Moore’s law has enabled the $4 trillion worldwide IT industry to nearly double the performance and functionality of digital electronics roughly every two years within a fixed cost and area. However, the International Semiconductor Technology Blueprint (ITRS) predicts that the technological underpinnings for Moore’s law will end by 2025. IRTS points out that two-dimensional (2D) materials will bring new opportunities for the Post-Moore Era, especially for the CMOS technology beyond 5 nm node. However, very few 2D materials based electronic products are available commercially over the decades of study. With the scaling-down of the electronic devices, it is urgent for academia and industry to seek ways to integrate 2D materials in practical and commercial electronic devices. Introducing 2D materials in the structure of commercial electronic devices is challenging due to their complex synthesis and manipulation. The 2D-HETERO project will explore large wafer-scale (from 2-inch to 300 mm) and uniform growth of different 2D materials by chemical vapor deposition (CVD) method. Van der Waals heterostructures based on different 2D materials will be developed by stacking 2D materials through the direct growth or through clean and large wafer-scale transfer methods. The developed high quality and wafer-scale van der Waals heterostructures will be integrated in different nanoelectronics (mainly field effect transistors), with the goal of enhancing the device performance, yield and uniformity. Using an interdisciplinary approach that combines materials science, physics, electrical engineering, industry-relevant nanofabrication and characterization, 2D-HETERO will pave the way to industrialize 2D materials based nanoelectronics. The combination of learning through research and a comprehensive training plan, including both scientific and technological as well as soft skills, will strongly enhance the profile of the applicant and provide a boost for her future scientific career.

Fluorescent microscopy is an indispensable tool in biology and medicine that has fueled many breakthroughs in a wide set of sub-domains. Recently the world of microscopy has witnessed a true revolution in terms of increased resolution of fluorescent imaging techniques. To break the intrinsic diffraction limit of the conventional microscope, several advanced super-resolution techniques were developed, some of which have even been awarded with the Nobel Prize in 2014. High resolution microscopy is also responsible for the spectacular cost reduction of DNA sequencing during the last decade. Yet, these techniques remain largely locked-up in specialized laboratories as they require bulky, expensive instrumentation and highly skilled operators. The next big push in microscopy with a large societal impact will come from extremely compact and robust optical systems that will make high-resolution (fluorescence) microscopy highly accessible, enabling both cellular diagnostics at the point of care and the development of compact, cost-effective DNA sequencing instruments, facilitating early diagnosis of cancer and other genomic disorders. IROCSIM will facilitate this next breakthrough by introducing a novel high-resolution imaging platform based entirely on an intimate marriage of active on-chip photonics and CMOS image sensors. This concept will completely eliminate the necessity of standard free-space optical components by integrating specially designed structured optical illumination, illumination modulation, an excitation filter and an image sensor in a single chip. The resulting platform will enable high resolution, fast, robust, zero-maintenance, and inexpensive microscopy with applications reaching from cellomics to DNA sequencing, proteomics, and highly parallelized optical biosensors.

Soft electronic devices are indispensable for the development of artificial skin due to their high stretchability and sensing functionality. Conventionally, to mimic touch and temperature sensing of mechanoreceptors and thermoreceptors, compliant structural design accompanied with signal transduction mechanism such as piezoresistive, capacitive, piezoelectric, pyroelectric sensing have been utilized so far. The design of these pressure sensors requires highly flexible and robust electrical properties of materials as active and supporting components. In addition, strategically engineered micro-structure is employed to enhance the sensing performance. In this spirit, flexoelectric material, which relates strain-gradient and electrical polarization, emerges as a naturally suitable candidates for flexible pressure sensors. The strain-gradient-induced polarization does not only distinguish flexoelectricity from the commonly used piezoelectricity but also widen the choice of electro-mechanical coupling materials, especially lead-free and bio-compatible materials that are crucial for the development of biomedical devices. Furthermore, flexoelectric effect exhibits size-dependent behavior, particularly at sub-micron- and nano-scale so that proper design of micro-structure can open an opportunity to a new type of pressure sensor. Therefore, this project aims to propose a novel design for electronic skin (e-skin) based on flexoelectric effect. Specifically, a comprehensive virtual design framework including simulation, characterization and experimental testing of flexoelectric-based sensor will be employed to evaluate key parameters such as sensitivity, limit of detection, linearity, response time and power consumption.

The project proposes to convert solar energy into hydrogen fuel by utilizing a thermoelectric integrated tandem photoelectrochemical (PEC) system with the main goal of generating a robust, scalable, and competitive solution of solar energy technologies. The project will focus on materials development, rigorous characterization, cell development, and prototyping. We will utilize solution-based techniques to address the urgent need for efficient absorbers for PEC systems via transferable methods for large scale production. We will target cost-effective and abundant materials for all required components without sacrificing their performance. Our proposed system will be the first work on solar driven-overall water splitting utilizing solution processing routes with benign molecular ink for photoabsorber synthesis coupled with earth-abundant and low-cost material cocatalysts. Furthermore, rigorous in-situ characterization will provide an overview of the overall processes involved in PEC reactions which will further guide system design. Finally, a prototype of an efficient and durable PEC cell will be realized.

The availability of a tunable laser source in the visible and near-infrared (NIR) range is crucial for a variety of high-impact applications, such as frequency-modulated continuous wave LiDAR, optical coherence tomography, quantum photonics, and molecular spectroscopy. Despite the demand, current solutions for tunable lasers in these wavelength ranges remain limited, both in terms of availability and performance. Metal halide perovskite thin films are emerging as highly promising materials for such applications due to their exceptional optical properties, ease of processing, and compatibility with a wide range of substrates and photonic platforms. In PEROTUNE, we aim to demonstrate a mode-hop free (MHF) tunable laser by leveraging the unique properties of perovskite materials combined with innovative design strategies to enable continuous tuning without mode hopping. This approach capitalizes on the tunability and high optical gain of perovskites in the visible/NIR spectrum, addressing current limitations in laser source technology. By adopting advanced integration techniques, the proposed design will deliver compact, efficient, and versatile laser sources suitable for a wide range of applications. In particular, this breakthrough innovation has the potential to impact fields ranging from medical diagnostics and environmental monitoring to advanced manufacturing and telecommunications, opening new doors for next generation photonic devices