For the First Time, Scientists Create a Single Atom Layer Thick Material, They Name It 'Goldene'

For years, scientists have grappled with the challenge of creating single-atom-thick sheets of gold due to its tendency to aggregate. However, a team of researchers from Linköping University has cracked this puzzle using a centuries-old technique employed by Japanese artisans. This discovery has unleashed a new era of possibilities for gold in nanotechnology. The Science Behind Goldene Dr. Shun Kashiwaya from the Materials Design Division explains, "When you make a material extremely thin, something extraordinary happens – similar to graphene. Gold, typically a metal, transforms into a semiconductor when reduced to a single-atom-layer thickness." This transformation opens doors to a myriad of applications previously unexplored in the realm of nanomaterials. Unveiling the Process The creation of goldene involves embedding gold within a three-dimensional base material comprised of titanium and carbon layers. Fortunately, the researchers stumbled upon a method known as "intercalation," resulting in the formation of titanium gold carbide. The subsequent challenge was to exfoliate the gold into single-atom layers. The Art of Adaptation: Murakami’s Reagent Inspired by traditional Japanese forging techniques, specifically Murakami’s reagent, the scientists devised a modified approach to etch away carbon residue and isolate the gold sheets. Adjusting concentrations and etching durations were key steps in refining this process, leading to the successful extraction of stable goldene sheets.  Stabilizing Goldene: Akin to "Cornflakes in Milk" To prevent the goldene sheets from curling up, a surfactant was introduced, acting as a stabilizing agent akin to milk in a bowl of cornflakes. This innovative method not only enabled the production of stable goldene but also laid the groundwork for further exploration into similar applications with other noble metals. Applications of Goldene The newfound properties of goldene, particularly its semiconductive nature at the atomic level, hold immense promise across diverse fields. Applications range from catalyzing hydrogen production and carbon dioxide conversion to enhancing water purification and communication technologies. With the successful creation of goldene, researchers are now poised to explore similar methodologies with other noble metals. This opens doors to a future where nanomaterial science drives innovation in sustainability, chemistry, and advanced technologies. The unveiling of goldene represents more than just a scientific breakthrough; it marks a paradigm shift in the utilization of precious metals at the atomic scale. The potential applications of goldene are limitless, offering solutions to pressing global challenges while pushing the boundaries of scientific exploration.