Heat Pump and solar appliances are the most social accepted residential Renewable Energy based energy systems. SunHorizon will demonstrate up to TRL 7 innovative and reliable Heat Pump solutions (thermal compression, adsorption, reversible) that acting properly coupled and managed with advanced solar panels (PV, Hybrid, thermal) can provide heating and cooling to residential and tertiary building with lower emissions, energy bills and fossil fuel dependency. A Cloud based functional monitoring platform will be realised in the project to be the “performance data mine” for the development of Data Driven/KPI oriented optimized algorithms and tools to predict maintenance, optimize the management towards maximisation of solar exploitation and give to the manufacturer inputs for new installation design, via an innovative “robust design under uncertainty approach” which aims to overcome classical H&C equipment oversizing due to safety factors . This monitoring platform will also drive smart end user interfaces that will be applied at building level to collect thermal comfort data towards a new end-user driven H&C control system. SunHorizon tools will be applicable not only to proposed solar coupled HPs, but to all H&C appliances towards a global increasing efficiency of EU H&C stock and its decarbonisation. 5 low emission H&C Technology packages (TPs) will be tested coupling HP and solar installation. SunHorizon aims to be a breakthrough demonstration to market project involving 21 partners and 8 demosites all around EU focusing its activities on “reducing system costs and improving performance as well as optimising existing technologies for H&C applications”. SunHorizon will be focused on three main research pillars interacting each other towards project objectives achievement, demonstration and replication: i) OPTIMIZED DESIGN, ENGINEERING AND MANUFACTURING OF SUNHORIZON TECHNOLOGIES ii) SMART FUNCTIONAL MONITORING FOR H&C,iii) KPI DRIVEN MANAGEMENT AND DEMONSTRATION.

Over the past 60+ years CMOS-based digital computing has giving rise to ever-greater computational performance, „big data“-based business models and the accelerating digital transformation of modern economies. However, the ever-growing amounts of data to be handled and the increasing complexity of today’s tasks for high performance computing (HPC) are becoming unmanageable as the data handling and energy consumption of HPCs, server farms and cloud services grow to unsustainable levels. New concepts and technologies are needed. One such HPC technology is Quantum computing (QC). QC utilizes so-called quantum bits (qubits) to perform complex calculations fundamentally much faster than a conventional digital-bit computers can. First quantum computer prototypes have been created. Superconducting Josephson junctions (SJJs) have been shown to be extremely promising qubit candidates to achieve a significant nonlinear increase of computational power with the number of qubits. For novel materials there is a great challenge yet opportunity in Europe to create a complete value chain for SSJs and QCs. Such a complete value chain will contribute to Europe’s technology sovereignty. The MATQu project aims at validating the technology options to produce SJJs on industrial 300 mm silicon-based process flows. It covers substrate technology, superconducting metals, resonators, through-wafer-via holes, 3D integration, and variability characterization. These will be assessed with respect to integration practices of qubits. Core substrate and process technologies with high quality factors, improved material deposition on large-substrates, and increased critical temperature for superconducting operation, will be developed and validated. The MATQu partners complement each other in an optimal way across the value chain to create a substantial competitive advantage, e.g. faster time-to-market and roll-out of technologies and materials for better Josephson junctions for quantum computing.