Human Rights Justifications (HRJ) are when States use human rights to justify decisions. Human rights regimes operate on the presumptions that only individual persons can be in possession of human rights. The regulatory gaps occurring when the States use HRJ for their actions are two-fold, one in the regulation of the States’ use of HRJ and one in the individual human rights protection when States use HRJ. This activity is not regulated by any international, regional or national regime. In other words, significant and important gaps in human rights regulations has now been identified, which this project seeks to address. We will develop a theory of HRJ and a process for Systematic Ongoing Civil Society Engagement (ODCSE) as a tool for a gender and intersectional inclusive Civil Society engagement. Through ODCSE, we will identify gaps in human rights regulations and protection, serving as underpinning data for our recommendations to EU in support of a multinational human rights system and promotion of transnational democratic governance. ODCSE will also help us identify geopolitical elements that influence States’ use of HRJ. This will be done through 5 countries: Sweden, Finland, Taiwan, India and Ukraine, through three actions: human rights dialogue, inclusive democratic participations, and protection of human rights defenders, and operationalised through three themes: Covid, Migration and Climate.

The project aims at the design and realization of a new analytical platform implementing a series of innovative technologies able to provide a highly-integrated solution for the analysis in-situ of the effects of the space environment on model biological systems and for the evaluation of shielding technologies combined with radioprotective agents. The main objective of the project will be achieved through the development of a lab-on-chip device with integrated thin-film sensors and actuators that will implement an extremely compact cell-incubator capable to sample the status of the cell culture during a space mission using real-time monitoring techniques based on bioluminescence. Genetically modified microorganisms will be designed in order to monitor specific stress responses based on a luciferase-based reporter system. An electronic system will be integrated in the platform for the characterization of the radiation environment allowing to evaluate the correlation between observed biological effects and radiation exposure. The main features of the proposed technology include low power consumption, extreme compactness, high data efficiency and full automation making it suitable for cubesat missions. In particular, a complete cubesat payload will be designed to address and solve any integration issue and to provide a test bench for a preliminary set of experiments to be carried out on ground facilities simulating the deep space environment. The proposed system will therefore represent a key element to pave the route toward deep space human mission as it offers the possibility to test the effects of long term exposure to the space environment on model biological systems using simple platforms as cubesats. This opens new scenarios where minor effort will be required to plan multiple low-cost missions for improving the risk modeling and for testing new countermeasures in a continuous-improvement scheme.

The peculiar behaviour of liquid and supercooled water has been baffling science for at least 236 years and is still seen as a major challenge facing chemistry today (Whitesides & Deutch, Nature 469, 21 (2011)). It was suggested that such strange behaviour might be caused by thermodynamic transitions, possibly even a second critical point. This second critical point would terminate a coexistence line between low- and high-density amorphous phases of water. Unfortunately, this second critical point (if it exists) and the associated polyamorphic liquid-liquid transition is difficult to study as it is thought to lie below the homogeneous nucleation temperature in a region known as "no man's land" (Angell, Science 319, 582 (2008)). In recent preliminary femtosecond optical Kerr-effect spectroscopy experiments, we have shown that water in concentrated eutectic solutions forms nanometre scale pools in which it retains many if not most of its bulk liquid characteristics. Most importantly, such solutions can be cooled to below 200 K without crystallisation (typically forming a glass at lower temperatures) allowing one to explore "no man's land" in detail for the first time. Preliminary experiments combining femtosecond spectroscopy with NMR diffusion measurements have shown that water in these pools undergoes a liquid-liquid transition as predicted for bulk water. Hence, it is proposed to use such nanopools as nanometre scale laboratories for the study of liquid and glassy water. A wide-ranging international collaboration has been set up to be able to study different critical aspects of the structure and dynamics of water. This includes cryogenic viscosity measurements, large dynamic-range (femtosecond to millisecond) optical Kerr-effect experiments, pulsed field gradient NMR, dielectric relaxation spectroscopy, terahertz time-domain spectroscopy, infrared pump-probe spectroscopy, and two-dimensional infrared spectroscopy. To ensure maximum impact of the experimental work, it is critical to have strong ties with experts in the theory and simulation of water and its thermodynamic behaviour. We have arranged collaboration with two international theory groups covering different aspects of the proposed work. Although the proposed research is relatively fundamental in nature, it will have impact as described in more detail elsewhere. The research addresses EPSRC priorities in nanoscience (supramolecular structures in liquids), energy (proton transport and liquid structuring in electrolytes for batteries and fuel cells), life sciences (the role of water in and on biomolecules), and the chemistry-chemical engineering interface (the role of the structuring of water in crystal nucleation). Our strong links with theory collaborators will ensure that fundamental insights will indeed propagate to the 'users' of such information. The close working relationship between the PI and CI has made Glasgow a centre of excellence in advanced femtosecond spectroscopy. This project exploits this expertise and international collaborations to immerse PDRAs and PGRSs in internationally leading research using state-of-the-art previously funded equipment.