Functional materials achieve specific functions such as energy conversion, information processing, or environmental responsiveness through their unique responsiveness to external physical or chemical stimuli. Characterized by distinctive microstructures and compositions, these materials allow for the customization and optimization of properties via precise manipulation of their atomic, molecular, or crystal structures. Jooe specializes in delivering high-performance functional materials and comprehensive chemical technology support, covering the entire industrial chain from monomer synthesis to end-product applications. Our solutions empower cutting-edge fields including display technology, new energy, and biomedical innovation.
We design and synthesize specific functional material monomers according to customer requirements. For OLED/liquid crystal applications, we enhance carrier mobility and luminance efficiency by modulating molecular conjugation structures through structure-property relationship studies. Concurrently, targeted substituent modification improves solubility and glass transition temperature, effectively addressing device phase separation issues.
We offer end-to-end services for MOF/COF and organic semiconductor material synthesis, including property assessments targeting thermal stability, surface activity, optical performance, and bioactivity.
We assist customers in integrating materials into end-products, and establish material-to-device validation platforms (e.g., OLED device testing) for industrial chain integration, tackling real-world application challenges.
We deliver expert guidance on material selection, process bottlenecks, and sustainability compliance. Proprietary technologies including porphyrin-based photosensitizers and AIE materials are available through licensing partnerships to circumvent technical barriers.
Electroluminescent materials that emit visible light via carrier recombination, requiring balanced luminous efficiency, color purity, and device longevity.
Core photovoltaic materials converting solar to electrical energy, characterized by light absorption coefficients, carrier mobility, and interface passivation capabilities.
Bio-based/low-toxicity plasticizers enhancing coating flexibility while complying with VOC emission regulations.
High-Tg thermoplastics (Tg>180°C) with robust mechanical strength and chemical resistance for extreme environments.
Tunable-porosity frameworks (MOFs/COFs) and quantum-sized nanomaterials enabling catalysis, adsorption, and sensing applications.
Ultra-high-purity precursors (e.g., trimethylaluminum) for CVD/ALD deposition of semiconductor thin films.
