TECH OFFERS

Concrete deterioration caused by cracking, carbonation, and rebar corrosion represents a multi-billion-dollar global challenge. The global concrete repair market is valued at approximately USD 20 billion. Current methods are often labour-intensive, disruptive, or temporary, creating a strong demand for durable, cost-effective, and sustainable repair solutions. This innovation addresses these needs with a two-part treatment system that restores durability and prevents further structural damage: Water-based Concrete Sealer: Applied directly to concrete and steel surfaces, it prevents the ingress of water and corrosive agents (e.g., chlorides). This reduces the rate of concrete carbonation and rebar corrosion, while also functioning as an anti-corrosion coating for steel reinforcement. Micro-cementitious Crack Injection Sealant: A flowable, non-shrink material designed for sealing narrow concrete cracks (≥1.0 mm). When injected into damaged concrete, it consolidates the structure, re-alkalises adjacent carbonated concrete, and protects embedded steel rebars. By reinstating the passivating layer around embedded bars, it slows corrosion and reduces the likelihood of further cracking. Unlike traditional polyurethane injections, it provides durable, long-lasting repair without shrinkage. Both the water-based sealer and micro-cementitious sealant can be used independently or in combination, depending on the protection and repair requirements. This technology is available for R&D collaboration, IP licensing, and test-bedding with industrial partners in the construction and infrastructure sectors. The key technical advantages of this solution include: Two-part solution for crack sealing and concrete carbonation treatment Durable & long-lasting repair: Flowable, non-shrink cementitious sealant for injection grouting High penetration: Effectively seals cracks ≥1 mm  in concrete and mortar Re-alkalisation: Restores the passivating layer around rebars to prevent corrosion Protective barrier: Sealer reduces ingress of water and corrosive chemicals Strong adhesion: Bonds directly to cement, penetrates pores, and will not crack, peel, or delaminate Environmentally friendly: Low odour, VOC-free, water-based formulation This solution can be applied across the construction, building restoration, and conservation industries. Key applications include: Repair of cracking and spalling concrete caused by carbonation Restores the protective alkaline layer around steel reinforcement Mitigates further corrosion and expansion of rebars, preventing progressive cracking of concrete Preventive treatment for newly placed concrete in aggressive environments Provides protection for structures in high-risk areas such as coastal regions, where exposure to moisture, chlorides, and carbonation accelerates deterioration Conventional repair methods for reinforced concrete structures, such as removing damaged concrete or applying polyurethane injections, are often costly, disruptive, and temporary. In contrast, this solution: Preserves existing concrete by restoring alkalinity in-place without removal Reduces rebar corrosion risk, extending the service life of structures Delivers a long-lasting, non-shrink repair that aligns with sustainability goals Anti-carbonation, Penetrating sealer, Concrete water repellent, Concrete hardener, Non-shrink grout, Crack sealant Materials, Composites, Chemicals, Coatings & Paints, Polymers

Heat management has become a critical bottleneck in advanced industries such as electric vehicles, aerospace, data centers, and next-generation electronics. Traditional design processes rely heavily on expert intuition and repetitive simulation, requiring weeks to explore only a narrow design space. This results in high costs, limited performance improvements, and significant delays in bringing products to market.  The presented technology introduces a thermal-fluid topology optimization engine that autonomously generates optimal structures for cooling and fluid management. Unlike conventional parameter studies, this approach explores the entire design space and discovers novel, high-performance solutions beyond human intuition. By integrating multi-fidelity modeling and high-accuracy simulations with lightweight surrogate models, the technology reduces design time from 20-30 days to just 3-5 days, while improving cooling efficiency by more than 30%.  By combining breakthrough computational science with industrial applicability, this technology provides a next-generation design foundation for sectors where thermal performance is a decisive factor for competitiveness. Potential adoptors of this technology includes manufacturers facing urgent thermal challenges: automotive OEMs, aerospace suppliers, electronics and semiconductor companies, and data center operators. These industries demand shorter design cycles, reduced CO₂ emissions, and higher product reliability.  The technology owner is seeking to collaborate with design and manufacturing companies from different industries looking to optimise heat transfer in thermal-fluid systems. The technology owner is also open to partnerships with Computer-Aided Engineering software providers who are interested to intergrate this technology into a platform.  The technology consists of a cloud-based topology optimization engine specialized for thermal-fluid systems. At its core is a proprietary multifidelity algorithm that dynamically integrates high-precision computational fluid dynamics (CFD) models with low-cost physics-based surrogate models. This hybrid approach achieves a dramatic reduction in computation time while maintaining design accuracy. By enabling radical improvements in performance, manufacturability, and energy efficiency, this technology provides a foundation for disruptive products across multiple global markets. Key features include:  Rapid design generation and optimisation: Reduces thermal-fluid design cycles from 20–30 days to 3–5 days.  High-performance solutions: Demonstrated >30% improvement in cooling efficiency compared to conventional designs.  Design for manufacturing: System is designed to incorporate manufacturing constraints directly into the optimization process. Munufacturing methods include additive manufacturing, injection molding, and machining processes.  CAD/CAE integration: Seamless export of optimized geometries into standard CAD models, ensuring manufacturability.  Scalable computing: Built for cloud deployment, supporting parallel processing and multi-user environments.  This technology has broad applicability across industries where thermal management and fluid design are critical performance bottlenecks. Ideal collaboration partners span multiple points in the industrial value chain. Automotive & Mobility: Electric vehicles require highly efficient battery cooling and powertrain thermal management. By reducing thermal resistance and enabling compact, lightweight cooling systems, this technology directly enhances driving range, charging speed, and safety. Aerospace & Aviation: Lightweight structures and high heat resistance are essential for aircraft and spacecraft. Optimized cooling channels and thermal-fluid systems improve reliability while reducing weight and fuel consumption.  Electronics & Semiconductors: As devices become smaller and more powerful, overheating is a major risk. This technology can be applied to smartphones, laptops and high-density servers, enabling higher performance with lower energy loss. Data Centers: With data demand exploding, cooling efficiency is the key cost driver. Optimized liquid-cooling solutions derived from this platform can reduce energy consumption and CO2 emissions while improving reliability.  Industrial Equipment & Energy Systems: From robotics and heat exchangers to renewable energy storage, the technology enables more durable, efficient, and sustainable designs.  Software vendors and CAE providers: are potential partners for integration into broader engineering toolchains.  Others: Products that can be marketed based on this technology include high-efficiency heat sinks, advanced cooling plates for EV batteries, liquid-cooled data center modules, aerospace thermal management components, and next-generation industrial heat exchangers.  The market potential for advanced thermal-fluid design technologies is vast and rapidly expanding. The global CFD (Computational Fluid Dynamics) software market is projected to grow from USD 2.6 billion in 2023 to USD 5.3 billion by 2033, with a CAGR of 7.2%. Within this, thermal management for electric vehicle batteries alone is estimated at USD 3.7 billion in 2024, expected to grow at 12.6% CAGR through 2034. Similarly, aerospace, electronics, and data center industries are facing exponential demand for high-performance cooling solutions, driven by electrification, miniaturization, and rising energy costs.  Existing technologies struggle with speed, scalability, and design freedom. By overcoming these barriers, this technology positions itself as a game-changing design platform. Its value lies not only in potential cost reduction and improved energy efficiency but also in enabling new categories of products from ultra-fast EV charging systems to liquid-cooled high-density data centers.  It reduces reliance on expert intuition and empowers manufacturers to achieve breakthrough performance, shorter time-to-market, and lower carbon footprints.  Design Freedom: The ability to explore entire design spaces and generate non-intuitive, high-performance solutions.  Improved Heat Exchange Efficiency: Can potentially achieve >30% improvement in cooling performance compared to conventional design methods.  Speed: By leveraging multi-fidelity topology optimization, it combines high-accuracy models with lightweight surrogate simulations. This enables unparalleled turnaround time for industrial-scale thermal-fluid optimization by speeding up design cycles by >90%. Manufacturability: Optimised designs can be directly fabricated using standard industrial and manufacturing processes with the option of direct export to CAD/CAE. Energy, Thermal Power System, Infocomm, Computer Simulation & Modeling

This technology introduces a closed-loop wearable human–machine interface (HMI) that enables natural robotic control with real-time sensory feedback. At its core are ultrasensitive, flexible on-skin electromyography (EMG) sensing arrays that capture comprehensive muscle activity with high fidelity and stability. Unlike conventional EMG systems that rely on a few electrodes and often miss weak signals or suffer from noise, this platform delivers exceptional responsiveness for intuitive and precise robotic hand movement, making it ideal for advanced robotic control applications. The robotic hand is further equipped with high-density tactile sensors, providing force and texture feedback to the user. This bidirectional interface not only enables seamless control of robotic limbs but also creates a more immersive connection with the physical environment. In parallel, an EEG module with preparation-free gel materials is under development to integrate brain–computer interface (BCI) functions, further extending the system’s capabilities. Designed for next-generation prosthetics, rehabilitation robotics, assistive exoskeletons, and advanced HMIs, this technology offers a comprehensive platform for restoring and enhancing motor function. The team is actively seeking collaboration with medical device manufacturers (prosthetics, rehabilitation robotics, wearable sensors), rehabilitation centers and hospitals (for clinical test-bedding), deep-tech companies specializing in AI, data analytics, or biosignal processing, as well as robotics firms to co-develop and deploy this innovation in real-world applications. This system combines materials science, electrophysiology, and robotics innovations to create a robust, skin-integrated platform: Ultrasensitive EMG Sensing Conductive gel with ultra-low skin-electrode impedance Detects EMG signals as low as 1.5% Maximum Voluntary Contraction (MVC) 32–64 channel high-density sensor arrays Stretchable, conformable design with excellent motion artifact resistance Robotic Tactile Sensor Arrays > 1000 distributed sensors across the robotic hand Sensitivity: 0.01 N, with shear force detection Proven durability: >100,000 cycles EEG Module (in development) Preparation-free electrode system Thermally responsive phase-change materials Delivers high-quality, stable EEG signals for brain–computer interface integration Together, these features deliver a closed-loop system that supports multi-channel EMG-driven control with robotic tactile feedback, enabling real-time, natural, and immersive human–robot interaction. This technology can be applied across prosthetics, rehabilitation robotics, assistive exoskeletons, and advanced human–machine interfaces (HMIs). It enables the commercialization of: EMG-Controlled Prosthetic Limbs Delivering intuitive, high-resolution muscle signal decoding for natural prosthetic control. Robotic Rehabilitation Devices Adapting therapy in real time through continuous monitoring of muscle activity. Assistive Exoskeletons Supporting mobility with muscle-driven, responsive control for users with motor impairments. Robotic Hands with Tactile Feedback Providing force and texture sensing to enhance dexterity and object interaction. Multimodal HMIs Combining EMG and EEG inputs for gesture-based and brain–computer interface applications. Wearable Biosignal Platforms Extending use to clinical diagnostics, tele-rehabilitation, and immersive VR/AR systems. This solution is a closed-loop wearable interface that integrates ultrasensitive on-skin EMG sensing with robotic tactile feedback for truly intuitive human–machine interaction. Unlike conventional systems that rely on a few electrodes with poor signal fidelity, it delivers high-density, high-stability EMG acquisition capable of detecting even subtle muscle activations. The robotic hand further provides force and texture feedback, creating a responsive two-way interface. Engineered with advanced conductive gels, stretchable materials, and clinical-grade stability, this technology sets a new standard for intelligent prosthetics, rehabilitation robotics, and next-generation HMI. Flexible Electronics, On-Skin Sensing, Haptic Feedback, Human-Machine-Interface (HMI), Robotic Sensing, Electrophysiology Electronics, Printed Electronics, Sensors & Instrumentation, Healthcare, Medical Devices

Timber has long been a primary construction material for its versatile properties, such as strength and durability. However, it grows slowly and cannot match the performance of concrete or steel. Bamboo, with its high strength-to-weight ratio and rapid renewability, offers a sustainable alternative for structural applications in the construction industry. The technology on offer, Bamboo Veneer Lumber (BVL), is a next-generation high-performance bio-composite developed through a patented process in Switzerland and Singapore. BVL combines natural bamboo fibres with a specially formulated bio-based binder under high heat and pressure, ensuring superior strength and stability. As an advanced form of bio-composite, it showcases how innovation in composite technology can drive sustainable material development. This makes BVL suited for applications in construction, manufacturing, and furniture, positioning it as a sustainable alternative to conventional materials like timber and concrete. With strong green credentials—including bamboo’s rapid renewability, up to 40% lower carbon footprint compared to conventional materials, and FSC-certified sourcing—BVL represents a cutting-edge, eco-conscious option for both structural and design-driven applications. Furthermore, BVL complies with the 4 SEED characteristics: Strength, Environmental Friendliness, Economic Feasibility, and Durability—a combination crucial to the future of the built environment. Its success highlights the growing role of bio-based composites in high-performance construction and design, further validating the potential of modern composite technology in sustainable engineering. These bio-based composites also align with the global shift toward low-carbon manufacturing and renewable resource utilisation. The technology owner is seeking collaboration with manufacturing and fabrication partners, as well as companies in construction, interior design, and furniture, that are looking for more sustainable and higher-performance alternatives to wood. Sustainable Composition & Process Engineered from sustainably harvested, FSC-certified bamboo fibres fused with a custom binder matrix Produced through a patented lamination process, aligning bamboo veneers under heat and pressure to enhance natural strength of bamboo Key Performance Benefits High strength-to-weight ratio — up to 3× stronger yet 20% lighter than traditional hardwoods and engineered wood Durable and stable — resistant to decay, rot, and moisture, with excellent dimensional stability. Offers a veneer-quality surface finish, uniformity, and compatibility with standard adhesives and coatings Scalable Supply Chain Currently manufactured in one location with one bamboo species, with global expansion across the equatorial belt to leverage bamboo diversity and ensure steady supply A controlled value chain ensures consistent mechanical properties, outperforming conventional engineered bamboo in strength, durability, stability, and aesthetics Construction: as structural or non-structural components including beam, column, wall cladding, door and window frame as well as flooring Furniture: for medium to high-end furniture products where sustainability and high quality and performance matter Industrial Manufacturing: sporting goods, vehicle interiors or cabinetry delivering high-performance veneer and compatibility with a variety of other materials and adhesives The market for green building materials and furniture products is projected to exceed USD 1.3 trillion by 2030, driven by rapid urbanisation and resource depletion. In this context, bamboo stands out as a sustainable, renewable, and readily available alternative, offering significant advantages over timber and other fibres commonly used in composite manufacturing. Its natural, carbon-neutral properties align with the growing demand for eco-friendly building materials. Through uniquely patented processing and production techniques, bamboo is enhanced with the strength and durability required for high-performance applications—a critical advantage as global standards and demand for bio-based construction continue to rise. BVL distinguishes itself in the market by addressing key limitations of conventional wood and bamboo-based products. Sustainable Engineering: Made from full-length bamboo veneers bonded with a proprietary low-emission binder Patented Process: Unique lamination ensures structural continuity, enhancing load-bearing capacity, dimensional stability, and long-term durability Superior Performance: Up to 3× stronger than hardwood and most engineered woods, while approximately 20% lighter Low Environmental Impact: Combines high performance with reduced emissions and sustainably sourced materials Versatile Applications: Offers precision form, high surface quality, and adaptability for both structural and aesthetic uses Structural Applications, Sustainable Construction Material, Fibre Composite, Bamboo, , Bio-Based Material Materials, Composites, Bio Materials, Sustainability, Circular Economy

The mobility and construction sectors face increasing pressure to reduce carbon emissions, meet stricter recycling regulations, and achieve lightweighting without compromising performance. Conventional fiber-reinforced plastics (FRPs) provide strength and stiffness but introduce significant end-of-life challenges, as their multi-material composition makes separation and recycling costly and often impractical. This results in large volumes of waste, higher lifecycle costs, and growing regulatory risks for manufacturers, highlighting the urgent need to recycle composite materials more effectively across industries. This technology introduces a recyclable, self-reinforced PET (srPET) composite, delivering high-performance mechanical properties in a truly circular, mono-material system. Unlike FRPs that rely on different polymers or fiber reinforcements, srPET uses PET for both the matrix and the reinforcement, eliminating material incompatibility at end-of-life. The composite is produced from 100% post-consumer recycled PET (PCR-PET), ensuring alignment with global carbon-reduction and circular economy goals and enabling manufacturers to recycle composite materials in a closed-loop cycle. By combining excellent strength, formability, and thermal performance with compatibility for standard thermoplastic processing methods (such as press molding and lamination), this material bridges sustainability with industrial scalability. It provides a lightweight, durable, and recyclable alternative to traditional plastics, metals, and non-recyclable composites. The technology is ideally suited for automotive, aerospace, defense, and construction industries, where manufacturers seek to balance regulatory compliance, sustainability, and performance. The technology owner is seeking R&D collaborations, licensing partnerships, and test-bedding opportunities with OEMs committed to sustainable material adoption. Self-reinforced composite made entirely from PET (mono-material design). Superior mechanical performance compared to traditional unfilled thermoplastics.  High impact resistance, structural rigidity, and dimensional stability.  Low shrinkage with excellent formability.  Compatible with standard thermoplastic processing methods, including: Extrusion Lamination Thermoforming Hot-press molding Extendable functionalities  Flame-retardant formulations Sandwich panel structures for mobility and construction sectors Thermal insulation properties This technology is suitable for a wide range of industries where lightweighting, recyclability, and high performance are critical: Automotive: door trims, underbody shields, NVH (noise, vibration, harshness) components. Aerospace: interior panels and non-structural lightweight parts. Defence: anti-stab panels and impact-resistant protective structures. Marine: lightweight structural covers and panels. Construction: interior/exterior wall panels, insulation boards, and sandwich panels. The material is especially suited for sectors demanding recyclability, high strength-to-weight ratios, thermal insulation, and compliance with evolving regulatory standards. The global lightweight materials market is expected to exceed USD 250 billion by 2030. Demand is rising across EVs, aerospace, and defense sectors, while increasing sustainability regulations such as EU ELV and U.S. EPR are accelerating the adoption of circular materials like srPET composites. In the building sector, demand is also growing for carbon-neutral and sustainable construction materials. This technology leverages 100% recycled PET to deliver superior thermal stability, processing compatibility, and recyclability. Its mono-material structure enables true closed-loop recycling without the need for material separation, directly supporting ESG commitments and circular economy goals. In addition to mechanical durability and excellent formability, the material offers inherent insulation performance, creating a strong advantage for cost-sensitive, regulation-driven markets such as green construction, lightweight mobility, and consumer products. Chemicals, Polymers

Many organisations rely on unstructured workflows across legal, procurement, HR, finance, sales, supply chain and production, resulting in inconsistent policy enforcement and limited visibility over contract and audit obligations. This technology solves the widespread inefficiencies of manual and fragmented contract or approval processes, which often lead to delays, compliance gaps, revenue leakage, and increased legal exposure. The technology provides an AI-powered contract lifecycle management platform that streamlines document/contract generation, redlining, approval, execution, and tracking within a single digital workspace. It enables business users to independently generate compliant contracts using pre-approved templates and embedded rules, while still allowing internal teams to maintain oversight and enforce standards. The platform features clause-level risk analysis, AI-assisted contract review, a no-code workflow engine, and audit-ready document integrity checks. By automating routine legal work and centralising contract data, the technology reduces turnaround time, improves compliance, and frees legal/compliance teams to focus on higher-value tasks. It meets a growing market need for scalable, policy-aligned contract systems that are secure, user-friendly, and adaptable across different compliance requirements. This solution is designed for enterprises, government agencies, and regulated institutions with high volumes of contracts and strict policy controls. It is especially relevant to industries such as banking, real estate, manufacturing, logistics, education, and telecommunications. The technology owner is looking to partner with solution adoptors to customise platform functions to specific use cases. Features: Secure, scalable architecture. Deployment options include public cloud, private cloud, or hybrid models. System availability is maintained through automated backups, disaster recovery protocols, and uptime monitoring aligned with enterprise SLAs. The platform includes API connectors for integration with third-party systems such as ERP, CRM, and file repositories. It supports multi-language deployments, full audit trails, and advanced user permissions for both centralised and decentralised teams. Modular design that allows organisations to configure contract processes based on internal policies, user roles, and jurisdictional requirements. The system offers granular access control (including RBAC and ABAC) and complies with global regulatory frameworks such as ESIGN, eIDAS, GDPR, and HIPAA. Transparent, usage-based pricing with unlimited digital signings. Comprehensive local after-sales support that follows through from integration to ongoing operations and beyond, ensuring client success and continuous improvement. Continuous optimisation and feedback integration with a dedicated support team for post-implementation reviews to ensure continued alignment. System Components: A template and clause library with version control for rapid document generation. An AI-powered review engine that analyses contract text, compares it to internal playbooks, and flags non-compliant clauses. A document integrity checker capable of detecting changes across native, scanned, and image-based files. A no-code workflow builder that configures approval paths, escalation rules, and role-based access control without developer intervention. A real-time tracking dashboard that monitors contract status, key dates/deadlines, and renewal obligations to ensure accountability throughout the lifecycle. A native digital signature module that supports legally recognised e-signatures in multiple jurisdictions. This technology can be deployed across industries that require structured, high-volume contract processing and enforceable compliance controls. It is particularly suited to organisations with decentralised teams or multi-tiered approval structures where coordination, legal/audit risk, and turnaround time are critical operational concerns.  Financial services: the technology supports contract automation for lending agreements, NDAs, supplier contracts, and internal governance documentation. Real estate and construction sectors: it is used to manage leasing agreements, contractor onboarding, and procurement workflows. Manufacturing and logistics: firms benefit from streamlined handling of distribution agreements, service-level agreements (SLAs), international vendor contracts and management of manufacturing documents. Public sector: the platform enables statutory bodies and agencies to digitise internal workflows while complying with transparency and audit requirements. Educational institutions: platform to support research collaboration agreements, student placement contracts, and licensing arrangements.  Others: The technology is also applicable in telecommunications, energy, and healthcare, where regulatory requirements, jurisdiction-specific clauses, and ongoing contract obligations must be managed consistently.  The global market for contract lifecycle and digital signature solutions is experiencing rapid growth, driven by rising compliance demands, increased contract volumes, and the need for secure remote collaboration. The contract lifecycle management (CLM) segment alone is expected to surpass USD 5.8 billion by 2030, while the digital signature market is projected to grow from USD 2.5 billion in 2023 to USD 22.5 billion by 2032, reflecting a strong compound annual growth rate (CAGR) of over 27%. Asia-Pacific, North America, and Europe are major growth regions, with the Asia-Pacific market projected to reach USD 12 billion by 2030. This growth is supported by increasing adoption of legal tech tools in sectors such as banking, real estate, manufacturing, healthcare, and the public sector. This technology stands out in a crowded field by offering a truly end-to-end CLM platform that includes native AI tools, such as clause-level risk analysis, smart redlining suggestions, and document integrity checks.   This technology represents a substantial improvement over the current state of contract management by replacing manual, disjointed processes with streamlined, AI-driven workflows. It transforms contract operations from reactive, document-heavy tasks into proactive, data-informed functions that support business strategy. Efficiency gains and cost savings: Clients have achieved potentially up to 45% faster contract cycles and 80% faster drafting. Automated workflows and integrated e-signatures shorten approval and execution times, while standardised templates and AI-assisted review reduce drafting effort and ensure compliance. Obligations tracking prevents missed renewals and revenue leakage, and integration with enterprise systems eliminates duplicate data entry. Together, these capabilities transform contract management into a faster, more accurate, and cost-efficient process. Integrated Proprietary AI: Instead of providing e-signature and CLM modules separately or rely on third-party AI, this solution offers purpose-built automation across pre-signature and post-signature stages. These differentiators make the platform attractive to enterprises and institutions seeking secure, scalable, and intelligent contract management beyond basic storage and signature tools. Proprietary AI modules are trained on client-specific data, enabling accurate clause analysis, automated contract reviews, and policy-aligned compliance checks. Frictionless collaboration: Features like in-platform commenting and secure chat promote cross-functional teamwork. Strategic visibility: Built-in analytics surface insights on contract performance and bottlenecks, supporting data-driven legal/documentation operations and helping teams demonstrate business value. Contract Lifecycle Management, AI-Powered Automation, Legal Technology, Workflow Automation, Digital Signatures, Compliance Management, Cloud-Based SaaS Solution Infocomm, Enterprise & Productivity, Data Processing

With the increasing demand for higher computational power, quantum computing has received growing attention due to its ability to perform parallel processing. Among the different approaches, ion trap quantum computing stands out as a promising option. Unlike other methods, such as superconducting qubits, ion trap systems can operate at room temperature and are compatible with standard semiconductor manufacturing processes. However, there is currently no standardized process design kit (PDK) available for developing photonic circuits in ion trap systems, resulting in the in-depth technical expertise needed to handle the complex design and optimisation process of photonic devices. This gap highlights the growing need for reliable design tools to support integrated photonics within ion trap quantum computing architectures. The technology owner has leveraged on their patent pending photonic design process to develop an AI-assisted platform to assist and accelerate the design-to-layout process of photonics-integrated ion trap systems. By specifying the desired parameters, such as trapped ion species, photonic components and ion trap, users can automatically validate via simulation and generate a Graphic Data System (GDS) layout that is ready-to-fabricate while meeting the photonic design requirements. This results in an increased productivity by reducing guesswork and resources, reducing verification turnaround time and lowering the technical barrier required within the design process. This approach strengthens the ecosystem for advanced chip development in Singapore while pushing the frontier of integrated photonics in emerging quantum applications. The technology owner has successfully conducted a pilot test with a Singapore-based company in developing a photonic chip utilising their platform. Currently, the owner is actively seeking industrial collaborators interested in exploring photonic applications in quantum computing device design and manufacturing. The technology solution leverages on the technology owner’s technical research and expertise on on-chip ion trap development to develop the AI-assisted digital platform catered to accelerate the design process of such photonics-integrated ion trap system. The key features include: Input parameters such as intended photonic wavelength (from visible to infrared), trapped ion species, photonic components Automated design of 4 gratings for trapping ability of ion-trap Technical processing of numerous design and considerations, such as broadband grating couplers for input-coupling of light, output grating of couplers and ring resonators for the filtering of wavelengths and respective light sources pairing Built-in formation and performance verification of constructed photonics circuit into on-chip ion trap Automated generation of photonic circuit in a ready-to-tape-out DGS format layout Given the technology solution being utilised within the ion-trap design and fabrication process, below are some potential applications in which have the capability to leverage on the solution, including: Quantum computing companies leveraging on the ion-trap system for its working mechanism Photonic integrated circuits (PICs) and co-packaged optics (CPO) who requires stringent production of photons Quantum clock applications requiring strict ion-trap focusing on optical transitions. Industrial players within the photonics industry looking to accelerate their verification turnaround time This AI-assisted platform solution can automatically internalise the in-depth technical knowledge required to design photonic devices needed for ion trap systems, integrate them into the ion trap layout, and generate a tape-out-ready design. It has the potential to significantly reduce the time, manpower and technical resources required in the traditional chip design process, particularly in the development of photonics-integrated ion trap systems. Silicon Photonics, Photonics Integration, Ion-Trap, Quantum Computing, Photonic Integration Circuit, Co-Packaged Optics, Graphic Data System, Design-to-Layout Electronics, Lasers, Optics & Photonics, Infocomm, Computer Simulation & Modeling, Quantum Computing

Polishing stainless steel parts with internal channels remains a challenge when aiming for high-quality surface roughness and tight tolerances. Mature technologies often fall short in this area, and traditional polishing methods can also be expensive to set up. Surface finishing is a persistent issue across all metal additive manufacturing (AM) processes, directly impacting part quality and limiting applications. This challenge is particularly pronounced in AM compared to conventional methods due to the inherently rough surface finish and the frequent use of hollow or lattice geometries. The presented technology offers a potentially more cost-effective, high-quality, and scalable solution for polishing internal channels of 316L stainless steel. As an electropolishing solution for stainless steel components, it enables rapid, automated improvement of both internal and external surfaces, enhancing appearance, corrosion resistance, and mechanical properties. The technology provider is open to R&D collaboration where proof of concept for specific applications can be explored. During deployment, guidance on set up and training can be provided. Target audience are additive manufacturers who are interested license and implement this technology to perform electropolishing in-house. The technology owner is also looking to work with product owners or OEM who are interested to implement this technology into their production workflows, particularly those seeking an electropolishing solution for stainless steel for in-house finishing efficiency. The set up consist of: Customised chemicals Electrodes Other apparatus that work together to polish the surface and internal channels of metal parts Specifications: Surface Roughness: Minimum surface roughness achievable as low as Ra = 1.0 μm, with surface roughness reduction of 91% (tested on 2205 duplex and 316L stainless steels, applicable to austenitic and ferritic stainless steels) Channel size: 5 mm or greater  Maximum part size: 200mm This technology can be implemented in industries that require precise, repeatable, high-quality metal parts or polishing of typically inaccessible surfaces. It is suitable for automation for improved productivity. Applications includes:  Precision engineering Aerospace e.g. propellers Medical e.g. surgical tooling and jigs Oil and gas e.g. impellers Chemical Electronics Food and beverage Other applications that require polishing of stainless steel channels  Compared to traditional polishing methods for stainless steel channels, this technology is more superior due to below reasons:  Better surface roughness Better tolerance for internal channels  Potentially more cost effective compared to methods that require high pressure settings Better corrosion prevention with passivation Eliminates laborious manual residual powder removal during post-processing process for additive manufacturing Proprietary process avoids the use of perchloric acid and flammable solvents, and ensures complex internal geometries are uniformly and optimally polished manufacturing, materials, electroplating Manufacturing, Additive Manufacturing, Chemical Processes

In Singapore’s space-constrained and high-cost manufacturing landscape, maintaining food safety and product quality efficiently is critical. This technology  provides a smart, adaptable solution designed to meet these unique local challenges. Currently, product packaging inspections are often assigned to production operators who  juggle multiple responsibilities. Since this manual process relies heavily on human judgment, outcomes vary with individual skill levels and are vulnerable to worker fatigue - leading to inconsistent inspection standards.  Random sampling is commonly used, where only a subset of packages within each batch is checked. However, this approach risks missing foreign objects, which may contaminate products and compromise food safety.  Product recalls are  costly and damaging to brand reputation, in addition to posing significant food safety risks. It is therefore essential to prevent them wherever possible. This solution minimises this problem by replacing manual inspections with an automated system capable of examining packaging in the production line  before product filling. Its modular design allows seamless integration with existing production lines, minimizing the need for extensive modifications and lowering the cost of adoption for food manufacturers.  Ultimately, the modular vision inspection system goes beyond quality assurance - it represents a strategic investment in resilient, efficient, and future-ready food manufacturing in Singapore.   This machine vision solution uses a camera with an AI algorithm software to perform QC inspection on product or packaging continuously. It detects and rejects foreign objects on packaging or food surfaces to relief the production operators from repetitive and mundane QC duties, thereby enhancing overall productivity while ensuring the food safety standard are being well maintained. Modular: Easily adaptable to existing production line to include machine vision on detection of foreign objects. Technology owner provides expertise in system integration if required. Transparent-on-transparent detection: Able to detect as small as 3mm of glass particle against glass material e.g. jars with up to 95% accuracy.  Detection of other challenging contaminents: E.g. Opaque items such as hair, insect as small as 1mm in size.   Food manufacturing facilities such as:  Sauce Production Facilities Pre-mix powder production facilities OEM Packaging inspection and qualification Other applications includes:  Medtech manufacturing  Semiconductor manufacturing  SMEs who are looking to integrate vision inspection with incremental features AI data interpretation has the ablilty to detect transparent on transparent material (e.g. glass on glass, white hair, insects) on packaging or food surfaces. Modular and able to adapt into existing production set up easily. Potentially more cost effective as a modular solution compareed to available solutions with extended systems and features.   Food safety, Vision inspection, Quality control, Physical defects detection Foods, Quality & Safety, Processes