# WP1: Advanced Integrated Design Model (IDM)
- Comprehensive system encapsulating all ALCYONE components, their requirements, properties, and inter-relations.
- Real-time, collaborative access to multi-dimensional project representation.
- Advanced simulations and trade-off analyses capabilities, facilitating rapid decision-making.
# WP2: Innovative Biosensors
- Developed a cyanobacterium-based biosensor for deep space radiation monitoring, leveraging its desiccation and radiation tolerance.
- Created bioluminescence-based yeast and mammalian cell biosensors for CubeSat missions, a previously unexplored application.
# WP3: Advanced Lab-on-Chip Design
- Three-layer modular architecture with separate sensors, actuators, and microfluidic layers.
- Design takes into account all the system aspects in parallel: the biological requirements, the technological constraints, the ease of fabrication and testing, the operation in micro-gravity conditions and the lab-on-chip interfacing.
- Geometry and materials optimized for micro-gravity conditions with sidewall microfluidic connections and sandwich-type electrical contacts.
- Integrated thin-film sensors and actuators for accurate local control and sensitive bioluminescence measurement.
# WP4: Novel Dosimetry System
- First-in-world use of TI-LGAD technology in dosimeters, overcoming limitations of traditional LGAD technology.
- Achieved high spatial resolution and high fill factor through trench isolation technique.
- Single-particle resolution detection and energy measurement in high-particle-rate conditions.
- Maintained low power consumption for efficient radiation detection and measurement.
# WP5: Innovative Microfluidic System
- Developed a miniaturized fluidic dispensing subsystem suitable for space applications.
- Advanced bubble management for microgravity environments.
- Innovative fluidics concept compared to classical bench fluidics for microfluidic chips.
The ALCYONE project has made significant advancements in space research technology, offering innovative solutions for radiation monitoring, biological experiments, and system integration. These developments contribute substantially to the future of deep space exploration and long-term human missions, pushing the boundaries of current technological capabilities in space research.