Blografi

Art, design, and advanced materials are converging at an unprecedented pace, with nanotechnology in art emerging as a central force behind this transformation. As one of the leading companies developing advanced nanomaterials and functional surfaces, Nanografi operates at the forefront of nano-engineered materials that enable stimuli-responsive behavior, adaptability, and time-dependent performance. This same material intelligence is now reshaping contemporary art, making it possible for artwork …

From Fiction to Advanced Nanomaterials in Real Protective Systems For years, popular culture has portrayed “super suits” capable of extreme impact resistance, thermal control, electromagnetic shielding, and seamless embedded electronics. While these cinematic armors belong to fictional universes, the underlying performance attributes increasingly align with what advanced nanomaterials can deliver today. As Nanografi, we work at the core of this evolving materials ecosystem, deliverin …

Quantum dots (QDs) are nanoscale semiconductor crystals capable of emitting light at specific wavelengths when exposed to UV light or other energy sources. Their ability to fluoresce in specific, tunable colors determined by the size and composition of each particle makes them ideal for brand protection applications. Unlike conventional dyes, quantum dots are highly photostable, resistant to fading, and able to deliver distinct optical signatures. This allows them to be embedded into inks, label …

The promise of nanotechnology in medicine is no longer hypothetical—it’s rapidly becoming the foundation of a new era in healthcare. In recent years, researchers have begun to demonstrate how nanomaterials can change how we diagnose, treat, and even prevent diseases. Unlike conventional methods that work on tissue or organ level, nanotechnology enables precise interactions with cells, proteins, and even DNA—opening pathways for previously unthinkable medical solutions. At the …

Vibrational spectroscopy is a fundamental analytical technique that provides molecular-level insights into the structure, bonding, and chemical composition of materials. The method is based on detecting the vibrational motions of atoms within molecules. These motions, such as stretching or bending, correspond to specific vibrational energy levels. The two most commonly used forms of vibrational spectroscopy are Infrared (IR) spectroscopy and Raman spectroscopy. Each technique interacts with mole …