Here you can find a list of our scientific publications:

  1. Loureiro, T.; Sterling, R., Biorefinery Combining HTL and FT to Convert Wet and Solid Organic, Industrial Wastes to 2nd Generation Biofuels with Highest Efficiency: Heat-to-Fuel, Proceedings 2, 1128, 2018.
  2. Pipitone, G.; Zoppi,G.; Ansaloni, S.; Bocchini, S.; Deorsola, F.; Pirone, R.; Bensaid, S., Towards the sustainable hydrogen production by catalytic conversion of C-laden biorefinery aqueous streams, Chemical Engineering Journal, 2018.
  3. Miliotti, E.; Dell’Orco, S.; Lotti, G.; Rizzo, A.; Rosi, L.; Chiaramonti, D., Lignocellulosic Ethanol Biorefinery: Valorization of Lignin-Rich Stream through Hydrothermal Liquefaction, Energies 12(4), 2019.
  4. Mauerhofer, A.; Fuchs, J.; Müller, S.; Benedikt, F.; Schmid, J.; Hofbauer, H., CO2 gasification in a dual fluidized bed reactor system: Impact on the product gas composition, Fuel 253, 2019.
  5. Aranda, I.; Loureiro, T., Scientific review of the Heat-to-Fuel Project, Proceedings 20 (6), 2019.
  6. Mauerhofer, A.; Müller, S.; Benedikt, F.; Fuchs, J.; Bartik, A.; Hofbauer, H., CO2 gasification of biogenic fuels in a dual fluidized bed reactor system, Biomass Conversion and Biorefinery, 2019.
  7. Mauerhofer, A.; Schmid, J.; Benedikt, F.; Fuchs, J.; Müller, S.;  Hofbauer, H., Dual fluidized bed steam gasification: Change of product gas quality along the reactor height, Energy 173, 2019.
  8. Pipitone, G.; Zoppi, G.; Frattini, A.; Bocchini, S.; Pirone, R.; Bensaid, S., Aqueous phase reforming of sugar-based biorefinery streams: from the simplicity of model compounds to the complexity of real feeds, Catalysis Today, 2019.
  9. Pipitone, G.; Zoppi, G.; Bocchini, S.; Rizzo, A.; Chiaramonti, D.; Pirone, R.; Bensaid, S., Aqueous phase reforming of the residual waters derived from lignin-rich hydrothermal liquefaction: investigation of representative organic compounds and actual biorefinery streams, Catalysis Today, 2019.
  10. Mauerhofer, A.; Müller, S.; Benedikt, F.; Fuchs, J.; Bartik, A.; Hammerschmid, M.; Hofbauer, H., Dual fluidized bed biomass gasification: Temperature variation using pure CO2 as gasification agent, Proceedings ICPS 19, 2019.
  11. Szul, M.; Słowik, K.; Głód, K.; Iluk, T., Influence of pressure and CO2 in fluidized bed gasification of waste biomasses, Proceedings ICPS19, 2019.
  12. Dell’Orco, S.; Miliotti, E.; Lotti, G.; Rizzo, A.; Rosi, L.; Chiaramonti, D., Hydrothermal Depolymerization of Biorefinery Lignin-Rich Streams: Influence of Reaction Conditions and Catalytic Additives on the Organic Monomers Yields in Biocrude and Aqueous Phase, Energies, 2020.
  13. Zoppi, G.; Pipitone, G.; Gruber, H.; Weber, G.; Reichhold, A.; Pirone, R.; Bensaid, S., Aqueous phase reforming of pilot-scale Fischer-Tropsch water effluent for sustainable hydrogen production, Catalysis Today, 2020.
  14. Rizzo, A.; Dell’Orco, S.; Miliotti, E.; Chiaramonti, D., Design, Commissioning And Start-Up of a New Hydrothermal Liquefaction Continuous Pilot Unit, Chemical Engineering Transactions, 2020.
  15. Zoppi, G.; Pipitone, G.; Galletti, C.; Rizzo, A.; Chiaramonti, D.; Pirone, R.; Bensaid, S., Aqueous phase reforming of lignin-rich hydrothermal liquefaction by-products: A study on catalyst deactivation, Catalysis Today, 2020.
  16. Pérez, L.Aranda, I.Loureiro, T., Novel Process to Convert Wet and Dry Organic Feedstocks into 2nd Generation Biofuels: A Scientific Review of the Heat-to-Fuel Project, Proceedings 65 (13), 2020.
  17. Zoppi, G.Pipitone, G.Pirone, R.Bensaid, S., Aqueous phase reforming process for the valorization of wastewater streams: Application to different industrial scenarios, Catalysis Today, 2021.

For more information on all of the project’s public data, check out Heat to Fuel’s page in Zenodo.