Two-dimensional (2D) materials are crystalline solids consisting of a single atomic layer in thickness, with lateral dimensions from hundreds of nanometres to several microns. Their atomically thin structure, combined with engineered crystal architecture, delivers properties that surpass conventional materials in conductivity, mechanical strength, surface reactivity, and spin-dependent behaviour.

At NANOARC, our portfolio of mono- and multicomponent 2D materials is designed to provide quantifiable performance advantages, enabling innovation across electronics, energy, coatings, and biomedical sectors.

PERFORMANCE HIGHLIGHTS

• Electrical Conductivity: Up to 10× higher carrier mobility than conventional thin-film semiconductors, supporting faster, lower-power electronic devices.

• Mechanical Strength: Tensile strength exceeding 130 GPa for atomically thin layers, ideal for composite reinforcement and flexible electronics.

• Spin Transport: Spin diffusion lengths up to 20 µm, enabling advanced spintronic and quantum devices.

• Surface Reactivity: Up to 5× increase in catalytic efficiency relative to traditional nanomaterials for energy and chemical applications.

• Optical Tunability: Bandgap engineering across the visible to near-infrared range, optimising coatings, sensors, and photonic devices.

SECTOR-SPECIFIC BENEFITS

ELECTRONICS

• High-mobility 2D materials enable next-generation transistors, sensors, and spintronic devices.

• Reduced power consumption and faster switching speeds for low-energy computing.

• Tailored bandgaps support flexible printed, or transparent electronic components.

ENERGY

• Multicomponent 2D materials provide high-efficiency electro-catalysts for fuel cells, electrolyzers, and batteries.

• Engineered surfaces enable enhanced charge transfer and long-term stability, improving energy conversion efficiency by up to 30%.

COATINGS

• Exceptional mechanical strength and chemical stability support durable, functional coatings with UV-blocking, antimicrobial, or anti-corrosion properties.

• Atomically thin layers allow ultra-lightweight and highly conformal coatings with up to 50% thinner layersthan conventional solutions while maintaining performance.

BIOMEDICAL

• Biocompatible 2D materials with tunable surface chemistry enhance drug delivery, imaging, and biosensing.

• High surface-to-volume ratio and chemical activity enable nanotherapeutics with improved targeting and efficacy, achieving up to 5× higher loading capacity for therapeutic agents.