Loving the desert 🐪 so much! Even if you woke up with 🦂 https://www.instagram.com/p/B9JkP_mgxcSGK6j9ANg_oHhESj93l3hJKYuU-s0/?igshid=mzdo77voer9o

Au nanoparticle sintering (video 2)

What are the limiting factors for waste-to-hydrogen?

Undoubtedly, hydrogen (H2) is a clean feedstock and energy carrier whose sustainable production should be anticipated. The pyrolysis of biomass or waste plastics and the subsequent reforming over base (transition) or noble metals supported catalysts allows reaching elevated H2 yields. However, the catalyst used in the reforming step undergoes a rapid and severe deactivation by means of a series of physicochemical phenomena, including metal sintering, metallic phase oxidation, thermal degradation of the support and, more notoriously, coke deposition. This review deals with the currently existing alternatives at the catalyst and reactor level to cope with catalyst deactivation and increase process stability, and then delves with the fundamental phenomena occurring during this catalyst deactivation. An emphasis is placed on coke deposition and its influence on deactivation, which depends on its location, chemical nature, morphology, precursors or formation mechanism, among others. We also discuss the challenges for increasing the value of the carbon materials formed and therefore, enhance process viability.

Here is the link for the free download over the next days: https://authors.elsevier.com/a/1aWoF4s9Hvxlyn

§ Ochoa, A., Bilbao, J., Gayubo, A.G., Castaño, P., Coke Formation and Deactivation during Catalytic Reforming of Biomass and Waste Pyrolysis Products: a Review, Renew. Sustain. Energy Rev. (1364-0321), 119 (2020) 109600. DOI: 10.1016/j.rser.2019.109600.

When you land in Oslo from Saudi (at Vigelandsanlegget) https://www.instagram.com/p/B21p4dXgDn8HH3LTUV8-i9Hie5AZoLbZRRjscM0/?igshid=l0lpgzslbdrc

Arabia and the ♾ (at I don't know where I'm) https://www.instagram.com/p/B18Eaupgohp_JeGc7q6S37Qe2KUC4y9PbnbTrs0/?igshid=sbk9y5w2h7f8

at San Diego, California https://www.instagram.com/p/B1pqQKeAkamlwkenUXmE2stuBpU2ZDoccORK4Q0/?igshid=167m6k3hd89hh

Mesmerized with the Red Sea. Photo credit: Jerry Gordon (at Red Sea) https://www.instagram.com/p/B0a4RAEgHo_bIGzG16Pbcfdh8O25pWs5qPAQJs0/?igshid=1pwj2dfre2npx

Dream in the beacon (at King Abdullah University of Science and Technology) https://www.instagram.com/p/BzWHlJIg-9QVMVQuSrZe1XO1tZT6RZchRYSr4Y0/?igshid=1vs4kn19e3gae

Polyolefin wastes as co-feedstock for boosting FCC performance

Polyolefin wastes are great feedstock for the fluid catalytic crackers (FCC). In our work in Fuel Processing Technology (Elsevier), we proved once more the benefits of this feedstock and step up into the best way to feed these wastes: a previous pyrolysis in delocalized units. In particular, in this work we demonstrate how polyolefins are beneficial in terms of conversion, product distribution, gasoline yield and above all, diminishing the catalyst deactivation. We have recurrently analyzed the deactivated FCC samples in order to propose a mechanism behind the mentioned positive outcomes of polyolefins. Thus, in light of our results polyolefins can be of interest as when co-fed with very heavy oil fractions, in order to cope the severe coke deposition of the latter.

Rodríguez, E., Elordi, E., Valecillos, J., Izaddoust, S., Bilbao, J., Arandes, J.M., Castaño, P., Coke Deposition and Product Distribution in the Co-Cracking de Waste Polyolefin Derived Streams and Vacuum Gas Oil under FCC Unit Conditions, Fuel Process. Technol., 192 (2019) 130-130. DOI: 10.1016/j.fuproc.2019.04.012.

Small microreactors to visualize hydrodynamics

In our recent work in Reaction Chemistry & Engineering (RSC) we have proved the great impact of solid arrangement in microreactors for developing a particular hydrodynamic flow. This issue is of primary importance in order to enhance mass and heat transfer in high-throughput screening systems using catalyst (solid and stationary) and a dynamic flow of gas and liquid passing trough. Examples of these systems are used every day for hydroprocessing, hydrotreating, selective hydrogenation, selective oxidation, liquid phase reforming… among many others. Besides, the mentioned mass and heat transfer limitations are pressingly important for very active catalyst testing, which is the case in the majority of the examples mentioned.

Our approach was designing, building and testing micro-machined reactors, with pillars of 150 µm arranged homogeneously or heterogeneously. The testing experiments were performed allowing flows of liquid and gas trough the systems; using different capillary numbers, contact angles and gas-liquid velocities; and quantifying the hydrodynamic behavior by image processing using a florescence microscope and Matlab. The results show that the interfacial area and the pulsing hydrodynamic behavior can be modified by changing the arrangement of the pillars, the capillary number or the contact angle in these systems.

§ Márquez, N., Moulijn, J.A., Makkee, M., Kreutzer, M.T., Castaño, P., Tailoring the Multiphase Flow Pattern of Gas and Liquid through Micro-Packed Bed of Pillars, React. Chem. Eng. (2058-9883), 4 (2019) 838-851. DOI: 10.1039/c9re00056a.

How to perform a catalyst screening with thousands of reactants/products?

Many catalytic reactions involve thousands of types of molecules with different nature, interacting one another and with the catalyst. In such cases, performing a catalyst screening is rather difficult because simple concepts such as “conversion” cannot be calculated straight forward. Based on a detailed product analysis, we propose in this work a methodology to account and quantify catalyst activity in complex multi-parallel chemistries with heavy fractions. This is a step forward into the rational reaction engineering of these processes.

You can access this work for free in the following days using this link

 Palos, R., Kekäläinen, T., Duodu, F., Gutiérrez, A., Arandes, J.M., Jänis, J., Castaño, P., Screening Hydrotreating Catalysts for the Valorization of a Light Cycle Oil/Scrap Tires Oil Blend Based on a Detailed Product Analysis,Appl. Catal. B: Environ. (0926-3373), 256 (2019) 117863. DOI: 10.1016/j.apcatb.2019.117863.

✅ Meeting the president and ✅ one of the most influential figures here in KAUST @clairesaleksa #kaust #kaustlife (at KAUST- King Abdullah University For Science And Technology) https://www.instagram.com/p/Bw1l5V1A-ttjqkeMn6LnKCdd_SayKsScoL24jk0/?utm_source=ig_tumblr_share&igshid=1dtxki923tih

Shall we bet? (at Gardens Lane at KAUST) https://www.instagram.com/p/Bwu676HATqd3bNlbaCroEqQXogrOi4ezJ4jQeg0/?utm_source=ig_tumblr_share&igshid=dcno49l0nqkm

IKEA’s immersion v.4.0 (at IKEA) https://www.instagram.com/p/BwuwigKAZtWsbXFMb7bKz3Um7ThE9qLnXqwWNs0/?utm_source=ig_tumblr_share&igshid=dnttijkdv4lw

This is how I feel right now... https://www.instagram.com/p/BwRBYqRHBWkrtXl74y_JF_pqWmvhaRC27tQwdI0/?utm_source=ig_tumblr_share&igshid=ygjkh48fpt2u