The CHemPGM project is a joint initiative of 7 expert organizations from the fields of chemistry, engineering, mining, metallurgy and materials science, designed to conduct fundamental research regarding the chemistry of platinum group metals (PGMs) and utilize the obtained knowledge to improve and secure the PGMs value chain. Specifically, the project aims i) to establish fundamental knowledge regarding the chemistry of the PGMs, their reactions and complexation with other metals and chemical compounds, and the corresponding reactivities during leaching, separation and recovery processes; ii) to gain a complete understanding of the mechanisms associated with the above-mentioned processes, during the utilization of secondary materials to extract PGMs and incorporate them into new materials and processes such as nanomaterials, catalysis and CO2 capture; iii) to create knowledge, provide expertise and educate the public. This will lead to the upgrading of existing processes and the development of new ones, aligned with sustainable principles, to ensure a circular operation model of the relevant industries. Through the involvement of universities, RTOs and SMEs, CHemPGM is backed by a well-rounded team, with multiyear expertise in the relevant fields, capable to deliver high-quality results regarding the project objectives. The consortium approaches the challenge from a multidiscipline aspect and proposes a balanced number of secondments alongside trainings, workshops, seminars and events that guarantee a cross-sectorial synergy among them. As a result, CHemPGM will broaden the expertise of the organizations, contribute to the advancement of the secondees and enhance the potential for innovation to its stakeholders and those inter-related with it. Overall, the methodology for carrying out the tasks involved, guarantees the smooth running of the project and the successful fulfillment of the objectives to contribute towards a more efficient and sustainable future.

The aim of this project to investigate the role(s) of mTORC2 in mRNA translation and cellular metabolism, in the context of lung cancer development. This work will be carried out in the laboratory of Dr. Pierre Close, at the GIGA-Uliège, who made seminal discoveries in the field of translation regulation and cancer biology. This ambitious project will bring an opportunistic synergy between the expertise in cancer metabolism of the researcher, Dr. Blomme, and the knowhow in translation regulation of the host laboratory. In addition, the project relies on the combination of cutting-edge unbiased “omics” approaches and involves the characterisation of unique mouse models recently generated in the host lab. It is further supported by four high-profile international collaborations that will provide essential technical expertise in metabolomics and lipidomics, and support the clinical aspects of the proposal. As part of an interdisciplinary training, Dr. Blomme will carry out a secondment in the translational research group of Prof. Vooijs, at Maastricht University, in order to learn ex-vivo organoid models of lung cancer. The proposed project addresses fundamental questions of cell biology in a highly clinically relevant context. As such, it holds the potential to result in the design of future anticancer therapeutic strategies. Indeed, the mTORC2 pathway is very often dysregulated in lung cancer. Therefore, by deciphering the molecular mechanisms that sustain mTORC2-dependent metabolism, this work will provide innovative strategies to target mTORC2 signalling in lung cancer.

The ENIGMA network will train a new generation of young researchers in the development of innovative sensors, field survey techniques and inverse modelling approaches. This will enhance our ability to understand and monitor dynamic subsurface processes that are key to the protection and sustainable use of water resources. ENIGMA focuses mainly on critical zone observation, but the anticipated technological developments and scientific findings will also contribute to monitor and model the environmental footprint of an increasing range of subsurface activities, including large-scale water abstraction and storage, enhanced geothermal systems and subsurface waste and carbon storage. While many subsurface structure imaging methods are now mature and broadly used in research and practice, our ability to resolve and monitor subsurface fluxes and processes, including solute transport, heat transfer and biochemical reactions, is much more limited. The shift from classical structure characterization to dynamic process imaging, driven by ENIGMA, will require the development of multi-scale hydrogeophysical methods with adequate sensitivity, spatial and temporal resolution, and novel inverse modelling concepts. For this, ENIGMA will gather (i) world-leading academic teams and emerging companies that develop innovative sensors and hydrogeophysical inversion methods, (ii) experts in subsurface process upscaling and modelling, and (iii) highly instrumented field infrastructures for in-situ experimentation and validation. ENIGMA will thus create a creative and entrepreneurial environment for trainees to develop integrated approaches to water management with interdisciplinary field-sensing methods and novel modelling techniques. ENIGMA will foster EU and international cooperation in the water area by creating new links between hydrogeological observatories, academic research groups, innovative industries and water managers for high-level scientific and professional training.

The WeForming project aims to change the paradigm of efficiently managing energy in buildings, paying special attention to their interaction with the energy ecosystem (energy networks and markets) by developing, deploying and demonstrating innovative solutions addressing (i) digital operation, management and maintenance and (ii) efficient and interactive energy processing for Intelligent Grid-interactive Efficient Buildings (iGEBs), able to operate intelligently in a multi-energy, multi-user, multi-sector, multi-market, and multi-objective environment, without forgetting quality, comfort, health and acceptation. The WeForming Framework will deploy an umbrella framework covering all aspects around the establishment and adoption of iGEBs in cities, which consists of (i) a Building Operational Pillar encompassing all assets of iGEBs, including the energy management systems and the different platforms, aiming towards the building operational optimization, the actors and the actual flexibility resources, generation and storage components; (ii) a novel Interoperability Assurance Pillar which leverages on, adapts, evolves, and specifically validates leading-edge interoperable architectures; (iii) a Business Pillar including all necessary processes to bring the proposed solutions to the market, through the design and validation of sustainable and competitive business models, ensuring the economic viability of the investments needed for the establishment of smart cities featuring new and refurbished iGEBs; (iv) a Smart-city enabling Pillar integrating iGEBs as modular units addressing all different non-technical barriers and limitations for the widespread deployment of the proposed solutions that will create a stock of active buildings acting as active utility nodes within cities.

As the ‘social’ in social sciences is rethought beyond the human, multispecies research across disciplines increasingly asks how to speak with and for non-human others. I pose that intuitive interspecies communication (IIC), a strategy practiced by successful animal communicators to engage in explicit, detailed, two-way communication with non-human animals, holds uncharted resources for doing research with rather than on animals. Research on IIC has been curtailed to specific domains and mythologized, while the worldwide boom in professional animal communicators has been ignored. ANICOM’s unique engagement with animal communicators’ practical strategies for relating across nature/culture and mind/body dichotomies is ground-breaking in the often largely theoretical discussions of the ontological and species turns. It simultaneously unsettles continued divides between humans and animals as well as dominant and subjugated ways of knowing. The project triangulates participant observation, Q method, interviews and audio-visual methods (including video-diaries and video-elicitations) with natural science approaches, to collaboratively work with six expert animal communicators and a variety of animals in Europe and Africa. It addresses unexplored possibilities for cross-fertilization between new materialism and posthumanism on the one hand, and Indigenous studies and knowledge systems on the other, while relying on the latest insights in biosemiotics and animal cognition. It thus develops transdisciplinary innovations that include non-human animals as full research participants, while achieving a deeper reflexivity on the limitations of humans thinking animals outside the human-animal relationship. It’s ultimate objective is to establish the resources and foundation for dialogic multispecies methods (DMM), a dynamic set of conceptual, theoretical and methodological approaches and tools to engage with the views, experiences and knowledges of non-human animals in academia.