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Supervisor: Dennis Arigbe

Research field: Nanoporous Material

Work type: Experimental

Available for: HiWi, Bachelor Thesis, Master Thesis

Start date: Flexible

Project brief:

For optimizing the supercritical drying of aerogels, it is crucial to understand the drying kinetics, especially on a larger scale. A new large-scale plant is installed in the technical hall to measure this. One important property that needs to be monitored therefore is the development of the CO2/solvent mixture composition throughout the entire drying process at various measuring points. Raman spectroscopy is used as the analysis tool, because it has several advantages, like a low measure volume. 

To get reliable composition results, a very important step is to calibrate the measuring setup properly. For the parameters like pressure, temperature and mixture composition in the expected regions, different measuring points need to be evaluated and measured. After postprocessing of the arising data, the calibration results need to be regressed with a suitable model.

Objectives:

• Measuring the Raman signals at different Parameters
• Postprocessing of the data
• Regression of the experimental data
• Validation of the regression model

Supervisor: Lara Gibowsky

Research field: Nanoporous Material

Work type: Experimental

Available for: Master Thesis

Start date: Flexible

Project brief:

(Biopolymer-based) aerogels are lightweight solid materials, which are particularly suitable for applications as insulation material but also in the food and pharmaceutical industries due to their low density, high porosity and specific surface area. They have a very fine, air-filled pore structure, the properties of which are decisive for their subsequent use. 

Despite the high relevance, the manufacturing process, which consists of the three steps gelation, solvent exchange and supercritical drying, still represents a cost and time challenge for the application in the industry. In order to be able to implement larger aerogel quantities in production, this often takes place in packed beds. However, this causes the disadvantage of mechanical stress on the gel particles due to their own weight as well as external forces such as pressure loss across the packed bed. In extreme cases, this stress can lead to plastic deformation of the gel particles, resulting in irreversible damage to the microstructure, loss of the characteristic properties and increased pressure drops across the packed bed. 

The correlation between the process parameters of the solvent exchange and the mechanical and microstructural properties of the gel particles has not yet been clarified.

Objectives:

• Investigation of solvent exchange and supercritical drying in packed bed systems
• Investigation of the influence of process parameters (solvent concentration, flow rate, etc.) on deformation mechanisms of soft gels in packed beds
• Production and screening of different gel systems (various biopolymers and particle sizes)
• Analyzing the microstructure and deformation of the final aerogels
• Analyzing the correlations to identify the critical states in the manufacturing process

Supervisor: Alberto Bueno

Research field: Nanoporous Material

Work type: Experimental and Theoretical

Available for: Master Thesis

Start date: Flexible

Project brief:

In order to produce nanoporous solid materials such as aerogels it is required to dry a wet gel without disrupting the porous structure of it. Different drying techniques such as freeze drying have been developed in order to preserve the nanoporous structure. Supercritical CO₂ (scCO₂) drying has been proven to be a universal drying technique and gives the best results to produce aerogels. The misconception that scCO₂ drying is an expensive and time-consuming technique has limited this technique to just the lab scale.

Recently, it has been proven that scCO₂ drying is feasible at an industrial scale and can compete with standard drying techniques. To further attract industrial attention, better analytical tools which allow a better measurement of the drying kinetics are necessary. Measuring the scCO₂ drying kinetics has proven a challenge since the density and viscosity of the bulk fluid are changing constantly during the process.

In order to determine the real drying kinetics from the experimental data, it is required to develop mathematical algorithms which correlate the system flow dynamics with the data obtained during the drying experiments. The corrected data obtained can be applied in mathematical models in order to optimize the whole process.

Objectives:

• Non-steady state residence time distributions are to be determined and fitted to RTD models.
• A deconvolution algorithm is used to recover the real kinetics which are going to be used to evaluate a mathematical model describing the process.
• Determination of RTD distribution at different conditions of temperature, pressure and CO₂/solvent compositions.
• Effect of the internal geometry of the autoclave in the drying kinetics.
• Development of a deconvolution algorithm in Python.
• Further development of a mathematical model which represents the process (Python).

Supervisor: Razan Altarabeen

Research field: Nanoporous Material

Work type: Experimental

Available for: Project Work

Start date: Flexible

Project brief:

One of the common approaches towards green energy is reduction of CO₂ emissions. Electricity and Heating of households generate high percentage of CO₂ and an amount of this heat is lost when conventional insulation materials are used.

Innovative insulation materials can reduce the required heating power by minimizing heat losses and thus reduce CO₂ emissions. One potential solution is the use of Aerogels which are highly porous lightweight materials (up to 99% air).

Lignin, the most second abundant carbon source which is found in the plant wall can be used as a bio-polyol to synthesize bio-based PU Aerogels. The aim of this project is to incorporate lignin in PU Hydrogels via sol gel process followed by supercritical CO₂ drying to obtain lignin-PU aerogels.

The methods used in this project include the sol-gel gelation process for hydrogel formation, supercritical CO₂ drying to preserve the porous structure, BET measurements for surface area analysis, SEM for morphological characterization, and thermal conductivity determination using the Hot Disk method.

Objectives:

• Solubility measurement of lignin in different solvent mixtures.
• Optimization of the aerogels density
• Evaluation of the crosslinking of lignin in the lignin-PU aerogels.
• Supercritical CO₂ drying of the aerogels
• Characterization of the lignin-aerogel in regard to their mechanical and thermal properties

Supervisor: Razan Altarabeen

Research field: Nanoporous Material

Work type: Experimental

Available for: Project Work

Start date: Flexible

Project brief:

Biopolymer aerogels, such as alginate aerogels, are nanoporous ultralight materials with high biocompatibility, which enables them to be tailored for various applications such as tissue engineering and drug delivery systems. One major challenge is their porous structure, which is prone to damage and collapse when subjected to moisture due to the surface’s hydrophilicity.

Coating can be used to prevent the penetration of moisture, thus reducing the shrinkage of aerogels. However, conventional coating strategies often involve synthetic chemicals and complex processes. Preliminary results showed lignin’s potential as a biopolymer additive for the coating of alginate aerogel particles.

In this project, the main focus is the investigation of the lignin-alginate interaction, the study of the gelation mechanism, and the analysis of the coating layer’s thickness and homogeneity.

The methods used include BET measurements for surface area analysis, SEM for morphological characterization, FTIR spectroscopy for structural analysis, and CamSizer for particle size distribution analysis.

Objectives:

• Lignin Alginate aerogel particles formation via dripping method.
• Evaluation of lignin’s influence on crosslinking and shrinkage behaviour of alginate particles.
• Drying of the hydrogel particles via supercritical CO2 drying.
• Characterization of the lignin coating layer and surface characteristics

Supervisor: Dr. Vasilii Korotenko

Research field: Nanoporous Material, Molecular Methods for Separation Processes

Work type: Theoretical, Computational

Available for: Bachelor Thesis, Master Thesis

Start date: Flexible

Project brief:

Polymer materials in solution exhibit complex behavior that depends on solvent interactions, external stimuli (temperature, pH, electric field), and processing conditions. Some polymer networks show adaptive, memory-like responses and can even mimic neural networks under electric fields. Understanding and predicting these effects is critical for applications in biomedicine, flexible electronics, and soft robotics.

This research explores how molecular-level interactions determine macroscopic properties such as porosity, swelling, elasticity, and phase behavior. Students will apply a range of computational methods depending on the focus of their thesis. All topics combine theory, simulation, and modern data analysis in collaboration with experimental partners.

Available Thesis Topics

1. Quantum Mechanical Modeling of Non-Covalent Interactions (QM)

• Focus: Study of hydrogen bonding, dispersion, and electrostatic interactions in gel-forming monomers using density functional theory (DFT).
• Tools: ORCA, Psi4, Multiwfn, Python.
• Skills gained: Quantum chemistry, potential energy surface analysis, data extraction for ML potentials.

2. Molecular Dynamics Simulation of Gel Formation (MD)

• Focus: Atomistic modeling of polymer-solvent systems to study gelation, swelling, and network reorganization.
• Tools: LAMMPS, VMD, Python, Packmol.
• Skills gained: Simulation setup and analysis, trajectory interpretation, RDF and diffusion analysis.

3. Coarse-Grained Modeling of Polymer Networks (CG)

• Focus: Large-scale modeling of fibrils, pores, and mesoscale dynamics using DPD or MARTINI models.
• Tools: LAMMPS, HOOMD-blue, custom Python scripts.
• Skills gained: Mesoscale simulation, force field tuning, model validation.

4. Finite Element Simulation of Macroscopic Behavior (FEM)

• Focus: Modeling elasticity, swelling, and poroelasticity based on inputs from MD and CG simulations.
• Tools: COMSOL Multiphysics, FEniCS, MATLAB.
• Skills gained: FEM model building, coupling of simulation scales, transport modeling.

5. Machine Learning for Property Prediction (ML)

• Focus: Surrogate modeling of structure–property relations, prediction of gel behavior, and ML force field development.
• Tools: Python (scikit-learn, PyTorch, XGBoost), pandas, FastAPI.
• Skills gained: ML model training, feature engineering, integration with simulation and literature data.

Supervisor: Alberto Bueno Morales

Research field: Nanoporous Material

Work type: Experimental

Available for: Bachelor Thesis, Master Thesis

Start date: Flexible

Project brief:

Cellulose is one of the most abundant polymers on earth which is readily available from many sources including waste streams from many processes. The upcycling of this streams into a high performance product which will in turn increase the thermal efficiency of processes, building etc. will have a huge impact on the near future. By taking advantage of the cellulose properties together with the amazing attributes that aerogels can bring, the development of a high performance thermal insulation that outperforms any commercial available thermal insulation can be achieved.

Objectives:

• Screening of different reaction conditions.
• Screening of different gelation baths.
• Screening of different post-processing step.

Supervisor: Alberto Bueno Morales

Research field: Nanoporous Material

Work type: Experimental

Available for: Master Thesis

Start date: Flexible

Project brief:

The production of green aerogels consumes large quantities of ethanol. To develop an efficient and cost effective aerogel production process the energy required to recover the ethanol streams should be reduced to a minimum. During this master thesis the student will have the opportunity to develop an innovative adsorption process for the dehydration of an ethanol stream. Using a mixture of experiments and modelling the optimal process architecture and parameters are going to be derived

Objectives:

• The aim of this project is to design a high efficient and low-energy ethanol dehydration process.
• Determination of RTD distribution at different conditions.
• Evaluation of kinetics and thermodynamic equilibrium using dynamic adsorption experiments.
• Development and evaluation of an energy efficient regeneration procedure
• Modeling of the process at different levels using a combination of Python, Comsol and Flowsheeting simulations.
• Proposal of a scaled-up process.

Supervisor: Erik Manke

Research field: Nanoporous Material

Work type: Experimental

Available for: Hiwi, Bachelor Thesis, Master Thesis

Start date: Flexible

Project brief:

So far, supercritical drying of Aerogels is carried out in time-consuming batch processes, which are energy and cost-inefficient. A more efficient approach is the continuous supercritical drying of wet gel particles. A deeper understanding of the system needs to be developed to improve the process and make it even more efficient. Crucial for a successful drying is the residence time of the particles in the column, which needs to be longer than the drying time on the one hand. But short enough to provide an efficient process on the other hand. Many parameters influence the residence time, e.g. the process parameters like pressure, temperature, CO2 flow, or particle flow. Additionally, particle parameters like density, porosity and particle diameter play a major role. Two view cells at the top and bottom of the column are installed to determine the residence time. With the help of fluorescent particles, which are used as tracers and a python program to track those particles, the residence time can be experimentally determined.

Objectives:

• The aim of this work is to experimentally determine the residence time for different particle sizes and various Process Parameters.
• Screening of different particle Parameters
• Screening of different Process Parameters
• Screening of different post Processing steps

Supervisor: Kathrin Marina Eckert

Research field: Nanoporous Material

Work type: Experimental

Available for: Hiwi, Project Work, Bachelor Thesis, Master Thesis

Start date: Flexible

Project brief:

Stimuli-responsive gels undergo significant but reversible configurational changes caused by external influences. Solvent uptake leads to expansion of the polymer chains and the gel swells, while suppression of the solvent out of the polymer matrix leads to shrinkage of the gel.

The conformational change of the gels takes place as a response to external stimuli, such as changes in temperature or the solvent composition in the bulk phase. This characteristic behavior offers a wide range of applications, however, due to the insufficient understanding of the special swelling behavior of the gels, the final application of stimuli-responsive gels in various (separation) processes has so far only been established in a few areas.

Objectives:

• Analysis of structural changes of gels during solvent exchange
• Synthesis of the gels and analysis of swelling degrees
• Analysis of gel structure using different analytical methods (FT-IR, NMR spectroscopy, optical coherence tomography (OCT), visual analysis of macroscopic swelling state)
• Analysis of changing stiffness in distinct solvents

Supervisors: Kathrin Marina Eckert and Patrick Kißling (mail & phone)

Research field: Nanoporous Material

Work type: Experimental

Available for: Bachelor Thesis, Master Thesis

Start date: Flexible

Project brief:

Stimuli-responsive gels undergo significant but reversible configurational changes caused by external influences. Solvent uptake leads to expansion of the polymer chains and the gel swells, while suppression of the solvent out of the polymer matrix leads to shrinkage of the gel.

The conformational change of the gels takes place as a response to external stimuli, such as changes in temperature or the solvent composition in the bulk phase. This characteristic behaviour offers a wide range of applications, however, due to the insufficient understanding of the special swelling behaviour of the gels, the final application of stimuli-responsive gels in various (separation) processes has so far only been established in a few areas.

Due to their chemical inertia and high temperature stability, carbon nano tubes (CNTs) along with ceramics, are widely used as support materials for catalysts in heterogeneous catalysis. In order to further develop heterogeneous catalysis, renewable raw materials shall be implemented as educts, but these have varying quality. To conserve the catalyst, it must be protected e.g. by an electro-responsive polymer.

Objectives:

• Analysis of structural changes of gels due to electro response
  • Synthesis of the gels used and analysis of swelling degrees
  • Examination of the gel structure using different analytical methods
  • Strength measurements of the gels produced during electrical response <=> setup development
• Membrane production from the electro-responsive polymers
  • Setup development for diffusion tests during electrical response
  • Layer thickness optimization
• Analysis of changes in wetting behaviour of CNTs in various polymer gels
  • Embedding commercial CNTs in various polymer gels
  • Coating of commercial CNTs in various polymer gels
  • Examination of the gel structure using different analytical methods
  • Strength measurements of the gels produced during electrical response <=> setup development