Conference Proceedings

2026

[20]	Mahendran, J., Funk, M., Faber, F., Dieguez-Alonso, A., Vorhauer-Huget, N., Ilona, R., & Barowski, J. (2026). Material Characterization Through an Overmoded Circular Waveguide Using a D-Band FMCW Radar. 17th German Microwave Conference (GeMiC 2026)

2025

[19]	Briest, L., Wagner, R., Tretau, A., Ganß, M., , ., Tsotsas, E., & Vorhauer-Huget, N. (2025). In-situ temperature monitoring during microwave heating using fiber-optic sensors. 2nd international workshop on reacting particle-gas systems: modelling and experimental characterization of reactive particle-gas systems, 187–189. https://doi.org/10.25673/118928
[18]	Faber, F., Bhaskaran, S., Dieguez-Alonso, A., & Vorhauer-Huget, N. (2025). Methodology for derivation of effective heat transfer properties by pore network modeling. 2nd international workshop on reacting particle-gas systems: modelling and experimental characterization of reactive particle-gas systems, 76–78. https://doi.org/10.25673/118928
[17]	Ujjani Narasimhaiah, A., Schmidt, A., Briest, L., Tretau, A., Wagner, R., Tsotsas, E., & Vorhauer-Huget, N. (2025). Modelling of a lab-scale microwave dryer for thermally thick materials. 2nd international workshop on reacting particle-gas systems: modelling and experimental characterization of reactive particle-gas systems, 128–130. https://doi.org/10.25673/118928

2024

[16]

Dernbecher, A., Bhaskaran, S., Vorhauer-Huget, N., Seidenbecher, J., Gopalkrishna, S., Briest, L., & Dieguez-Alonso, A. (2024). Evaluation of Convective Heat Transfer Inside the Pores of Pyrolyzed Wood using a µ-CT Based Realistic Geometry. Advances in Computational Heat and Mass Transfer: Proceedings of the 14th International Conference on Computational Heat and Mass Transfer (ICCHMT 2023), 386 – 395. https://doi.org/10.1007/978-3-031-66609-4_36

2023

[15]	Govindarasu, V., Wagner, R., Ganß, M., Tretau, A., Vorhauer-Huget, N., & Briest, L. (2023). Analysis of the power input for crack-free drying of green bricks. Proceedings of the 19th International Conference on Microwave and High-Frequency Applications (AMPERE 2023) https://doi.org/10.5281/zenodo.10159426
[14]	Ganß, M., Wagner, R., Tretau, A., Vorhauer-Huget, N., Briest, L., & Tsotsas, E. (2023). Measuring of process-dependent temperature distribution in bricks during drying with intermittent microwaves using distributed fibre-optical sensors. Proceedings of the 19th International Conference on Microwave and High-Frequency Applications (AMPERE 2023) https://doi.org/10.5281/zenodo.10159426
[13]	Briest, L., Dharmananda, P., Tretau, A., Wagner, R., Tsotsas, E., & Vorhauer-Huget, N. (2023). Microwave heating as a possible route for the defossilization of green brick drying. Proceedings of the 8th European Drying Conference (EuroDrying 2023)
[12]	Gruber, S., Thomik, M., Vorhauer-Huget, N., Coppens, F., Tsotsas, E., & Först, P. (2023). In-situ analysis of the 3-D microstructure and its impact on the freeze-drying kinetics. Proceedings of the 8th European Drying Conference (EuroDrying 2023)
[11]	Vorhauer-Huget, N., Thomik, M., Gruber, S., Först, P., & Tsotsas, E. (2023). Pore network simulation of heat and mass transfer during freeze-drying of porous media. Proceedings of the 8th European Drying Conference (EuroDrying 2023)
[10]	Ehrhardt, A.L., Rzepus, H.J., Griehl, C., Broneske, D., & Vorhauer-Huget, N. (2023). Autarkyo: Interactive App for the Planning and Evaluation of Energy Self-Sufficient Houses. EDULEARN23 Proceedings, 1458 – 1467. https://doi.org/10.21125/edulearn.2023.0453

2022

[9]	Aamer, E., Bettenbrock, K., Beyer, L., Dürr, R., Kienle, A., & Vorhauer-Huget, N. (2022). Pore network extraction from simulated biofilms.
[8]	Thomik, M., Briest, L., Vorhauer, N., Gruber, S., Petra, F., Schuchmann, H., & Tsotsas, E. (2022). Evaluation of methods to represent the structure in tomographic images of freeze-dried porous media. Proceedings of the 22nd International Drying Symposium on Drying Technology - IDS '22 https://doi.org/10.55900/ldswiytv
[7]	Vorhauer, N., Tretau, A., Wagner, R., & Tsotsas, E. (2022). Microwave drying of wet clay in pilot-scale plant. Proceedings of the 22nd International Drying Symposium on Drying Technology - IDS '22 https://doi.org/10.55900/pgrnojwt
[6]	Gruber, S., Vorhauer, N., Schulz, M., Xu, X., Hilmer, M., Thomik, M., Tsotsas, E., Schuchmann, H., & Foerst, P. (2022). Experimental investigations on freeze-drying of particulate matter by using neutron imaging. Proceedings of the 22nd International Drying Symposium (IDS 2022) https://doi.org/10.55900/owapnrwq
[5]	Desai, K.S., Seenuvasan, K., Bhaskaran, S., Pandey, D., Bandaru, N., Vorhauer-Huget, N., Tsotsas, E., & Kumar Surasani, V.K. (2022). Comparison of CM and LBM to study multiphase flow in the anodic porous transport layer of PEM water electrolyzer.
[4]	Ehrhardt, A.L., Vorhauer-Huget, N., Rzepus, H.J., & Broneske, D. (2022). Animation of a Forgotten Invention - the Soda Locomotive. EDULEARN22 Proceedings, 2358 – 2364. https://doi.org/10.21125/edulearn.2022.0612

2021

[3]

Vorhauer, N., Mathew, P., Gunasekaran, H., Do, M., Thalakkotoor, S., Jayanand, V., Dhanasekaran, P., Hegde, C., Kochupurakkal, B., & Broneske, D. (2021). 3d Animation of Single Stage Batch Distillation for Distance Learning. EDULEARN21 Proceedings, 476 – 483. https://doi.org/10.21125/edulearn.2021.0146

2020

[2]	Mencke, N., Vondran, M., Vorhauer, N., Nicolas, E., & Tsotsas, E. (2020). VR-Based Knowledge Preservation in Chemical Process Industry. EDULEARN20 Proceedings, 5928 – 5935. https://doi.org/10.21125/edulearn.2020.1548

2018

[1]	Vorhauer, N., Först, P., Schuchmann, H., & Tsotsas, E. (2018). Pore network model of primary freeze drying. Proceedings of the 21st International Drying Symposium (IDS 2018) ocs.editorial.upv.es

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Publications