Dr.-Ing. Joachim Venus
Articles in peer reviewed journals [85 Results]
- Kleps, C.; Schneider, R.; Venus, J.; Pleissner, D. (2024): Investigation of the utilization of oat pomace and acid whey in technical scale succinic acid fermentation including downstream processing. Sustainable Chemistry One World. : p. 1-10. Online: https://doi.org/10.1016/j.scowo.2024.100028
- Babor, M.; Liu, S.; Arefi, A.; Olszewska-Widdrat, A.; Sturm, B.; Venus, J.; Höhne, M. (2024): Domain-Invariant Monitoring for Lactic Acid Production: Transfer Learning from Glucose to Bio-Waste Using Machine Learning Interpretation. Bioresource Technology. : p. 1-23. Online: Preprint: http://dx.doi.org/10.2139/ssrn.5012080
- Arefi, A.; Sturm, B.; Babor, M.; Horf, M.; Hoffmann, T.; Höhne, M.; Friedrich, K.; Schroedter, L.; Venus, J.; Olszewska-Widdrat, A. (2024): Digital model of biochemical reactions in lactic acid bacterial fermentation of simple glucose and biowaste substrates. Heliyon. (19): p. 1-13. Online: https://doi.org/10.1016/j.heliyon.2024.e38791
- Olszewska-Widdrat, A.; Babor, M.; Höhne, M.; Alexandri, M.; López Gómez, J.; Venus, J. (2024): A mathematical model-based evaluation of yeast extract’s effects on microbial growth and substrate consumption for lactic acid production by Bacillus coagulans. Process Biochemistry. (November): p. 304-315. Online: https://doi.org/10.1016/j.procbio.2024.07.017
- Wall, A.; Rabemanolontsoa, H.; Venus, J. (2024): Bioprocessing and Fermentation Technology for Biomass Conversion. Applied Sciences. (5): p. 1-3. Online: https://doi.org/10.3390/app14010005 (registering DOI)
- Marzo Gago, C.; Unger, P.; Schneider, R.; Venus, J.; López Gómez, J. (2023): Valorising pasta industry wastes by the scale up and integration of solid-state and liquid-submerged fermentations. Bioresource Technology. (Part A): p. 129909-129909. Online: https://doi.org/10.1016/j.biortech.2023.129909
- Pamueangmun, P.; Abdullahi, A.; Kabir, M.; Unban, K.; Kanpiengjai, A.; Venus, J.; Shetty, K.; Saenjum, C.; Khanongnuch, C. (2023): Lignocellulose Degrading Weizmannia coagulans Capable of Enantiomeric L-Lactic Acid Production via Consolidated Bioprocessing. Fermentation. : p. 1-16. Online: https://doi.org/10.3390/fermentation9080761
- Ioannidou, S.; López Gómez, J.; Venus, J.; Valera, M.; Eßmann, V.; Alegria-Dallo, I.; Kookos, I.; Koutinas, A.; Ladakis, D. (2023): Techno-economic evaluation and life cycle assessment for sustainable alternative biorefinery concepts using the organic fraction of municipal solid waste. Green Chemistry. (11): p. 4482-4500. Online: https://doi.org/10.1039/D3GC00244F
- Klongklaew, A.; Unban, K.; Kalaimurugan, D.; Kanpiengjai, A.; Azaizeh, H.; Schroedter, L.; Schneider, R.; Venus, J.; Khanongnuch, C. (2023): Bioconversion of Dilute Acid Pretreated Corn Stover to L-Lactic Acid Using Co-Culture of Furfural Tolerant Enterococcus mundtii WX1 and Lactobacillus rhamnosus SCJ9. Fermentation. (2): p. 112. Online: https://doi.org/10.3390/fermentation9020112
- Olszewska-Widdrat, A.; Xiros, C.; Wallenius, A.; Schneider, R.; Portugal Rios da Costa Pereir, L.; Venus, J. (2023): Bioprocess optimization for lactic and succinic acid production from pulp and paper industry side stream. Frontiers in Bioengineering and Biotechnology. : p. 1-8. Online: https://doi.org/10.3389/fbioe.2023.1176043
Monographs by authorship [1 result]
Monographs by editorship [1 result]
Bookchapters and proceedings [26 Results]
- López Gómez, J.; Marzo Gago, C.; Venus, J. (2023): Upgrading pasta waste through lactic acid fermentation. In: . WIRE’s MC Meeting & 3rd Working Groups Workshop Waste biorefinery technologies for accelerating sustainable energy processes. (ISBN 978-989-8806-69-7), p. 89-90.
- Pleissner, D.; Dietz, D.; van Duuren, J.; Wittmann, C.; Yang, X.; Ki Lin, C.; Venus, J. (2019): Biotechnological production of organic acids from renewable resources. In: Advances in Biochemical Engineering/Biotechnology. . Springer, Berlin, Heidelberg, (ISBN 978-3-319-97119-3), p. 373-410. Online: https://doi.org/10.1007/10_2016_73
- Venus, J. (2018): Stoffliche Nutzung von Biomasse. In: Berger, L.(eds.): Bioökonomie und Bioversität. Workshop Dokumentation. . Bundesamt für Naturschutz, Bonn - Bad Godesberg, (978-3-89624-233-4), p. 50-54. Online: http://epflicht.ulb.uni-bonn.de/content/titleinfo/409314
- Demichelis, F.; Pleissner, D.; Venus, J.; Fiore, S. (2016): Fermentative production of lactic acid and biogas from food waste: preliminary tests. In: CISA Publisher Italy(eds.): SUM 2016 Symposium on Urban Mining and Circular Economy. SUM 2016 "3rd Symposium on Urban Mining and Circular Economy. p. 1-9.
- Pleissner, D.; Neu, A.; Venus, J. (2016): Verwertung von Reststoffen aus der Kaffeeproduktion als Kohlenstoffquellen in der fermentativen Milchsäureproduktion. In: DGQ(eds.): Pflanzen für die Bioökonomie - Welche Herausforderungen ergeben sich für die Qualität nachwachsender Rohstoffe?. 50. Vortragstagung DGQ "Pflanzen für die Bioökonomie - Welche Herausforderungen ergeben sich für die Qualität nachwachsender Rohstoffe?". Eigenverlag, Braunschweig, (ISSN 1866-590X), p. 35-35. Online: DOI 10.5073/berjki.2016.183.000
- Pleissner, D.; Venus, J. (2016): Scale-up of Continuous Mode Lactic Acid Fermentation. In: . Training School "Regulations and policy in food waste valorization". p. 1-10.
- Pleissner, D.; Venus, J. (2016): Vom Reststoff zum Biokunststoff. In: bioenergy2020(eds.): Biobased Future. . Eigenverlag, Graz, p. 13-13.
- Kwan, T.; Pleissner, D.; Lau, K.; Venus, J.; Pommeret, A.; Lin, C. (2015): Techno-economic analysis of a food waste valorization process via microalgae cultivation and co-production of plasticizer, lactic acid and animal feed from algal biomass and food waste. In: Proceeding of the. International Conference on Solid Wastes 2015. p. 499-503.
- Pleissner, D.; Venus, J. (2015): Scale-up of fermentative lactic acid production from renewable feedstocks. In: DECHEMA(eds.): Abstract book. Dechema Himmelfahrtstagung "Scale-up and scale-down of bioprocesses". p. 72-72.
- Venus, J.; Pleissner, D. (2015): Bioconversion of renewable feedestocks and (agri/food) residues into lactic acid. In: Körner, I.(eds.): Abstract book. 16th International Conference Rural-Urban Symbiosis (RAMIRAN). TuTech Verlag, Hamburg, (ISBN: 978-3-941492-95-0), p. 1-4. Online: https://portal.dnb.de/opac.htm?method=simpleSearch&cqlMode=true&query=idn%3D1076174809
Orals and posters [226 Results]
- López Gómez, J.; Marzo Gago, C.; Venus, J. (2023): Upgrading pasta waste through lactic acid fermentation.
- Schroedter, L.; Venus, J. (2023): Produktion von optisch reiner L-Milchsäure aus Altholz.
- Schroedter, L.; Schneider, R.; Venus, J. (2023): Production of optically pure lactic acid from waste wood via continuous fermentation with cell-recycle.
- Venus, J. (2023): Herausforderungen bei der fermentativen Herstellung biobasierter Produkte.
- Venus, J. (2023): Production of lactic acid from biowaste.
- Venus, J. (2023): Biowaste as feedstock for lactic acid fermentation.
- Venus, J. (2023): Lignocellulosic Biomass and Residues as Potential Substrates for the Industrial Biotechnology.
- Schneider, R.; Venus, J. (2023): Überwachung und Regelung von Substraten und Produkten bei der Herstellung organischer Säuren.
- Venus, J. (2023): Fermentationsprodukte aus biogenen Roh- und Reststoffen - Herausforderungen und Chancen für die Region.
- Venus, J. (2023): Herausforderungen bei der fermentativen Herstellung biobasierter Produkte.