Clemens Mostert (Dr.-Ing.)
Wissenschaftlicher Mitarbeiter
- Telefon
- +49 561 804-6131
- mostert[at]cesr[dot]de
- Standort
- Wilhelmshöher Allee 47
34109 Kassel
- Raum
- Raum 1170
Vita
Akademischer Werdegang seit 2016 Habilitation am Fachgebiet Nachhaltiges Ressourcenmanagement (Prof. Bringezu) der Universität Kassel 2003-2007 Promotion am Fachgebiet Umweltgerechte Produkte und Prozesse (Prof. Hesselbach) der Universität Kassel, Abschluss: Dr.-Ing. 2002-2003 Studium "International Marketing and Sales" an der Kassel International Management School, Abschluss: MBA 1989-1995 Studium der Luft- und Raumfahrttechnik an der Universität Stuttgart, Abschluss: Dipl.-Ing. |
Publikationen
2023
| Mostert, C., Sameer, H., & Bringezu, S. (2023). Die Ermittlung der Ressourceneffizienz und der Klimabelastung von Bauwerken. In N. Fouad (Hrsg.), 2023 Bauphysik Kalender (S. 83–118). Berlin: Ernst & Sohn, Wiley. https://doi.org/10.1002/9783433611289.ch4 |
2022
| Mostert, C., Weber, C., & Bringezu, S. (2022). Modelling and Simulation of Building Material Flows: Assessing the Potential for Concrete Recycling in the German Construction Sector. Recycling, 7, 13. https://doi.org/10.3390/recycling7020013 |
| Sameer, H., Behem, G., Mostert, C., & Bringezu, S. (2022). Comparative Analysis of Resource and Climate Footprints for Different Heating Systems in Building Information Modeling. Buildings, 12(11), 1824. https://doi.org/10.3390/buildings12111824 |
| Mostert, C., Bock, J., Sameer, H., & Bringezu, S. (2022). Environmental Assessment of Carbon Concrete Based on Life-Cycle Wide Climate, Material, Energy and Water Footprints. Materials, 15(14), 4855. https://doi.org/10.3390/ma15144855 |
| Mostert, C., & Bringezu, S. (2022). Biotic Part of the Product Material Footprint: Comparison of Indicators Regarding Their Interpretation and Applicability. Resources, 11, 56. https://doi.org/10.3390/resources11060056 |
| Kaiser, S., Siems, F., Mostert, C., & Bringezu, S. (2022). Environmental and Economic Performance of CO2-Based Methanol Production Using Long-Distance Transport for H2 in Combination with CO2 Point Sources: A Case Study for Germany. Energies, 15, 2507. https://doi.org/10.3390/en15072507 |
2021
| Mostert, C., Sameer, H., Glanz, D., Bringezu, S., & Rosen, A. (2021). Neubau aus Rückbau: Wissenschaftliche Begleitung der Planung und Durchführung des selektiven Rückbaus eines Rathausanbaus aus den 1970er-Jahren und der Errichtung eines Neubaus unter Einsatz von Urban Mining (RückRat). Abgerufen von https://www.bbsr.bund.de/BBSR/DE/veroeffentlichungen/bbsr-online/2021/bbsr-online-15-2021-dl.pdf;jsessionid=C8EEBE16CBE0F5FFCA19A9B7147F321E.live21303?__blob=publicationFile&v=3 |
| Mostert, C., Sameer, H., Glanz, D., & Bringezu, S. (2021). Climate and resource footprint assessment and visualization of recycled concrete for circular economy. Resources, Conservation and Recycling, 174, 105767. https://doi.org/10.1016/j.resconrec.2021.105767 |
2020
| Mostert, C., Sameer, H., Glanz, D., & Bringezu, S. (2020). Urban Mining for Sustainable Cities: Environmental Assessment of Recycled Concrete. IOP Conference Series: Earth and Environmental Science, 588, 052021. https://doi.org/10.1088/1755-1315/588/5/052021 |
| Turnau, S., Mignot, C. S., Mostert, C., & Bringezu, S. (2020). Material or fuel: comparative cradle-to-grave climate and material footprint analysis for the use of methanol from recycled CO2. Green Chemistry, 1–22. https://doi.org/10.1039/D0GC02946G |
| Sameer, H., Mostert, C., & Bringezu, S. (2020). Product Resource and Climate Footprint Analysis during Architectural Design in BIM. IOP Conference Series: Earth and Environmental Science, 588, 052022. https://doi.org/10.1088/1755-1315/588/5/052022 |
2019
| Sameer, H., Weber, V., Mostert, C., Bringezu, S., Fehling, E., & Wetzel, A. (2019). Environmental Assessment of Ultra-High-Performance Concrete Using Carbon, Material, and Water Footprint. Materials, 12(6), 851. https://doi.org/10.3390/ma12060851 |
| Mostert, C., & Egenolf, V. (2019). Software Supported Calculation of the Product Wood Footprint using Regionalized Characterization Factors. In R. Schaldach, K.-H. Simon, J. Weismüller, & V. Wohlgemuth (Hrsg.), Environmental Informatics: Computational Sustainability: ICT methods to achieve the UN Sustainable Development Goals (S. 208–213). Düren: Shaker. |
| Bringezu, S., Kaiser, S., Turnau, S., & Mostert, C. (2019). Bestimmung des Materialfußabdrucks mit ökobilanziellen Methoden und Softwarelösungen (S. TBD). Universität Kassel. https://doi.org/10.17170/KOBRA-202003241101 |
| Mostert, C., & Bringezu, S. (2019). Measuring Product Material Footprint as New Life Cycle Impact Assessment Method: Indicators and Abiotic Characterization Factors. Resources, 8(2), 61. https://doi.org/10.3390/resources8020061 |
2018
| Mostert, C., Ostrander, B., Bringezu, S., & Kneiske, T. (2018). Comparing Electrical Energy Storage Technologies Regarding Their Material and Carbon Footprint. Energies, 11(12), 3386. https://doi.org/10.3390/en11123386 |
2009
| Schlüter, A., Hesselbach, J., Mirciov, S., Mostert, C., & Junge, M. (2009). Praxisleitfaden - Energieeffizienz in der Produktion. Hessen-Umwelttech, 8/2009, 2–47. |
2007
| Mostert, C. (2007). Fabrik-Umfeld Simulationsmodell zur kennzahlenbasierten Bewertung von Produktionsstrategien. Kassel: kassel university press. Abgerufen von urn:nbn:de:0002-3327 |