Researchers Create Shiny Rainbows of Nanotech Chocolate

Chocolate is the latest material to be colorized by nanotechnology instead of chemical dyes

2 min read
3 pieces of chocolate shimmer due to a special surface imprint that produces what the scientists refer to as a structural colour.
Photo: Giulia Marthaler/ETH Zurich

While so many of us are working at home during the coronavirus pandemic, we do worry that serendipitous hallway conversations aren’t happening.

Last year, before the pandemic, it was one of those conversations that led researchers at ETH Zurich to develop a way of making chocolates shimmer with color—without any coloring agents or other additives.

Gif of shimmering chocolate Gif: Giulia Marthaler/ETH Zurich

The project, announced in December, involves what the scientists call “structural color”. The team indicated that it creates colors in a way similar to what a chameleon does—that is, using the structure of its skin to  scatter a particular wavelength of light. The researchers have yet to release details, but Alissa M. Fitzgerald, founder of MEMS product development firm AMFitzgerald, has a pretty good guess.

She explains that Iridescence in nature (like that inside oyster shells and on the wings of butterflies) involves nanoscale patterns in the form of lines, plates, or holes. To make iridescent chocolate, she surmises, the researchers likely created a nanotech chocolate mold, using e-beam lithography to etch lines of about 100 nm wide on a glass or silicon wafer.

The ETH researchers hope to get their technique for coloring chocolate out of the lab and into the mass market. Meanwhile, during the pandemic shutdown, some tech professionals have been playing with rainbow chocolates of their own, like software engineer and startup founder Samy Kamkar, recently profiled in the New York Times. (You can only bake so much bread, after all.)

Chocolate is only the beginning for nanocolors, Fitzgerald says: “The combination of nano- and micro-technology fabrication techniques with atypical materials like food, fabric, paper and plastic is going to lead to some really exciting new products as well as improve or enhance existing products. For example, Teijin Fiber Japan uses structural color methods to make “Morphotex” fabric, named after the iridescent Morpho butterfly, recently demonstrated in the concept Morphotex Dress. Everyday objects are poised to benefit from advances in nanotechnology.”

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A Circuit to Boost Battery Life

Digital low-dropout voltage regulators will save time, money, and power

11 min read
Image of a battery held sideways by pliers on each side.
Edmon de Haro

YOU'VE PROBABLY PLAYED hundreds, maybe thousands, of videos on your smartphone. But have you ever thought about what happens when you press “play”?

The instant you touch that little triangle, many things happen at once. In microseconds, idle compute cores on your phone's processor spring to life. As they do so, their voltages and clock frequencies shoot up to ensure that the video decompresses and displays without delay. Meanwhile, other cores, running tasks in the background, throttle down. Charge surges into the active cores' millions of transistors and slows to a trickle in the newly idled ones.

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