Research Projects

Tailor-made and quality-assured magnetic materials for efficiency-optimized electric motors.
Overall project "Smart materials and intelligent production technologies for energy-efficient products of the future (SmartPro)" at Aalen University of Applied Sciences.

Project duration

01/2021 - 03/2026

Lead partner, lead entity

• Federal Ministry of Research, Technology and Space (BMFTR)
• VDI Technology Center

Development of amorphous soft magnetic cores for highly efficient transformers.

Project duration

09/2021 - 12/2026

Lead partner, lead entity

• Federal Ministry of Research, Technology and Space (BMFTR)

Innovative joining processes and stress-optimized design concepts for hybrid lightweight CFRP multi-material composites in the overall project "Smart materials and intelligent production technologies for energy-efficient products of the future (SmartPro)" at Aalen University of Applied Sciences.

Project duration

04/2022 - 03/2026

Lead partner, lead entity

• Federal Ministry of Research, Technology and Space (BMFTR)
• VDI Technology Center

Impulse project on the topic of ML in the overall project "Smart materials and intelligent production technologies for energy-efficient products of the future" (SmartPro) at Aalen University of Applied Sciences.

Project duration

04/2022 - 03/2026

Lead partner, lead entity

• Federal Ministry of Research, Technology and Space (BMFTR)
• VDI Technology Center

Creation of a damage catalog as a basis for the rapid tests of the test device for damage and condition analysis.

Project duration

07/2022 - 02/2026

Lead partner, lead entity

• Federal Ministry of Economy, Business and Energy (BMWE)

Digitalization for efficient process selection and design of hybrid structures based on experimental and synthetic data

Project duration

01/2023 - 08/2026

Lead partner, lead entity

• Federal Ministry of Education and Research

Automated process parameter determination for the calendering of electrodes using an additional module for battery cell production.

Project duration

02/2023 - 07/2026

Lead partner, lead entity

• Federal Ministry of Research, Technology and Space (BMFTR)

Adjustment of anisotropic grain structures in CoSm magnets additively manufactured by laser melting.

Project duration

03/2023 - 08/2026

Lead partner, lead entity

• DFG

Process modelling for the optimization of battery cell production

Project duration

03/2023 - 08/2026

Lead partner, lead entity

• Federal Ministry of Economy, Business and Energy (BMWE)

Data-based management of raw material and process influences on the structure and properties of LiB electrode materials.

Project duration

06/2023 - 05/2026

Lead partner, lead entity

• Federal Ministry of Research, Technology and Space (BMFTR)

Concepts for the assessment, rating and use of recycling materials from rare earth magnets and Li-ion batteries (PRESERVE).

Project duration

10/2023 - 09/2027

Lead partner, lead entity

• MWK Baden-Württemberg
• European Regional Development Fund (ERFE)

High-performance anode materials for resource-saving Na-ion batteries based on lignin and hemicellulose from hardwood and softwood waste.

Project duration

04/2024 - 03/2027

Lead partner, lead entity

• Carl Zeiss Foundation

GREENE, short for SINGLE-GRAIN RE-ENGINEERED ND-FE-B PERMANENT MAGNETS, is an EU-funded project focused on pioneering advancements in high-performance permanent magnets, re-engineering their microstructure to make them more powerful while at the same time reducing Rare Earth (RE) content. This approach is applied to both virgin and recycled feedstocks, addressing supply dependency while contributing to a more resilient, circular economy in Europe. Led by the Slovenian Jožef Stefan Institute, the consortium of 15 European partners is tackling the environmental and supply challenges associated with these crucial components of high-tech products that power a green energy future, such as e-vehicles and wind turbines.

Project duration

06/2024 - 05/2028

Lead partner, lead entity

• EU project

Locally reinforced permanent magnets for sustainable and efficient electrical machines.

Project duration

06/2024 - 05/2028

Lead partner, lead entity

• Federal Ministry of Research, Technology and Space (BMFTR)

The mission is to strategically and sustainably increase the research and innovation power of Aalen University of Applied Sciences by linking current developments in artificial intelligence with proven research in the application domains of the research focus areas. The aim is to drive forward the digital transformation and thus contribute to securing the region's competitiveness.

Project duration

11/2024 - 10/2028

Lead partner, lead entity

• Carl Zeiss Foundation

CZS Center for Circular Economy and Resource Efficiency through Additive Manufacturing Technologies.

Project duration

04/2025 - 03/2031

Lead partner, lead entity

• Carl Zeiss Foundation

Hybrid process for the production of superabrasive grinding tools.

Project duration

09/2025 - 08/2027

Lead partner, lead entity

• MWK Baden-Württemberg

Investigations/analyses of dynamic microstructural changes in solid-state batteries using X-ray and operando electron microscopy.

Project duration

09/2025 - 08/2028

Lead partner, lead entity

• MWK Baden-Württemberg

Customized permanent magnets through innovative co-sintering for Net Zero.

Project duration

10/2025 - 09/2028

Lead partner, lead entity

• MWK Baden-Württemberg

Direct recycling of production rejects in electrode production for lithium-ion batteries using laser ablation.

Project duration

10/2025 - 09/2028

Lead partner, lead entity

• MWK Baden-Württemberg

Resource-saving permanent magnets with a high Ce content for sustainable energy converters.

Project duration

01/2026 - 12/2028

Lead partner, lead entity

• DFG

Scaled and resource-saving scrap recycling for industrial battery cell production.

Project duration

01/2026 - 12/2028

Lead partner, lead entity

• Federal Ministry of Research, Technology and Space (BMFTR)

HAW-Forschungspraxis 2024: Innovative electrode architectures and manufacturing processes for solid-state battery cathodes with improved performance and service life.

Project duration

01/2026 - 06/2029

Lead partner, lead entity

• Federal Ministry of Research, Technology and Space (BMFTR)

Multimodal deep learning toolkit for cross-application improvement of image quality in microscopy and optical inspection

Project duration

01/2026 - 09/2027

Lead partner, lead entity

• MWK Baden-Württemberg
• European Regional Development Fund (ERFE)

Research activities focus on Li-ion batteries, particularly for automotive applications.

One special field is the investigation/analysis of the ageing behavior of different material concepts and the elucidation of the specific ageing mechanisms at microstructure level that are responsible for the degradation of the cells ("damage analysis"). In addition to targeted ageing tests and electrical analyses of the cells, changes at microstructure and material level are investigated and correlated with the degradation of the performance characteristics of the batteries. High-resolution imaging methods such as micro-computed tomography, light and electron microscopy and material analysis processes are available.

In this context, the influence of manufacturing defects (e.g. fluctuations in the electrode layer thickness) on the quality and service life of the batteries is also being researched and methods for quality assurance during production are being developed.

Project examples

Investigations/analyses of aged Li-ion batteries using CT and reflected light microscopy

Service life and reliability of Li-ion batteries - degradation mechanisms, accelerated testing, accurate service life predictions
Background:
Lithium-ion batteries (LiB) are valid from today for the storage of electrical Energy in hybrid and electric vehicles. Although there is many years of experience in the field (of) consumer electronics (e.g. laptops), the requirements for Energy and power density and, in particular, the service life and reliability of LiBs for automotive applications are many times higher and are still far from being met. The complex processes that lead to the degradation of the materials and thus to the loss of battery performance are still unsatisfactory understood in order to be able to derive targeted countermeasures.

Project goals:
The project aims to improve the service life and reliability of LiB. Based on the current valid from today's School of Engineering of 3 years service life, a service life of 10 years must be achieved for commercial, economical, profitable, financial, cost-effective use in electric vehicles. The proposed project creates a basis for this. For selected cells, a comprehensive understanding of the relationships between cell materials/design and load profile with measurable drops in performance and material changes on a microscopic level will be developed. With this understanding, aging tests will be improved in terms of predictive power and gathering, and new material analysis methods and service life predictions will be developed with increased accuracy.

Computed tomography and microscopy at LiB for quality assurance

Computed tomography and microscopic processes, procedures for quality assurance of lithium-ion batteries during production
Background:
For the large-scale production of lithium-ion batteries (LiB) for hybrid and electric vehicles, the well-known production technologies for consumer electronics applications have been used up to now due to a lack of proven alternatives. Proven, reliable and cost-optimized production methods for automotive applications are unsatisfactory. The effects of manufacturing deviations (i.e. deviations from specified target values) on the performance and service life of PCBs are largely unknown. In addition, there is a lack of efficient and meaningful processes, procedures to assess the quality of individual manufacturing steps within the complex manufacturing process chain.

Project objectives:
Assessment, rating of the manufacturing quality of different manufacturers at the levels of cell structure and material structure (anode, cathode, separator) using X-ray computed tomography and various microscopic procedures
Identification of parameters that can be used to describe the quality (e.g. uniformity of the electrode layer thickness)
Development of methods to determine these parameters quantitatively, efficiently and automatically.
Investigations/analyses of the influences of various production parameters on production quality.

Stable manufacturing processes for Li-ion batteries: Characterization methods for quality assessment & knowledge-based manufacturing tolerances (Q-LiB).
Background:
Batteries are a key technology for electromobility and industrial applications. Research and development activities are currently focusing on Li-ion and related future technologies. One development goal is to increase cell quality and service life, as the requirements in the new fields of application are much higher than in the familiar field (of) consumer electronics due to the high costs and safety standards.

The quality of the cells is determined 80-90% by the production quality of the electrodes and the jelly roll (electrode winding). During their production, deviations from the defined requirements occur at the "material", "microstructure" and "fine geometry" levels. These significantly impair quality.

There is a lack of meaningful and efficient characterization methods for quality assessment on the different scales. Quantitative correlations between process parameters and production quality are not sufficiently known. Knowledge of the effects of defects and models to describe the interdependencies are largely lacking. This leads to expensive (fear) tolerances.

Contrasting the different phases in electrodes by reactive sputtering for subsequent analyses. a) Differentiation of the plastic binder (gray next to blue graphite grains) in the anode active mass, b) different oxide phases in a blend cathode (picture below: phases segmented for quantitative determination of the proportions)

Project objectives:
The scheme, enterprise, aims to evaluate and further develop materialographic and material-analytical methods with which quality-relevant characteristics on the scales mentioned as well as their influences by the manufacturing process can be assessed, rated. The influence of individual manufacturing process parameters on the quality of electrodes and jelly rolls is to be systematically investigated ("influence variable analysis"). In addition, the effect of discontinuities on the service life of cells is to be investigated by means of limit sample tests. This will make an important contribution to a better understanding of influencing variables and mechanisms of action within the complex production process chain of Li-ion cells, to optimize process parameters and to be able to derive tolerances based on knowledge.

Hard magnetic and soft magnetic materials are playing an increasingly important role in energy conversion. They are of strategic importance for generators in the production of renewable Energy or for electric motors in electrically powered vehicles.

High-performance magnetic materials such as FeNdB magnets are being further developed in various research projects with highly-respected companies and research institutes. In addition, new magnetic phases are being sought that have improved availability of raw materials or more suitable property profiles compared to current materials. Based on this, new and existing physical micromagnetic models are (further) developed. The correlation of the microstructure with the magnetic properties of the materials is indispensable both for the comprehensive understanding of known and new magnetic materials and for their further development to enable optimized and innovative magnetic applications.

Project examples:

Better understanding of the role of grain boundary phases in super-strong FeNdB sintered magnets

Optimization and further development of hard magnetic materials with regard to their application in electric drives
Background:
High-performance rare-earth magnetic materials such as FeNdB are an important key to efficient electrification of the powertrain (hybrid/direct drive). However, the availability and cost situation for these materials is unsatisfactory. With the help of significantly improved permanent magnets, the performance of electric motors can be increased while at the same time optimizing production and raw material costs and dispensing with expensive additives such as dysprosium.

Project goals:
Better understanding of the role of grain boundary phases in super-strong FeNdB sintered magnets with suitable model samples and model experiments for targeted optimization of the performance of modern permanent magnets combined with improved mechanical and thermal stability
Investigations/analyses of the formation process of intermetallic phases in rare earth-transition metal systems
Improvement and tailoring of the magnetic properties of sintered magnets, targeted selection of alloying elements, cost reduction

Efficient search for and characterization of new magnetic phases

Search for new hard magnetic phases with reduced rare earth metal content or free of rare earth metals
Background:
Hard magnetic materials with high energy density and corrosive resistance combined with low costs and high raw material availability are becoming increasingly strategically important. The aim is to replace today's rare earth magnets with new hard magnetic materials that are characterized by a significantly lower proportion of rare earths.

Project goals:
Development of high-throughput methods for the efficient synthesis and analysis of new rare earth-poor or rare earth-free hard magnetic phases
Investigation/analysis of the thermodynamic and kinetic processes involved in the formation of intermetallic phases, taking into account phase relationships and powder metallurgical aspects

The additive manufacturing of complex component geometries offers the industry many other advantages in addition to the creation of new design freedoms. Components that could not be produced using conventional manufacturing methods due to their complicated geometric shape can be manufactured using this layer-by-layer technique. The geometric data required for production is taken directly from existing CAD data and used for production. In addition to conventional mechanical material testing, 3D computed tomography, optical microscopy and electron microscopy are used for the assessment, rating of the powder types and the manufactured component.

Project example
Selective laser sintering for the construction of hard metal components (AddHard for short)
Project partner
Carl Zeiss Industrial Metrology GmbH
H.C. Starck Tungsten GmbH
MAPAL Fabrik für Präzisionswerkzeuge Dr. Kress KG
TRUMPF Laser and systems engineering GmbH
Project goals
Understanding powder requirements for the laser powder bed fusion process (L-PBF)
Effect of influencing variables on the L-PBF process
Relationships between microscopic, mechanical and physical properties of additively manufactured hard metals
Relationships between process parameters and microstructure formation
Findings on thermal post-treatment
Methods for the quantitative characterization of microstructural features

In the field (of) materialography/material analysis, other complementary processes, such as in-situ X-ray diffraction, are used in addition to the standard analytical methods of light and electron microscopy. In addition, 3D computed tomography is used, for example, to enable a connected to buildings and facilities as a basis for further classical investigations/analyses using common microscopic processes, procedures. In addition to targeted routine investigations, damage investigations of structure and functional materials are also carried out. Using a suitable combination of analytical methods (light microscopy, SEM, EDX and 3D computed tomography), the structure of a material or complete component can be investigated.

Another core competence of the working group is the development of image analysis software for new fields of application in the field (of) microscopy. Where appropriate, these image analysis methods are also used to solve problems.

A list of important routine examinations is shown below.

Steel components
Investigations/analyses of complete and/or
edge-hardened components
Assessment of hardness structure
Degree of steel purity according to
DIN 50 602 and EN 10 247
Grain size
Layer thicknesses
Cast/wrought alloys
Graphite formation
Cast structure
Grain size
Recrystallization
Cavity analysis VDG P201
High performance ceramics
Evaluation / Processing
Reinforcement phases
Grain size
Inhomogeneities
Microstructural defects
Fractography
Project examples

Software development for material microscopy

Software development for material microscopy
Background:
A new depth in the field (of) quantitative microstructure analysis is required in materials analysis. Developments in information technology as well as in digital camera technology and microscopy enable new methods and processes up to automated routine testing of microstructure parameters in materials.

Research objectives & areas of application:
Method and software development for automated microstructure analysis
Use of classic reflected light microscopes and scanning electron microscopy as 2D imaging processes, procedures
Alternative applications, e.g. in the pharmaceutical industry and Biotechnology
Poster (2.71 MB)

CT applications

3D computed tomography
Specification v|tome| x s of the company phoenix|x-ray:
2 X-ray tubes (240 kV microfocus and 180 kV nanofocus™)
High-resolution digital detector (1900 x 1500 pixels)
Resolution of up to 1 µm/voxel
Strong phase contrasts
Precise quantitative 3D characterization of difficult-to-pierce construction and functional materials or microcomponents
Extension of the value chain to include reverse engineering and dimensional metrology by integrating CAD, rapid prototyping and FEM simulation
Areas of application CT (7.03 MB)

SensMik ceramic component

FHprofUnt joint project: "Sensory microscopy to improve the reliability and efficient optimization of manufacturing processes of highly stressed powder technology components (SensMik)"
Background:
In order to counter sustained cost pressure, increasing efforts are being made to produce highly stressed components made of high-strength steels (e.g. tip-hardened 100Cr6) and ceramics by powder injection molding (PIM). A major challenge is meeting the reliability requirements: Microstructural defects such as pores and inhomogeneities act as internal defects or weak points that are the starting point for mechanical failure. These microstructural defects must be largely avoided in the manufacturing process and - since they cannot be completely avoided - their effect on the material strength and its scattering must be quantitatively determined. Valid from School of Engineering, the determination of the strength distribution is carried out with great effort by mechanical examination of a few model samples, statistical evaluations and subsequent fractographic analyses.

Project objectives:
The approach pursued in the project aims at the direct determination of strength properties on the basis of microscopically determined, quantitative microstructure parameters such as flaw size and their statistical evaluation on the component. Furthermore, methods are to be developed to assess the formation and development of microstructural defects within the process chain. This will create a basis for the targeted optimization of individual process steps.

The ultimate aim of the project is to develop methods and tools for quantitative microstructure analysis to evaluate the reliability properties of injection-moulded metal and ceramic high-performance materials and to optimize manufacturing processes in a targeted manner.

Poster (2.58 MB)

Time- and temperature-resolved multidimensional X-ray diffraction plot of the heat treatment process to visualize relevant phase transformations of an overhardened 100Cr6 steel

FHprofUnt joint project: "High-temperature X-ray diffraction in real time as a new method for characterizing dynamic phase transformation processes in materials for Energy Management (real-X-diff)"
Background:
X-ray diffraction (XRD) is one of the oldest and most advanced methods for crystalline structure analysis of condensed matter. Until now, such measurements have been very time-consuming and only reflect a static thermodynamic state. Modern detector and furnace technology now allows us to record diffractograms dynamically on a laboratory scale at 0.5s intervals during thermal, chemical or electrochemical treatment. The observation of such highly time-resolved, dynamic phase transformations was previously only possible with synchrotron radiation in a particle accelerator.

The in-situ XRD system at the Department, Institute of Materials Research (IMFAA) at HTW Aalen is the first laboratory system in the world with such thermal and temporal capabilities.

In-situ XRD X-ray diffraction for the elucidation of age-related crystallographic changes of differently aged cathode active materials in lithium-ion batteries

Project goals:
The aim of the project is to find new materials and process technologies for Energy Management and electromobility or to improve the properties of existing ones with the help of improved real-time processes, procedures for X-ray characterization. To this end, the kinetics of dynamic phase transformation processes and the formation of residual stresses as a function of temperature, time and atmosphere are to be fundamentally investigated and understood. A second goal is to further develop and verify this real-time process, procedure. Investigations/analyses on accuracy and resolution will also be carried out in direct comparison with differential thermal analysis (DTA). Energy-dispersive synchrotron radiation analysis will be used as a further reference method. The final goal at the end of project is to develop a reliable and robust experimental setup that enables such real-time experiments in a simple X-ray laboratory, also under industrial application aspects. The diffraction pattern will be determined on a second scale, which will make it possible, for example, to investigate very fast temperature-driven phase transformations (e.g. also for the important construction material steel) under real process conditions.