Tag Archives: Hitachi Electron Microscopy Products Development Centre

University of Victoria’s (Canada) microscope, world’s most powerful, unveiled

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This new microscope at the University of Victoria (UVic) was supposed to be unveiled in 2011 according to my July 28, 2009 posting about the purchase,

In other BC news, the University of Victoria (Canada) will be getting a new microscope which senses at subatomic levels. (From the media release on Azonano),

The new microscope-called a Scanning Transmission Electron Holography Microscope (STEHM) — will use an electron beam and holography techniques to observe the inside of materials and their surfaces to an expected resolution as small as one-fiftieth the size of an atom.

This is being done in collaboration with Hitachi High-Technologies which is building the microscope in Japan and installing it at U Vic in late 2010. The microscope will be located in a specially adapted room where work to prepare and calibrate it will continue until it becomes operational sometime in 2011.

I had been wondering if I’d ever hear of the microscope again, so finding a June 18, 2013 news item on Nanowerk announcing the world’s most powerful microscope at the University of Victoria (British Columbia, Canada) answered the question for me (Note: A link has been removed),

The world’s most powerful microscope, which resides in a specially constructed room at the University of Victoria, has now been fully assembled and tested, and has a lineup of scientists and businesses eager to use it.

The seven-tonne, 4.5-metre tall Scanning Transmission Electron Holography Microscope (STEHM), the first such microscope of its type in the world, came to the university in parts last year,. A team from Hitachi, which constructed the ultra high-resolution, ultra-stable instrument, spent one year painstakingly assembling the STEHM in a carefully controlled lab in the basement of the Bob Wright Centre.

The wait was worth it, says Rodney Herring, a professor of mechanical engineering and director of UVic’s Advanced Microscopy Facility. [emphasis mine]

The June 17, 2013 University of Victoria news release, which originated the news item, doesn’t address the two year delay directly as Herring’s quote seems to be in reference to the one-year assembly period. The news release goes on to describe the microscope’s resolution,

Herring viewed gold atoms through the microscope at a resolution of 35 picometres. One picometre is a trillionth of a metre. This resolution is much better than the previous best image with 49-picometre resolution taken at the Lawrence Berkley National Laboratory in California, and is about 20 million times human sight.

The STEHM allows researchers to see the atoms in a manner never before possible. It has full analytical capabilities that can determine the types and number or elements present, and high-resolution cameras for collecting data.

It will be used by researchers of many science and engineering disciplines for projects requiring knowledge of small atomic scale structures (nanoscience) and nanotechnology. Dr. Vincenzo Grillo from the Istituto Nanoscienze Consiglio Nazionale Delle Ricerche in Modena [Italy] will be the first visiting researcher later this month.

A line-up seems to have formed (from the news release),

Local scientists and businesses are also eager to use it. Ned Djilali, a UVic professor of mechanical engineering, is working with the National Research Council, Ballard Power Systems in Vancouver and Mercedes-Benz on fuel cell research. The STEHM “opens up entirely new possibilities” in fuel cell technology, says Djilali.

Redlen Technologies, a local company that manufactures high resolution semiconductor radiation detectors that are used for such things as nuclear cardiology, CT scanning, baggage scanning and dirty bomb detection, has been waiting for the STEHM to open for the company’s research and development.

If you are curious but don’t have any special influence, you can find out about the microscope (and perhaps view it?) later this week (from the news release),

Herring will give details of the results at a microscopy conference this week at UVic, as well as during a talk Thursday, June 20, that is open to the public. [emphasis mine] It is from 4:30 to 5 p.m. at the Bob Wright Centre, in Flury Hall, room B150.

I don’t usually include funding information but since I am from British Columbia, I have more of an interest than usual (from the news release),

The STEHM microscope is supported by $9.2 million in funding from the government of Canada through the Canadian Foundation for Innovation, the BC Knowledge Development Fund and UVic, as well as significant in-kind support from Hitachi.

Since microscopes and big equipment (in general) are weirdly fascinating to me, here are some details from UVic’s STEHM backgrounder,

The Scanning Transmission Electron Holography Microscope (STEHM) is the highest resolution microscope ever built and the only one of its kind in the world. It’s arrival makes the University of Victoria a global leader in the competitive field of advanced microscopy.

Unlike conventional microscopes, which use light to peer at specimens, the STEHM uses an electron beam and holography techniques to observe the inside of materials and their surfaces to an expected resolution smaller than the size of an atom.

The STEHM will see materials beyond the nanoscale to the picoscale. A nanometer is one-billionth of a metre, while a picometre is one-trillionth of a metre. Atoms are typically between 62 and 520 picometres in diameter.

The STEHM will not only see individual atoms, but it will indicate what type of atoms they are. It also features an electron vortex beam, which researchers can use like tweezers to manipulate individual atoms in a specimen.

The microscope itself is a 4.5-metre tall cylinder encased in metal shielding to block magnetic fields. It has a footprint of six square metres and weighs seven tonnes.

The microscope is so huge that researchers will climb a stepladder to insert their specimens through a tiny airlock into the vacuum of the column. They’ll then leave the room, wait for the air currents in the room to calm, and then operate the microscope remotely from an adjoining room.

The microscope is so sensitive that its image could be affected by little more than a passing cloud. …

I don’t know how many times the public will have any access to this microscope given its extreme sensitivity so you might want to make a point of attending the public talk on Thursday, June 20, 2013 at the University of Victoria.

One final comment, I find it a bit disconcerting that the only ‘academic’ research mentioned seems to be Italian and that the ‘Canadian’ research is primarily commercial. It’s very nice that Dr. Herring saw a gold nanoparticle but are there any local or Canadian publicly funded academic researchers using this microscope, which seems to have been paid for by taxpayers? Hopefully, this is a case where excitement took over and the writer who almost always focuses on local, academic research got carried away with the international involvement and big name companies (Mercedes Benz).

Canada’s National Institute of Nanotechnology gets first Hitachi H-95000 microscope outside of Japan

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Canada’s National Institute of Nanotechnology (NINT) has just opened a facility (which was mentioned as a future project in my July 20, 2009 posting) with three new Hitachi microscopes in a $15M funding partnership. From the July 13, 2011 article by Dave Cooper for the Edmonton Journal,

The Hitachi Electron Microscopy Products Centre [HEMiC; Note: This was formerly called the Hitachi Electron Microscopy Products Development Centre] at NINT opened Tuesday, a $15-million partnership between the federal and provincial governments and Hitachi, that marks the entry of Edmonton as the North American microscope leader.

One of the three new machines -the H-9500 environmental transmission electron microscope -is so new it is only the second in the world after one at a Toyota research centre in Japan.

“This technology suite (of three new microscopes) has enabled Alberta and Canada to establish a centre that will be the leading edge of nanotechnology research and development for many years to come,” Hidehito Obayashi, chairman of Hitachi High Technologies, said Tuesday.

I found some more information about the H-9500 microscope in this July 13, 2011 news item on Nanowerk,

The Hitachi H-9500 Environmental transmission electron microscope (ETEM) can study in-situ chemical reactions of samples in liquids and gases. It will offer a very low background pressure (in the 10-8 torr region) ensuring low sample contamination rate and low effect of background gases on the in-situ experiment. Its capabilities include the possibility to heat the sample to temperatures exceeding 1500° C while exposed to various gases or study liquid samples at temperatures exceeding 300° C. The analytical capabilities of the instrument include electron energy loss spectroscopy and energy dispersive X-ray spectrometry for chemical analysis. This instrument offers standard TEM imaging and diffraction capabilities allowing the investigation of sample structure and morphology.

As for the HEMiC facility (more from the news item on Nanowerk),

HEMiC will have two streams of activity: the provision of a wide range of electron microscopy services to industrial and academic clients; and a research collaboration between NINT and Hitachi researchers that will develop new electron microscope tools and techniques. The Centre will also be a Hitachi reference site, allowing Hitachi to showcase its latest microscopes, giving potential clients from North America an opportunity to gain hands-on experience with new instruments and techniques before buying.

I have mused on this before but I really do wonder what happens when there’s a scheduling conflict between research interests and commercial interests. In other words, what happens when you need to use the microscope for research purposes at the same time the sales people want to show it to potential customers? What is the protocol and who decides?

Responsible science communication and magic bullets; lego and pasta analogies; sing about physics

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Cancer’s ‘magic bullet],  a term which has been around for decades, is falling into disuse and deservedly. So it’s disturbing to see it used by someone in McGill University’s (Montreal, Canada) communications department for a recent breakthrough by their researchers.

The reason ‘magic bullet for cancer’ has been falling into is disuse because it does not function well as a metaphor with what we now know about biology. (The term itself dates from the 19th century and chemist, Paul Erlich.) It continues to exist because it’s an easy (and lazy) way to get attention and headlines. Unfortunately, hyperbolic writing of this type obscures the extraordinary and exciting work that researchers are accomplishing. From the news release on the McGill website (also available on Nanowerk here),

A team of McGill Chemistry Department researchers led by Dr. Hanadi Sleiman has achieved a major breakthrough in the development of nanotubes – tiny “magic bullets” that could one day deliver drugs to specific diseased cells.

The lead researcher seems less inclined to irresponsible hyperbole,

One of the possible future applications for this discovery is cancer treatment. However, Sleiman cautions, “we are still far from being able to treat diseases using this technology; this is only a step in that direction. Researchers need to learn how to take these DNA nanostructures, such as the nanotubes here, and bring them back to biology to solve problems in nanomedicine, from drug delivery, to tissue engineering to sensors,” she said.

You’ll notice that the researcher says these ‘DNA nanotubes’ have to be brought “back to biology.” This comment brought to mind a recent post on 2020 Science (Andrew Maynard’s blog) about noted chemist and nanoscientist’s, George Whitesides, concerns/doubts about the direction for cancer and nanotechnology research. From Andrew’s post,

Cancer treatment has been a poster-child for nanotechnology for almost as long as I’ve been involved with the field. As far back as in 1999, a brochure on nanotechnology published by the US government described future “synthetic anti-body-like nanoscale drugs or devices that might seek out and destroy malignant cells wherever they might be in the body.”

So I was somewhat surprised to see the eminent chemist and nano-scientist George Whitesides questioning how much progress we’ve made in developing nanotechnology-based cancer treatments, in an article published in the Columbia Chronicle.

Whitesides comments are quite illuminating (from the article, Microscopic particles have huge possibilites [sic], by Ivana Susic,

George Whitesides, professor of chemistry and chemical biology at Harvard University, said that while the technology sounds impressive, he thinks the focus should be on using nanoparticles in imaging and diagnosing, not treatment.

The problem lies in being able to deliver the treatment to the right cells, and Whitesides said this has proven difficult.

“Cancer cells are abnormal cells, but they’re still us,” he said. [emphasis is mine]

The nanoparticles sent in to destroy the cancer cells may also destroy unaffected cells, because they can sometimes have cancer markers even if they’re healthy. Tumors have also been known to be “genetically flexible” and mutate around several different therapies, Whitesides explained. This keeps them from getting recognized by the therapeutic drugs.

The other problem with targeting cancer cells is the likelihood that only large tumors will be targeted, missing smaller clumps of developing tumors.

“We need something that finds isolated [cancer] clumps that’s somewhere else in the tissue … it’s not a tumor, it’s a whole bunch of tumors,” Whitesides said.

The upside to the treatment possibilities is that they buy the patient time, he said, which is very important to many cancer patients.

“It’s easy to say that one is going to have a particle that’s going to recognize the tumor once it gets there and will do something that triggers the death of the cell, it’s just that we don’t know how to do either one of these parts,” he said.

There is no simple solution. The more scientists learn about biology the more complicated it becomes, not less. [emphasis is mine] Whitesides said one effective way to deal with cancer is to reduce the risk of getting it by reducing the environmental factors that lead to cancer.

It’s a biology problem, not a particle problem,” he said. [emphasis is mine]

If you are interested , do read Andrew’s post and the comments that follow as well as the article that includes Whitesides’ comments and quotes from Andrew in his guise as Chief Science Advisor for the Project on Emerging Nanotechnologies.

All of this discussion follows on yesterday’s (Mar.17.10) post about how confusing inaccurate science reporting can be.

Moving onwards to two analogies, lego and pasta. Researchers at the University of Glasgow have ‘built’ inorganic (not carbon-based) molecular structures which could potentionally be used as more energy efficient and environmentally friendly catalysts for industrial purposes. From the news item on Nanowerk,

Researchers within the Department of Chemistry created hollow cube-based frameworks from polyoxometalates (POMs) – complex compounds made from metal and oxygen atoms – which stick together like LEGO bricks meaning a whole range of well-defined architectures can be developed with great ease.

The molecular sensing aspects of this new material are related to the potassium and lithium ions, which sit loosely in cavities in the framework. These can be displaced by other positively charged ions such as transition metals or small organic molecules while at the same time leaving the framework intact.

These characteristics highlight some of the many potential uses and applications of POM frameworks, but their principle application is their use as catalysts – a molecule used to start or speed-up a chemical reaction making it more efficient, cost-effective and environmentally friendly.

Moving from lego to pasta with a short stop at the movies, we have MIT researchers describing how they and their team have found a way to ‘imprint’ computer chips by using a new electron-beam lithography process to encourage copolymers to self-assemble on the chip. (Currently, manufacturers use light lasers in a photolithographic process which is becoming less effective as chips grow ever smaller and light waves become too large to use.) From the news item on Nanowerk,

The new technique uses “copolymers” made of two different types of polymer. Berggren [Karl] compares a copolymer molecule to the characters played by Robert De Niro and Charles Grodin in the movie Midnight Run, a bounty hunter and a white-collar criminal who are handcuffed together but can’t stand each other. Ross [Caroline] prefers a homelier analogy: “You can think of it like a piece of spaghetti joined to a piece of tagliatelle,” she says. “These two chains don’t like to mix. So given the choice, all the spaghetti ends would go here, and all the tagliatelle ends would go there, but they can’t, because they’re joined together.” In their attempts to segregate themselves, the different types of polymer chain arrange themselves into predictable patterns. By varying the length of the chains, the proportions of the two polymers, and the shape and location of the silicon hitching posts, Ross, Berggren, and their colleagues were able to produce a wide range of patterns useful in circuit design.

ETA (March 18,2010): Dexter Johnson at Nanoclast continues with his his posts (maybe these will form a series?) about more accuracy in reporting, specifically the news item I’ve just highlighted. Check it out here.

To finish on a completely different note (pun intended), I have a link (courtesy of Dave Bruggeman of the Pasco Phronesis blog by way of the Science Cheerleader blog) to a website eponymously (not sure that’s the right term) named physicssongs.org. Do enjoy such titles as: I got Physics; Snel’s Law – Macarena Style!; and much, much more.

Tomorrow: I’m not sure if I’ll have time to do much more than link to it and point to some commentary but the UK’s Nanotechnologies Strategy has just been been released today.

Alberta welcomes a new nanotechnology product and research centre plus some news on a kissing phone

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The new facility will be called the Hitachi Electron Microscopy Products Development Centre (HEMiC) at Canada’s National Institute of Nanotechnology (NINT) at the University of Alberta, Edmonton. From the media release (on Azonano),

“Alberta’s strength in nanotechnologies, and the province’s coordinated strategy for nanotechnology made our decision to seek a partnership here easy,” said John Cole, President of Hitachi High-Technologies Canada, Inc. “This initiative engages Hitachi with Alberta’s nanotechnology community at the leading edge of research while contributing to commercial opportunities.”

The Centre will house three new electron microscopes valued at $7 million, including the first-ever Hitachi environmental transmission electron microscope Model H-9500 in operation outside of Japan.

There are many quotes in the media release, surprisingly, none from Dr. Nils Petersen, NINT’s  Director General.

Fast Company is featuring an article by Kit Eaton about phones that won’t require buttons for control (more touch screen-type technology but introducing a new level of innovation). As it turns out, these phones will be coming from Nokia. Kissing the phone as a gesture that you want to contact a loved is just one of the ideas being explored. More here including a Nokia video about the project. The product designers are looking at how people gesture and, depending on your culture, the meaning behind gestures can vary greatly as the Nokia designer notes in the video. Anyway, this type of project relates to my interest in multimodal discourse and my suspicion that we won’t be writing (or for the matter reading) as much as we do now.

Rob Annan over at Don’t leave Canada behind has picked up on my series of last week’s about innovation in Canada, in his posting Canada not simply hewers and drawers.