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Candidates
TU Delft Impact Contest
Naomi (semi-finalist)
Every morning, many people's willpower dies before the day even starts. The problem being addressed by Naomi is morning fatigue and difficulty waking up, which lead to underperformance. Inefficient waking methods disrupt the natural sleep cycle, causing stress, exhaustion, and decreased productivity. This can negatively impact mental health, leading to poor decision-making and reduced performance in both personal and professional life.
Read moreOnCue, computer keyboard for people with Parkinson's Disease (semi finalist)
This project focuses on improving computer keyboard interaction for individuals with Parkinson’s disease, specifically addressing the symptoms of tremors and bradykinesia, which cause slowed movement and impair fine motor skills. The goal is to reduce frustration and avoidance behavior associated with keyboard use, making interaction more accessible and comfortable.
Read moreInteractive Image Descriptions (semi-finalist)
Existing image descriptions often lack context or detail and fail to meet the diverse needs of people with visual impairment. Preferences vary widely based on factors such as the type and onset of visual impairment, age, and personal interests. A one-size-fits-all approach to image descriptions is inadequate, highlighting the need for customizable, context-aware solutions. As mentioned in the article “The Accessible Books Consortium: what it means for publishers” by Catherline Jewell in WIPO magazine in 2018, globally, less than 10% of published works are available in accessible formats, leaving a significant gap inclusive for people with visual impairments. Accessibility and inclusivity has often been an ignored segment. This project investigates how artificial intelligence (AI) and interactive technologies can bridge this gap - and develops other integrate the solution that fits well with the need and real life scenario of target users.
Read moreVi-te! (semi-finalist)
Most AI assistants require screens and manual input, making them disruptive rather than helpful. Vi-te provides a hands-free, proactive AI experience, reducing cognitive load and improving accessibility for both general users and people with disabilities.
Read moreProject: Aerosail (semi-finalist)
The shipping industry is a major contributor to global carbon emissions, producing approximately 706 million tonnes of CO₂ annually. As international trade grows, emissions from shipping are expected to rise, posing environmental and regulatory challenges. Current fuel-saving technologies often require expensive retrofitting, making adoption difficult for shipping companies. There is a need for a cost-effective, easily deployable solution that reduces fuel consumption and emissions without disrupting existing fleet operations. Meeting stricter environmental regulations while maintaining economic efficiency is a critical challenge for the maritime sector.
Read moreParaSolar (semi-finalist)
ParaSolar transforms existing surfaces, such as parasols, into energy sources by seamlessly integrating solar cells. We make sustainable energy accessible without taking up extra space.
Read moreInfrastructure monitoring software (InfraDCM) (semi-finalist)
The current methods of infrastructure monitoring are expensive, time-consuming, and often destructive.
Read moreThe Synergy Hub (semi-finalist)
We notice that teams in organisations are not harnessing the full potential of collaboration. Things like lack of vision and strategy, team misalignment, trust, defensiveness, and narcissism lead to reduced productivity and growth at best and destructive effects, at worst. Organisations and teams therefore suffer from underperformance and inefficiency, while also having members who are stressed, feeling disconnected, not feeling empowered, unable to be creative, and not feeling safe and included within their teams and organisations. Even if constructive conditions exist, collaborations still face hurdles to reach their full potential. This ultimately has an impact not only on the individuals, teams, and organisations, but on the society as a whole that would bear the costs of having members who are not thriving, happy and fulfilled.
Read moreJUMP (semi-finalist)
The space industry is undergoing an unprecedented boom, with institutions and private companies racing to deploy new satellites and spacecraft for commercial, scientific, and technological missions. From global communications to deep-space exploration, modern space missions are more ambitious than ever. However, a major weak link threatens their success: power system failures. Reliable energy is the lifeline of any spacecraft, yet nearly 20% of mission failures stem from power system malfunction: deployment failures are particularly critical, often leaving spacecraft powerless and unable to fulfill their mission. Additionally, current designs rely on oversized, redundant, and costly power systems, increasing launch expenses and limiting efficiency. But what if we could eliminate these risks and provide a continuous energy source? JUMP explores a revolutionary alternative: harvesting energy from the Van Allen Belts and other planets' radiation fields, to supply spacecraft with uninterrupted power. This breakthrough could radically enhance mission reliability, reduce failures, and unlock new frontiers in space exploration, paving the way for an original energy solution beyond Earth's orbit.
Read moreSircular
The semiconductor industry faces a significant silicon waste problem, with nearly 75% of the material lost during production. Current recycling rates for Si and SiC are extremely low (around 5%), and existing recycling methods are costly and inefficient. Europe’s heavy reliance on imported Si and SiC from Southeast Asia creates supply chain vulnerabilities, exacerbating risks during global semiconductor shortages. A sustainable, circular approach to silicon waste recovery is urgently needed to enhance resource efficiency, reduce environmental impact, and secure a stable supply of critical raw materials.
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