₂ layer, including SCR, ammonia oxidation, and the formation of N₂O, were derived based on an extensive flow reactor study.Comparison of ten ASC configurations for the oxidation of 200 ppm NH₃ at 300°C shows that configurations with a pure layer of NH3 oxidation catalyst generate undesirable high N₂O and NOx levels.The best ASC configurations feature fast diffusion in the catalytic layers (a high effective diffusion coefficient), a thin top layer loading with some ammonia oxidation catalyst, and a mixed layer of ammonia oxidation catalyst and the SCR catalyst to limit the formation of N₂O and NOx.

News (Medical) associated with Topsoe A/S

16 Jun 2021

·www.globenewswire.com

Ørsted plans carbon capture at Avedøre Power Station as part of the Green Fuels for Denmark project

Ørsted has identified the 100 MW straw-fired unit at the Avedøre Power Station in Copenhagen as the best point source of sustainable CO2 for the next phases of the Green Fuels for Denmark Power-to-X facility in the Greater Copenhagen area which over time is planned to reach a total capacity of 1.3 GW and have a carbon emission abatement potential of 850,000 tonnes yearly. If the project at Avedøre Power Station is realised, it could become Ørsted’s first carbon capture facility. A future final investment decision for the carbon capture project is subject to the realisation of the parts of Green Fuels for Denmark that will produce e-methanol and e-kerosene. Ørsted owns and operates Avedøre Power Station. The combined heat and power plant consists of two wood pellet-fired units and a straw-fired unit that supply power to the Danish power grid and district heating to the Greater Copenhagen area. Ørsted and HOFOR recently announced an agreement that Ørsted will offtake the power production from HOFOR’s planned 250 MW Aflandshage offshore wind farm for parts of the Green Fuels for Denmark project. With the agreement to source renewable electricity in place, Ørsted has now identified the straw-fired unit at Avedøre Power Station as the best point source of sustainable carbon, and will now investigate the possibilities of advancing parts of the project’s first phases in order to deliver substantial amounts of sustainable fuels well before the previously planned 2027 operation date of the second phase. Recently, Green Fuels for Denmark took an important step closer to realisation as the project became part of the process of being named an Important Project of Common European Interest (IPCEI) in the EU programme initiated to kick-off the hydrogen economy in the EU. Green Fuels for Denmark is envisaged to be built in phases, beginning with approximately 10 MW, scaling up corresponding to the supply of electricity to reach 1,300 MW of total electrolysis capacity when fully developed. While the first phase of Green Fuels for Denmark will exclusively produce hydrogen for heavy-duty road transport, the next phase is planned to combine the production of renewable hydrogen with carbon capture to produce sustainable methanol and e-kerosene for shipping and aviation, respectively. CO2 from sustainable sourcesProvided that a framework is established to promote the development of sustainable fuels, the 100 MW straw-fired unit at Avedøre Power Station could provide the amount of CO2 necessary for producing sustainable fuels in the next phases of Green Fuels for Denmark. Ørsted will now start investigating the best way forward to deploy carbon capture technology at the straw-fired unit at Avedøre Power Station, including optimising the electrolysis capacity of the second phase of Green Fuels for Denmark with the supply of renewable electricity. The straw-fired unit is fuelled by locally sourced agricultural by-products converting approx. 130,000 tonnes of straw each year to heat and power. The combination of using straw as fuel and utilising the surplus heat from both the carbon capture process and the Power-to-X process would result in up to 260 MW district heating, which would lead to both green and price-competitive district heating for the Greater Copenhagen area. Anders Nordstrøm, Vice President and head of Ørsted’s hydrogen and Power-to-X activities, said: “If Green Fuels for Denmark is realised, Copenhagen could become a showcase example of how new and existing energy technology can be combined to deliver on the vast European ambitions for sustainable fuels. Denmark can leverage its district heating systems, large sources of sustainable carbon, and massive offshore wind resources to create a new industrial stronghold and supply sustainable fuels to Danish logistics companies that are leading the green transformation of heavy transport. Green Fuels for Denmark is an ideal flagship project to realise this potential, and the agreement with Avedøre Power Station to source sustainable CO2 underlines Ørsted’s commitment to the project.” Ole Thomsen, Senior Vice President, Ørsted Bioenergy, says: “Converting our power stations from fossil fuels to sustainable biomass has been a centre-piece in Ørsted’s and Denmark’s green transformation. Utilising the potential for carbon capture at Avedøre Power Station could potentially be a showcase for even further decarbonisation at our power stations. Ørsted is currently exploring the potential for carbon capture at some of our other bioenergy plants, which would enable the carbon necessary for Power-to-X production plants to further contribute to the green transformation of our society.” The production of renewable hydrogen and sustainable fuels has a significant potential to reduce carbon emissions from hard-to-abate sectors, such as heavy transport. Sustainable fuels are currently more expensive to produce than fossil-based fuels. To reduce the cost, the production of sustainable fuels must be built out at industrial scale – just as we have seen with renewable energy technologies, such as offshore wind, onshore wind, and solar PV over the past decade. For this to be feasible, industry must join forces with governments to create the right framework that enables private investment in large-scale sustainable fuel production. About Green Fuels for DenmarkGreen Fuels for Denmark is Denmark's most ambitious vision for large-scale production of sustainable fuels and has a decarbonisation potential of 850,000 tonnes. Behind the project is a partnership consisting of A.P. Moller - Maersk, DSV Panalpina, DFDS, SAS, Copenhagen Airports, and Ørsted. Nel, Haldor Topsøe, and Everfuel have partnered up on the first phase of Green Fuels for Denmark and on developing the second phase. In addition, COWI is a knowledge partner on the project. The project is backed by Molslinjen, the City of Copenhagen, and the Capital Region of Denmark. Ørsted will continue to pursue opportunities to secure sustainable carbon and green power from additional sources for Green Fuels for Denmark towards the commissioning of the planned energy hub at the Danish island Bornholm. For further information, please contact:Media RelationsMichael Korsgaard+45 99 55 94 25mikon@orsted.dk Investor RelationsAllan Bødskov Andersen+45 99 55 79 96ir@orsted.dkAbout ØrstedThe Ørsted vision is a world that runs entirely on green energy. Ørsted develops, constructs, and operates offshore and onshore wind farms, solar farms, energy storage facilities, and bioenergy plants, and provides energy products to its customers. Ørsted ranks as the world’s most sustainable energy company in Corporate Knights' 2021 index of the Global 100 most sustainable corporations in the world and is recognised on the CDP Climate Change A List as a global leader on climate action. Headquartered in Denmark, Ørsted employs 6,311 people. Ørsted's shares are listed on Nasdaq Copenhagen (Orsted). In 2020, the group's revenue was DKK 52.6 billion (EUR 7.1 billion). Visit orsted.com or follow us on Facebook, LinkedIn, Instagram, and Twitter. Attachment

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