Tag Archives: Paul Smith

Xerox Research Centre Canada (XRCC) forms a materials alliance with Battelle Memorial Institute

Could this be described as an example of Canadian innovation? Xerox Research Centre Canada (XRCC) has signed a document with Battelle Memorial institute according to a May 8, 2014 news item on Nanowerk,

The Xerox Research Centre Canada (XRCC) and Battelle Memorial Institute have signed a strategic alliance to co-market and collaborate on materials science research services.

The alliance will allow clients of XRCC and Battelle to access the deep capabilities of the two renowned research organizations – including the use of XRCC`s pilot plant and manufacturing scale-up facility – to augment their own resources in developing and bringing new products to market. [emphasis mine]

Does anyone know if the XRCC pilot plant and/or the manufacturing scale-up facility received any Canadian government funding or tax credits? If so, it would appear that Canadian taxpayers have paid for a facility that will be used to develop materials for sale by a US-based organization. It is entirely possible that those materials could be sold back to Canadian institutions at a hefty profit for Battelle.

A May 8, 2014 Xerox news release (available on the Xerox.com site but not the XRCC.ca site), which originated the news item, provides more details (Note: Links have been removed),

Both XRCC and Battelle also expect the alliance will attract new innovation services customers. “Tapping into the strong capabilities of Xerox and Battelle is an agile and cost-effective way for businesses and government to add value, improve performance, gain competitive edge…or create something entirely new,” said Martin Toomajian, Battelle president of energy, health and environment.

Scientists at XRCC specialize in the design and development of electronic materials PDF file and specialty components; environmentally responsible processes PDF file; coatings, applied nanotechnology PDF file; polymer science PDF file, engineering and pilot plant scale-up PDF file. XRCC is part of the global Xerox Innovation Group, comprised of five research centers around the globe that each leverage XRCC’s unique, integrated, global materials research and development mandate.

Battelle manages the world’s leading national laboratories and maintains a contract research portfolio spanning consumer and industrial, energy and environment, health and pharmaceutical and national security. From large government agencies and multi-national corporations to small start-ups and incubator projects, Battelle provides the resources, brainpower and flexibility to fulfill client needs.

Battelle and Xerox share a unique historical connection. One of Battelle’s early clients was Chester Carlson whose invention of xerography launched Xerox Corporation. Seventy years ago, the two signed an agreement that provided Carlson with access to the Battelle labs in the interest of collaborative research, development and engineering work. Today’s announcement marks the beginning of the next generation of collaboration between two of the world’s most renowned innovation organizations.

Intriguingly, the ‘About’ section of the news release does not include XRCC (Note: Links have been removed),

About Xerox
Since the invention of Xerography more than 75 years ago, the people of Xerox (NYSE: XRX) have helped businesses simplify the way work gets done. Today, we are the global leader in business process and document management, helping organizations of any size be more efficient so they can focus on their real business. Headquartered in Norwalk, Conn., we have more than 140,000 Xerox employees and do business in more than 180 countries, providing business services, printing equipment and software for commercial and government organizations. Learn more at www.xerox.com.

About Battelle
Every day, the people of Battelle apply science and technology to solving what matters most. At major technology centers and national laboratories around the world, Battelle conducts research and development, designs and manufactures products, and delivers critical services for government and commercial customers. Headquartered in Columbus, Ohio since its founding in 1929, Battelle serves the national security, health and life sciences, and energy and environmental industries. For more information, visit www.battelle.org.

Earlier this year in an April 4, 2014 posting, I featured another XRCC deal where I questioned its relationship to Canadian innovation,

An April 1, 2014 news item on labcanada.com describes a recently signed deal which may turn up the competition in Canada’s currency authentication business sector,

The Xerox Research Centre Canada [XRCC] says it has signed a multi-year materials research services agreement with Dallas-based Authentix, a provider of anti-counterfeiting, brand protection and program integrity solutions for the oil and gas industry; currency, branded products and tax stamp markets.

“Working with companies like Authentix adds to the value our scientists bring to the research world,” said Paul Smith, vice president and director of the Xerox Research Centre Canada. “Not only do we continue to strengthen our scientific role in Canadian innovation, we are now bringing valuable research capabilities to other companies globally.” [emphasis mine]

Given that Xerox is a US company with a Canadian branch, I’m not sure how signing a deal with another US company aids Canadian innovation. On the plus side, it does give some Canadian scientists a job.

Xerox Research Centre Canada, authentic currency, etc. and a ‘nano’ deal with Authentix

An April 1, 2014 news item on labcanada.com describes a recently signed deal which may turn up the competition in Canada’s currency authentication business sector,

The Xerox Research Centre Canada [XRCC] says it has signed a multi-year materials research services agreement with Dallas-based Authentix, a provider of anti-counterfeiting, brand protection and program integrity solutions for the oil and gas industry; currency, branded products and tax stamp markets.

“Working with companies like Authentix adds to the value our scientists bring to the research world,” said Paul Smith, vice president and director of the Xerox Research Centre Canada. “Not only do we continue to strengthen our scientific role in Canadian innovation, we are now bringing valuable research capabilities to other companies globally.”

Given that Xerox is a US company with a Canadian branch, I’m not sure how signing a deal with another US company aids Canadian innovation. On the plus side, it does give some Canadian scientists a job.

I also noted the reference to “currency authentication”, which suggests that Authentix could be in direct competition with the Canadian company, Nanotech Security Corp. (I have written about Nanotech Security Corp. previously with the two most recent being a Jan. 31, 2014 posting about the company’s presentation at an Optical Document Security Conference and a March 17, 2014 posting about the company’s first commercial client, TED.) Perhaps Xerox plans to spur Canadian innovation by providing more competition for our technology companies.

Here’s more from the March 31, 2014 Xerox news release, which originated the news item about the deal with Authentix,

Scientists at XRCC specialize in the design and development of electronic materials and specialty components; environmentally-friendly processes; coatings, applied nanotechnology; polymer science, engineering and pilot plant scale-up. [emphasis mine]

“Materials science research makes it possible to bring new levels of security, accuracy and efficiency to product authentication,” said Jeff Conroy, chief technology officer of Authentix.  “Leveraging the core competencies of Xerox’s materials lab in Canada expands and accelerates our ability to bring innovative solutions to the authentication market.”

Located near Toronto, XRCC is part of the global Xerox Innovation Group made up of researchers and engineers in five world-renowned research centers. Each center leverages XRCC’s unique, integrated, global materials research and development mandate.

You can find out more about Authentix here.

Getting back to XRCC, they had a longstanding relationship with Canada’s National Institute of Nanotechnology (NINT) having signed a 2007 contract with NINT and the Government of Alberta, from a Xerox Innovation Story,

In Canada’s first major public-private nanotechnology research partnership, the Xerox Research Centre of Canada (XRCC), NRC National Institute for Nanotechnology (NINT) and Government of Alberta will provide approximately $4.5 million for research and development of materials-based nanotechnology over the next three years.

The three partners will invest funds, human resources, and available infrastructures to create a research program and teams focused on developing commercially successful nanotechnology-based discoveries. Personnel from NINT and XRCC will collaborate on research projects at NINT in Edmonton, Alberta, and at XRCC in Mississauga, Ontario.

The funds will contribute to the hiring of eight to 10 scientists who will investigate materials-based nanotechnologies, including document- and display-related technologies. The research program, co-managed by XRCC and NINT, will allow access to Xerox’s experience in successfully commercializing technology to facilitate the market application of resulting inventions.

“This level of public and private sector partnership helps fuel the type of innovation that will keep Alberta, and Canada as a whole, strong and competitive in an increasingly global, knowledge-based economy,” said Doug Horner, minister for Advanced Education and Technology, Government of Alberta. “The investments from the Government of Alberta, Xerox and NINT will build a world-class nanotechnology research program that embraces the spirit of innovation, but also that of commercialization.”

I find the references to Xerox and innovation and commercialization amusing since the company is famous for its innovation missteps. For example, the company owned the photocopying business from the 1960s into the 1970s due to its patent rights but once those rights ran out (there’s usually a time limit on a patent) the company was poorly equipped to compete. My guess is that they didn’t know how in an environment where they no longer held a monopoly. The other famous story concerns the mouse and the graphical user interface both of which were developed at Xerox but the company never pursued those innovations leaving Stephen Jobs and his colleagues to found Apple.

At any rate, Xerox survived those missteps so perhaps they learned something and they really do mean it when they talk about spurring innovation. Although, given the business model for most Canadian technology companies, I expect Nanotech Security Corp. to get purchased by Authentix or one of its competitors with the consequence that Canadian taxpayers have helped to pay, yet again, for innovation that will be purchased by a corporate entity with headquarters in another country and much less interest in maintaining a business presence in Canada. If you think I’m being cynical about another country’s corporate interests in Canada, take a look at this excerpt from Derrick Penner’s March 28, 2014 article for the Vancouver Sun about Vancouver’s recent Globe 2014 conference,

Globe, the biannual conference on sustainable development [March 26 – 28, 2014], is as much about doing business as it is about discussing bright ideas for reducing the impact of industry on the environment.

And a new twist for European delegates, such as Roumeas [Vincent Roumeas, a business development manager for the Paris Region Economic Development Agency], is the prospect of Canada Europe Free Trade.

Prime Minister Stephen Harper and European Commission President José Manuel Barroso, last October, signed an agreement in principal, which commits the two sides to finalizing a full agreement giving each other tariff-free access to each others’ markets.

Roumeas said it is too soon to tell how much of a draw EU free trade will be because he is working on developing immediate prospects within the next 18 months, which would be before any benefits from free trade would kick in, if the deal is concluded.

However, his colleague Jeremy Bernard Orawiec, a trade adviser for UbiFrance, does see the agreement as an attraction for French firms interested the American market.

He added that the U.S. is viewed as a tough market to crack, so Canada is looked at as an easier-accessed entry point to all of North America.

“It’s really positive to see Canada able to make an agreement before the U.S.,” Orawiec said. “It gives us a time frame so (companies) can come here [Canada] and explore the whole American market.” [emphases mine]

It’s not clear from his comments but I suspect Orawiec is unaware that Mexico is part of North America. In any event, Canada as a market place or as an innovation centre is not important in and of itself. One can criticize Orawiec for making those comments but I’d like to thank him as he has expressed an attitude that I believe is widely held.

Controlling crystal growth for plastic electronics

A July 4, 2013 news item on Nanowerk highlights research into plastic electronics taking place at Imperial College London (ICL), Note: A link has been removed,

Scientists have discovered a way to better exploit a process that could revolutionise the way that electronic products are made.

The scientists from Imperial College London say improving the industrial process, which is called crystallisation, could revolutionise the way we produce electronic products, leading to advances across a whole range of fields; including reducing the cost and improving the design of plastic solar cells.

The process of making many well-known products from plastics involves controlling the way that microscopic crystals are formed within the material. By controlling the way that these crystals are grown engineers can determine the properties they want such as transparency and toughness. Controlling the growth of these crystals involves engineers adding small amounts of chemical additives to plastic formulations. This approach is used in making food boxes and other transparent plastic containers, but up until now it has not been used in the electronics industry.

The team from Imperial have now demonstrated that these additives can also be used to improve how an advanced type of flexible circuitry called plastic electronics is made.

The team found that when the additives were included in the formulation of plastic electronic circuitry they could be printed more reliably and over larger areas, which would reduce fabrication costs in the industry.

The team reported their findings this month in the journal Nature Materials (“Microstructure formation in molecular and polymer semiconductors assisted by nucleation agents”).

The June 7, 2013 Imperial College London news release by Joshua Howgego, which originated the news item, describes the researchers and the process in more detail,

Dr Natalie Stingelin, the leader of the study from the Department of Materials and Centre of Plastic Electronics at Imperial, says:

“Essentially, we have demonstrated a simple way to gain control over how crystals grow in electrically conducting ‘plastic’ semiconductors. Not only will this help industry fabricate plastic electronic devices like solar cells and sensors more efficiently. I believe it will also help scientists experimenting in other areas, such as protein crystallisation, an important part of the drug development process.”

Dr Stingelin and research associate Neil Treat looked at two additives, sold under the names IrgaclearÒ XT 386 and MilladÒ 3988, which are commonly used in industry. These chemicals are, for example, some of the ingredients used to improve the transparency of plastic drinking bottles. The researchers experimented with adding tiny amounts of these chemicals to the formulas of several different electrically conducting plastics, which are used in technologies such as security key cards, solar cells and displays.

The researchers found the additives gave them precise control over where crystals would form, meaning they could also control which parts of the printed material would conduct electricity. In addition, the crystallisations happened faster than normal. Usually plastic electronics are exposed to high temperatures to speed up the crystallisation process, but this can degrade the materials. This heat treatment treatment is no longer necessary if the additives are used.

Another industrially important advantage of using small amounts of the additives was that the crystallisation process happened more uniformly throughout the plastics, giving a consistent distribution of crystals.  The team say this could enable circuits in plastic electronics to be produced quickly and easily with roll-to-roll printing procedures similar to those used in the newspaper industry. This has been very challenging to achieve previously.

Dr Treat says: “Our work clearly shows that these additives are really good at controlling how materials crystallise. We have shown that printed electronics can be fabricated more reliably using this strategy. But what’s particularly exciting about all this is that the additives showed fantastic performance in many different types of conducting plastics. So I’m excited about the possibilities that this strategy could have in a wide range of materials.”

Dr Stingelin and Dr Treat collaborated with scientists from the University of California Santa Barbara (UCSB), and the National Renewable Energy Laboratory in Golden, US, and the Swiss Federal Institute of Technology on this study. The team are planning to continue working together to see if subtle chemical changes to the additives improve their effects – and design new additives.

There are some big plans for this discovery, from the news release,

They [the multinational team from ICL, UCSB, National Renewable Energy Laboratory, and Swiss Federal Institute of Technology]  will be working with the new Engineering and Physical Sciences Research Council (EPSRC)-funded Centre for Innovative Manufacturing in Large Area Electronics in order to drive the industrial exploitation of their process. The £5.6 million of funding for this centre, to be led by researchers from Cambridge University, was announced earlier this year [2013]. They are also exploring collaborations with printing companies with a view to further developing their circuit printing technique.

For the curious, here’s a link to and a citation for the published paper,

Microstructure formation in molecular and polymer semiconductors assisted by nucleation agents by Neil D. Treat, Jennifer A. Nekuda Malik, Obadiah Reid, Liyang Yu, Christopher G. Shuttle, Garry Rumbles, Craig J. Hawker, Michael L. Chabinyc, Paul Smith, & Natalie Stingelin. Nature Materials 12, 628–633 (2013) doi:10.1038/nmat3655 Published online 02 June 2013

This article is open access (at least for now).