Electrification coupled with renewable electricity supply is a key pathway to achieve a deep decarbonization of our society and contribute to an energy transition in a sustainable way. The electric energy demand based on distributed renewable sources is going to be even more important and a more efficient, secure, flexible and affordable energy distribution should be envisaged for the next future. If these requirements are not met, the replacement of well-established solutions based on fossil fuels will be unfeasible. Consequently, apart from the evident environmental impacts, collateral effects could occur, such as great blackouts at national and continental level. In this scenario, SAFEPOWER first explores and investigates on essential digital, enabling, and emerging technologies to achieve a new generation of power converters for solar applications: i) capable of anticipating failures to prevent downtime using effective Condition and Health Monitoring (C&HM) solutions assisted by AI strategies, ii) based on more compactly-packaged, efficient, rugged and affordable Silicon Carbide (SiC) power MOSFETs, diodes and solid-state DC breakers with a more sustainable manufacturing, and iii) prospecting on Ga2O3-based emerging power devices (MESFETs, diodes and solid-state DC breakers) especially designed for this application. Leveraging these technologies, SAFEPOWER studies and proposes new converter topologies and control schemes to enhance their compactness, sustainability, competitiveness, and security. Additionally, these technologies streamline cost-effective maintenance through AI-assisted intervention plans and AI-enabled "limp mode" operation with derating strategies, which can be extended to offshore wind energy conversion. Therefore, the adoption of SAFEPOWER's technological solutions in the EU solar sector not only will establish a competitive advantage against non-EU power converter manufacturers, but also will enable their initial deployment within the EU.