Tag Archives: ESPCI ParisTech

LiquiGlide, a nanotechnology-enabled coating for food packaging and oil and gas pipelines

Getting condiments out of their bottles should be a lot easier in several European countries in the near future. A June 30, 2015 news item on Nanowerk describes the technology and the business deal (Note: A link has been removed),

The days of wasting condiments — and other products — that stick stubbornly to the sides of their bottles may be gone, thanks to MIT [Massachusetts Institute of Technology] spinout LiquiGlide, which has licensed its nonstick coating to a major consumer-goods company.

Developed in 2009 by MIT’s Kripa Varanasi and David Smith, LiquiGlide is a liquid-impregnated coating that acts as a slippery barrier between a surface and a viscous liquid. Applied inside a condiment bottle, for instance, the coating clings permanently to its sides, while allowing the condiment to glide off completely, with no residue.

In 2012, amidst a flurry of media attention following LiquiGlide’s entry in MIT’s $100K Entrepreneurship Competition, Smith and Varanasi founded the startup — with help from the Institute — to commercialize the coating.

Today [June 30, 2015], Norwegian consumer-goods producer Orkla has signed a licensing agreement to use the LiquiGlide’s coating for mayonnaise products sold in Germany, Scandinavia, and several other European nations. This comes on the heels of another licensing deal, with Elmer’s [Elmer’s Glue & Adhesives], announced in March [2015].

A June 30, 2015 MIT news release, which originated the news item, provides more details about the researcher/entrepreneurs’ plans,

But this is only the beginning, says Varanasi, an associate professor of mechanical engineering who is now on LiquiGlide’s board of directors and chief science advisor. The startup, which just entered the consumer-goods market, is courting deals with numerous producers of foods, beauty supplies, and household products. “Our coatings can work with a whole range of products, because we can tailor each coating to meet the specific requirements of each application,” Varanasi says.

Apart from providing savings and convenience, LiquiGlide aims to reduce the surprising amount of wasted products — especially food — that stick to container sides and get tossed. For instance, in 2009 Consumer Reports found that up to 15 percent of bottled condiments are ultimately thrown away. Keeping bottles clean, Varanasi adds, could also drastically cut the use of water and energy, as well as the costs associated with rinsing bottles before recycling. “It has huge potential in terms of critical sustainability,” he says.

Varanasi says LiquiGlide aims next to tackle buildup in oil and gas pipelines, which can cause corrosion and clogs that reduce flow. [emphasis mine] Future uses, he adds, could include coatings for medical devices such as catheters, deicing roofs and airplane wings, and improving manufacturing and process efficiency. “Interfaces are ubiquitous,” he says. “We want to be everywhere.”

The news release goes on to describe the research process in more detail and offers a plug for MIT’s innovation efforts,

LiquiGlide was originally developed while Smith worked on his graduate research in Varanasi’s research group. Smith and Varanasi were interested in preventing ice buildup on airplane surfaces and methane hydrate buildup in oil and gas pipelines.

Some initial work was on superhydrophobic surfaces, which trap pockets of air and naturally repel water. But both researchers found that these surfaces don’t, in fact, shed every bit of liquid. During phase transitions — when vapor turns to liquid, for instance — water droplets condense within microscopic gaps on surfaces, and steadily accumulate. This leads to loss of anti-icing properties of the surface. “Something that is nonwetting to macroscopic drops does not remain nonwetting for microscopic drops,” Varanasi says.

Inspired by the work of researcher David Quéré, of ESPCI in Paris, on slippery “hemisolid-hemiliquid” surfaces, Varanasi and Smith invented permanently wet “liquid-impregnated surfaces” — coatings that don’t have such microscopic gaps. The coatings consist of textured solid material that traps a liquid lubricant through capillary and intermolecular forces. The coating wicks through the textured solid surface, clinging permanently under the product, allowing the product to slide off the surface easily; other materials can’t enter the gaps or displace the coating. “One can say that it’s a self-lubricating surface,” Varanasi says.

Mixing and matching the materials, however, is a complicated process, Varanasi says. Liquid components of the coating, for instance, must be compatible with the chemical and physical properties of the sticky product, and generally immiscible. The solid material must form a textured structure while adhering to the container. And the coating can’t spoil the contents: Foodstuffs, for instance, require safe, edible materials, such as plants and insoluble fibers.

To help choose ingredients, Smith and Varanasi developed the basic scientific principles and algorithms that calculate how the liquid and solid coating materials, and the product, as well as the geometry of the surface structures will all interact to find the optimal “recipe.”

Today, LiquiGlide develops coatings for clients and licenses the recipes to them. Included are instructions that detail the materials, equipment, and process required to create and apply the coating for their specific needs. “The state of the coating we end up with depends entirely on the properties of the product you want to slide over the surface,” says Smith, now LiquiGlide’s CEO.

Having researched materials for hundreds of different viscous liquids over the years — from peanut butter to crude oil to blood — LiquiGlide also has a database of optimal ingredients for its algorithms to pull from when customizing recipes. “Given any new product you want LiquiGlide for, we can zero in on a solution that meets all requirements necessary,” Varanasi says.

MIT: A lab for entrepreneurs

For years, Smith and Varanasi toyed around with commercial applications for LiquiGlide. But in 2012, with help from MIT’s entrepreneurial ecosystem, LiquiGlide went from lab to market in a matter of months.

Initially the idea was to bring coatings to the oil and gas industry. But one day, in early 2012, Varanasi saw his wife struggling to pour honey from its container. “And I thought, ‘We have a solution for that,’” Varanasi says.

The focus then became consumer packaging. Smith and Varanasi took the idea through several entrepreneurship classes — such as 6.933 (Entrepreneurship in Engineering: The Founder’s Journey) — and MIT’s Venture Mentoring Service and Innovation Teams, where student teams research the commercial potential of MIT technologies.

“I did pretty much every last thing you could do,” Smith says. “Because we have such a brilliant network here at MIT, I thought I should take advantage of it.”

That May [2012], Smith, Varanasi, and several MIT students entered LiquiGlide in the MIT $100K Entrepreneurship Competition, earning the Audience Choice Award — and the national spotlight. A video of ketchup sliding out of a LiquiGlide-coated bottle went viral. Numerous media outlets picked up the story, while hundreds of companies reached out to Varanasi to buy the coating. “My phone didn’t stop ringing, my website crashed for a month,” Varanasi says. “It just went crazy.”

That summer [2012], Smith and Varanasi took their startup idea to MIT’s Global Founders’ Skills Accelerator program, which introduced them to a robust network of local investors and helped them build a solid business plan. Soon after, they raised money from family and friends, and won $100,000 at the MassChallenge Entrepreneurship Competition.

When LiquiGlide Inc. launched in August 2012, clients were already knocking down the door. The startup chose a select number to pay for the development and testing of the coating for its products. Within a year, LiquiGlide was cash-flow positive, and had grown from three to 18 employees in its current Cambridge headquarters.

Looking back, Varanasi attributes much of LiquiGlide’s success to MIT’s innovation-based ecosystem, which promotes rapid prototyping for the marketplace through experimentation and collaboration. This ecosystem includes the Deshpande Center for Technological Innovation, the Martin Trust Center for MIT Entrepreneurship, the Venture Mentoring Service, and the Technology Licensing Office, among other initiatives. “Having a lab where we could think about … translating the technology to real-world applications, and having this ability to meet people, and bounce ideas … that whole MIT ecosystem was key,” Varanasi says.

Here’s the latest LiquiGlide video,


Credits:

Video: Melanie Gonick/MIT
Additional footage courtesy of LiquiGlide™
Music sampled from “Candlepower” by Chris Zabriskie
https://freemusicarchive.org/music/Ch…
http://creativecommons.org/licenses/b…

I had thought the EU (European Union) offered more roadblocks to marketing nanotechnology-enabled products used in food packaging than the US. If anyone knows why a US company would market its products in Europe first I would love to find out.

Mystery of glass—shattered and Happy Canada Day!

I’m pretty sure I’ve said this before but a repetition can’t hurt, “I love glass both for the art and the mystery.” Naturally, I am of two minds about this ‘shattered’ glass mystery from the University of Waterloo (Canada).

A June 29, 2015 University of Waterloo news release (also on EurekAlert) provides a teasing (for impatient people like me) introduction before describing the solution to the mystery,

A physicist at the University of Waterloo is among a team of scientists who have described how glasses form at the molecular level and provided a possible solution to a problem that has stumped scientists for decades.

Their simple theory is expected to open up the study of glasses to non-experts and undergraduates as well as inspire breakthroughs in novel nanomaterials.

The paper published by physicists from the University of Waterloo, McMaster University, ESPCI ParisTech and Université Paris Diderot appeared in the prestigious peer-reviewed journal, Proceedings of the National Academy of Sciences (PNAS).

Glasses are much more than silicon-based materials in bottles and windows. In fact, any solid without an ordered, crystalline structure — metal, plastic, a polymer — that forms a molten liquid when heated above a certain temperature is a glass. Glasses are an essential material in technology, pharmaceuticals, housing, renewable energy and increasingly nano electronics.

“We were surprised — delighted — that the model turned out to be so simple,” said author James Forrest, a University Research Chair and professor in the Faculty of Science. “We were convinced it had already been published.”

The theory relies on two basic concepts: molecular crowding and string-like co-operative movement. [emphasis mine] Molecular crowding describes how molecules within glasses move like people in a crowded room. As the number of people increase, the amount of free volume decreases and the slower people can move through the crowd. Those people next to the door are able to move more freely, just as the surfaces of glasses never actually stop flowing, even at lower temperatures.

The more crowded the room, the more you rely on the co-operative movement with your neighbours to get where you’re going. Likewise, individual molecules within a glass aren’t able to move totally freely. They move with, yet are confined by, strings of weak molecular bonds with their neighbours.

Theories of crowding and cooperative movement are decades old. This is the first time scientists combined both theories to describe how a liquid turns into a glass.

“Research on glasses is normally reserved for specialists in condensed matter physics,” said Forrest, who is also an associate faculty member at Perimeter Institute for Theoretical Physics and a member of the Waterloo Institute for Nanotechnology.  “Now a whole new generation of scientists can study and apply glasses just using first-year calculus.”

Their theory successfully predicts everything from bulk behaviour to surface flow to the once-elusive phenomenon of the glass transition itself. Forrest and colleagues worked for 20 years to bring theory in agreement with decades of observation on glassy materials.

An accurate theory becomes particularly important when trying to understand glass dynamics at the nanoscale. This finding has implications for developing and manufacturing new nanomaterials, such as glasses with conductive properties, or even calculating the uptake of glassy forms of pharmaceuticals.

Here’s a link to and a citation for the paper,

Cooperative strings and glassy interfaces by Thomas Salez, Justin Salez, Kari Dalnoki-Veress, Elie Raphaël, and James A. Forrest. PNAS (Proceedings of the National Academy of Sciences) Published online before print June 22, 2015, doi: 10.1073/pnas.1503133112

This paper is behind a paywall.

Finally and again, Happy Canada Day!