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Three University of Sydney projects have received over $8 million in funding via theÌýCooperative Research Centres Projects (CRC-P)Ìýgrants, designed toÌýsupport short term, industry-led collaborative research.

The winning projects fromÌýtheÌýFaculty of ScienceÌý²¹²Ô»åÌýFaculty of EngineeringÌýwill support Australia’s visually impaired community, develop electric vertical take-off and landing (eVTOL) aircraft, and establish Australia as a pioneer in advanced hydrogen storage materials.

A total of 22 industry-led collaborative research and development projects will share in $47.1 million in funding from the Australian Government.

ARIA - bionic visual-spatial prosthesis for the blind

ARIA is a breakthrough bionic medical device that delivers high-fidelity visual-spatial perception for blind people. ARIA makes possible new levels of autonomy for Australia’s 600,000 blind & vision impaired citizens and for over 337 million blind/vision impaired people globally.Ìý

Led byÌýAssociate ProfessorÌýCraig JinÌýfrom theÌýSchool of Electrical and Information EngineeringÌýalongside DrÌýDonald DansereauÌýand DrÌýViorela IlaÌýfrom theÌýSchool ofÌýAerospace, Mechanical and Mechatronic Engineering,ÌýARIA has been granted $2,602,035 to undertake preclinical evaluations, build early prototypes, undertake preclinical trials, and prepare for future clinical trials.

Vertiia - powertrain development for high speed eVTOL transport

Vertiia is an Australian developed electric Vertical Take-off and Landing (eVTOL) Aircraft, that will provide rapid response air ambulance and low cost passenger transport for regional and remote Australia.Ìý

Helmed byÌýAssociate ProfessorÌýDries VerstraeteÌýfrom theÌýSchool ofÌýAerospace, Mechanical and Mechatronic Engineering, this project will enable the optimisation and development of a quiet, efficient and lightweight propulsion system tailored for Vertiia, greatly increasing range, reducing noise and lowering cost.Ìý

Optimising these components will increase Vertiia’s potential to operate in noise sensitive areas and enable the delivery of the lowest cost transport as an air ambulance or air taxi.

Advancing nanoporous MOF materials for high efficiency hydrogen storage

Led byÌýProfessorÌýCameron KepertÌýand Dr Lauren Macreadie, both from theÌýSchool of Chemistry, this project will prove-up breakthrough advanced hydrogen storage materials discoveries at the University of Sydney.Ìý

The inability to store H2 efficiently is a key barrier to the uptake of H2 as a new zero-carbon fuel, as identified in the National Hydrogen Strategy.Ìý

Granted $2,770,000 in funding, the project is expected to demonstrate the superior system-wide volumetric and gravimetric efficiency gains of the metal-organic-framework (MOF) material to enable higher density lower pressure storage.Ìý

These gains will enable key H2 markets in grid, mobility and aerospace, supporting decarbonisation. This project will enable technology validation and prototype development and testing with SME & large industry partners, accelerating commercialisation and uptake.