NEMOSHIP ambition is to contribute to the European Partnership “Zero Emission Waterborne Transport (ZEWT)” objectives by providing new deployable technological solutions needed for all main types of waterborne transport to reach a “net zero emission” by 2050. To reach this goal, NEMOSHIP will: - develop (i) a modular and standardised battery energy storage solution enabling to exploit heterogeneous storage units and (ii) a cloud-based digital platform enabling a data-driven optimal and safe exploitation, - demonstrate these innovations at TRL 7 maturity for hybrid ships and their adaptability for full-electric ships thanks to: (i) a retrofitted hybrid offshore vessel (hybrid diesel/electric after NEMOSHIP BESS installation), (ii) a newly designed hybrid cruise vessel (LNG/electric propulsion) and (iii) a semi-virtual demonstration for two additional full-electric vessels such as ferries and short-sea shipping. All results will be built upon a treasure chest of 18 years of ESS operation data. Thanks to a very ambitious exploitation plan, accompanied by very large dissemination actions, the NEMOSHIP consortium estimates that these innovations will reach the following impacts by 2030: (i) electrification of about 7% of the EU fleet; (ii) generate a potential revenue of €300M thanks to the sales of the NEMOSHIP products and services; (iii) reduce EU maritime GHG emissions by 30% compared to business as usual (BAU) scenario; and (iv) create at least 260 direct jobs (over 1000 indirect). The NEMOSHIP consortium is composed of 11 partners (3 RTO, 1 SME, 7 large companies) and covers the whole value chain, from research-oriented partners and dissemination and exploitation specialists to software developers, energy system designers, integration partners, naval architects and end-users.

The polar regions play a key role in the Earth’s system. They are essential for our climate and are sentinels of climate change, human expansion, and the hunt of new resources. The polar regions are losing ice, and their oceans and land are changing rapidly. The consequences of this polar transition extend to the whole planet and are affecting people in multiple ways. Evidence-based policy recommendations are needed, but the polar regions are difficult to reach, and research infrastructures able to operate in these regions are scarce. To understand and predict key processes in the polar regions and provide evidence-based information, the polar research community needs access to world-class research infrastructure operating in these regions. POLARIN is an international network of polar research infrastructures and their services, aiming at addressing the scientific challenges of the polar regions. The network includes a wide array of complementary and interdisciplinary top level research infrastructures: Arctic and Antarctic research stations, research vessels and icebreakers operating at both poles, observatories, data infrastructures and ice and sediment core repositories. POLARIN will provide integrated, challenge-driven, and combined access to these infrastructures to facilitate interdisciplinary research on complex processes. POLARIN will: 1. Provide challenge-driven transnational access to a large portfolio of research infrastructures. 2. Improve the access to data by improving data availability and interoperability between data infrastructures. 3. Provide virtual access to data and data services. 4. Provide data products for the scientific community and decision makers. 5. Train the young generation of polar researchers in optimally exploiting the infrastructures for their research. 6. Duly advertise the services offered by POLARIN and engage the infrastructure users to share their research outcomes with society.

The use of fossil fuels and emission of greenhouse gases (GHG) from waterborne must be minimised as fast as possible to reach a climate-neutral society by 2050. A vital prerequisite of the decarbonisation is the rapid growth of low-carbon power sources and energy storage. To achieve this, the efficient integration in the shipboard power system requires the development of high-power components and protections, and more specifically DC-DC power converters and DC switchgear. Albeit DC primary grids have been deployed for several vessels, the secondary grid has remained substantially identical to traditional solution based on AC. There is an opportunity to unlock the capabilities and functionalities of novel components for secondary grids that can improve the safety and the operations on the vessel. These components, integrated with the power converters and the protections of the primary grids, will reduce the risks of blackouts connected to faults and improve the reliability of the power supply. ALL-DC-SHIPS has devised a comprehensive strategy to address the challenges faced by shipowners, systems integrators and ship operators that includes: 1) development of new modular power converters with wide bandgap devices for primary DC grids 2) high-density power converters for secondary DC grids 3) innovative DC protection systems for primary and secondary DC grids 4) implementation of advanced algorithms for real-time ship energy management 5) rigorous testing and validation methodologies for the vessel demonstrator 6) providing recommendations for relevant use cases above 5,000 GT. ALL-DC-SHIPS will contribute to enable low-emission waterborne transport and technology transition for a resilient and sustainable future of the maritime sector.