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of excitonic many-particle states in novel two-dimensional materials coupled to THz radiation: spectroscopic investigations of two-dimensional semiconductors, measurements and analysis using linear and non
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focuses on advanced materials, innovative methodologies, and transformative solutions that address today’s most pressing challenges in the fields of energy transition and environmental sustainability
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, or for biomagnetic applications or to create new magnetic materials for environmentally friendly energy technologies. Project description The study and exploration of two-dimensional (2D) quantum materials, such as
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of numerical modelling and the validation of numerical results by an experimental study on material level. Firstly, the development of hydration processes including the carbonated matrix in three-dimensional
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boron nitride is a new two-dimensional optoelectronic material that is beginning to play an important role in prototypes for next-generation optoelectronic and electronic devices. As it is produced in a
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develop new theoretical frameworks to understand the root causes of active morphing in two-dimensional membrane-like structures and to explore strategies for achieving desired shapes. A key aspect of the
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characterization, and optical characterization. These may be applied and adapted to a variety of different material classes, including the traditional semiconductors, two-dimensional layered materials as
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, and contextual dependencies and correlations. In contrast, the field of visual analytics focuses on developing tools and techniques to support the interpretation of complex, multi-dimensional data. It
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this collaborative project, we will develop a comprehensive strategy combining (1) vasculature-on-chip models, (2) in-depth nanobubble characterization, and (3) tailored imaging solutions to advance cancer diagnostics
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) active in the fields of materials, environment, and IT. By transforming scientific knowledge into technologies, smart data, and tools, LIST empowers citizens in their choices, public authorities in