Per-Anders Carlsson

Professor; Chemistry and Chemical Engineering, Applied Chemistry

Per-Anders Carlsson conducts research in materials and surface sciences. Based on the principles of green chemistry and engineering, curiosity is directed towards new catalytic materials with (molecular) functions tailored for applications in environmental protection and sustainable production of chemicals, energy carriers and food. By developing a physical inorganic chemistry approach, robust catalysts are made and characterized with time-resolved experimental methods in controlled, yet realistic, environments at Chalmers and international research facilities. Per-Anders is heading the Chalmers Materials Analysis Laboratory (CMAL) and is active within the Competence Centre for Catalysis (KCK).

Keywords: Material and Surface Sciences; Physical Inorganic Chemistry; Green Chemistry and Catalysis; Operando Characterisation

Transport processes (KBT340)

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Products and Processes in a Sustainable Society (KBT201

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Green Chemistry (KBT245, 7.5 hec)
The course explains the principles of green chemistry and end-of-pipe methods, with a basis in the molecular and materials chemistry, and discusses alternative solutions to support a sustainable development. The level of understanding should be such that the students in their profession as engineers critically can participate in discussions regarding selection of methods for increased sustainability within industrial production of chemicals and fuels, and to avoid environmental stress caused by pollution and energy-related problems.

Heterogeneous Catalysis (FKBT210, 15 hec, graduate level)
The course aims at deep understanding of modern concepts and methods in catalysis with an expansion towards experimental analysis techniques and applications of catalyst technologies. It is designed for doctoral students and experienced materials researchers with an interest in catalysis and surface reactions. Participants should after the course possess the skills to critically analyse catalytic reactions, and synthesise and characterise catalytic materials on the atomic scale. Further, the participanst should gain knowledge about design of relevant catalyst technologies for industrial, environmental and energy-related problems. Biannual course given fall 2021.

​Research Aim and Approach
Catalysis has shaped our past and will shape our future. We explore new catalytic materials, their molecular function and ways to use them for environmental protection and chemical production without putting planetary boundaries for sustainability at risk. We make materials and study their properties with time-resolved spectroscopic and scattering methods in controlled environments (in situ) and most often while monitoring their efficiency (operando). We continuously strive to develop the experimental methodologies (instrument design, data processing etc). The gained knowledge is essential input for the design of new competitive materials and processes. Complementary information, such as the effects on the system level and techno-economic considerations, is achieved through cross-disciplinary collaborations. Funding: Swedish Research Council, Swedish Energy Agency and Chalmers Area of Advance

Green Aromatics for a biobased economy is a research direction where we explore catalytic valorization of low-cost pre-processed hemicellulosic furans/furfurals into benzene, toluene and xylenes (BTXs). These compounds are among the few major chemical building blocks that cannot be made from methane in established processes. Our approach follows many green principles when natural complexity in the renewable feedstock is catalytically refined as opposed to a syngas route where the feedstock first is broken down to a CO/H2 intermediate mixture. Together with researchers at RISE, we adopt a multidisciplinary methodology that incorporates fundamental catalyst science, on-line biostream speciation and techno-economic analysis. Funding: Formas and Swedish Energy Agency.

CO2 Utilization as chemical feedstock for production of base and speciality chemicals is increasingly more important for developing a sustainable chemical industry. Not only is the carbon footprint reduced but also safety and health risks when, for example, phosgene can be replaced with CO2. Our research aims at understanding operating mechanisms and designing new catalyst formulations for efficient CO2 hydrogenation to methane, methanol and higher hydrocarbons, which then can be used as green drop-in reactants in present chemical processes or as so-called electrofuels when the hydrogen is produced by electrolysis. Funding: Swedish Research Council and Knut and Alice Wallenberg foundation.

Power-to-Food (PtF) is a concept for production of food with significantly reduced environmental impact. It takes on the challenge to feed the 10 billion population, as predicted for 2050 by UN, without transgressing the planetary boundaries for sustainability. The concept makes use of energy carried by (renewable) electrical power and a carbon source, such as CO2, to produce food by a number of consecutive chemical steps. This way food can be produced within the planetary boundaries for, e.g., climate change, phosphorous and nitrogen balance, freshwater use, land-system change and biosphere integrity. Together with researchers at RISE, we develop the PtF concept with activities spanning from research on detailed chemistry to studies on system level effects and techno-economic analysis. Funding: Vinnova.

Catalytic Emission Control has been essential for improving urban air quality through mitigation of hazardous emissions from mobile and stationary sources. With increasing human population and emerging mega-cities, both outdoor and indoor air treatment will be necessary for a forseeable future. We study catalytic systems for oxidation of CO and HCs including VOCs and reduction of NOx foremost within the transport sector. We focus on revealing and controlling key structural and chemical catalyst performance parameters to make new catalyst concepts with improved efficiency. Many projects are carried out within the national research environment Competence Centre for Catalysis (KCK). Funding: Swedish Energy Agency, Vinnova and Swedish Research Council.

Doctoral candidates                                     Postdocs                                                   Researchers

Lic Eng Christopher Sauer                              PhD Felix Hemmingsson                          Dr Andreas Schaefer

Lic Eng Mengqiao Di

Lic Eng Yanyue Feng

MSc Alexander Nellessen

MSc Guido de Reijer


PhD Sheedeh Fouladvand; PhD Emma C. Adams; PhD Xueting Wang; PhD Peter Velin

PhD Djamela Bounechada; PhD Natalia M. Martin

MSc Christian Vartia; MSc Henrik Ström; MSc Markus Happel; MSc Michael Nordström; MSc Jiaxu Yang; BSc Steffen Schluter; MSc Laura Batchelli; MSc Dazheng Jing; MSC Samuel Antonio Rosas Melendez; MSc Susanne Ryberg; MSc Dtefan Schernish; MSc Seyyedmajid Sharifvaghefi; BSc Cathrine Kempe; BSc Frida Almqvist; MSc Andreas Persson; MSc Farzin Jahangiri; MSc Mattias Englund; MSc Peter Velin; MSc Sara Brazzée; MSc Niclas Eriksson; MSc Fredrik Carlsson; MSc Jakob Dahlqvist; MSc Oscar Sundell; MSc Linfeng Li; MSc Yuqi Zhang; Pol Mestre; MSc Linnea Hammer úr Skúoy; 

Page manager Published: Wed 16 Nov 2022.