136 lines
6.8 KiB
Plaintext
136 lines
6.8 KiB
Plaintext
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The following is an article published in "Video Computing (tm)", The
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Journal Of Interactive Video And Optical Storage Application. Published
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by VideoSoft. November/December 1988 issue.
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DISK STORAGE REACHES MOLECULAR LEVEL
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~~~~ ~~~~~~~ ~~~~~~~ ~~~~~~~~~ ~~~~~
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Forget disc capacity as we know it: 550 megabytes on a CD-ROM; 108,000
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frames on a videodisc; 4 gigabytes on a 14-inch optical disc. These will
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all become insignificant as Martin Marietta's new optical storage system
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works at a terabyte per square centimeter capacity, in half the current
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access time.
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OAK RIDGE, Tennessee -- Researchers at Oak Ridge National Laboratory
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(ORNL), have invented a new optical storage technology capable of turning
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a single molecule on an optical disc into a storage point.
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ORNL, part of the Department of Energy and one of the largest
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government research laboratories, is operated by Martin Marietta Energy
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Systems. The department has transferred the rights to Martin Marietta,
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which is now in the process of patenting and licensing the technology.
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Energy Systems has started to solicit interested companies for possible
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licensing agreements.
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The most common methods for writing on optical discs use lasers
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to burn pits or micron-sized holes or change the polarity of individual
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data points in substrate sandwiched between two layers of polycarbonate.
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The hardware then "reads" the change in the position of the reflected
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laser's beam. The new system uses a laser or radiation beam similar to
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current systems. But the unique featurea of ORNL's technology is in its
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ability to go to the molecular level.
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A VIDEO COMPUTING reporter talked with Mr. Guven Yalcintas
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(pronounced Yal*sin*tosh), Martin Marietta's licensing director.
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V.C.: Currently we use lasers to burn pits or blisters into substrate.
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What are you doing that is different?
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Mr. Yalcintas: We will license this technology to one of the companies,
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an American company. We would like to protect the patentable ideas. Our
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discussion will take place within that limit. In today's technology,
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optical disk technology, the lasers are simply burning a hole. Well, you
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can do that in this technology, too. What is new is we can write to the
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media without burning the hole. We can make changes in the molecular
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level.
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V.C.: Are you referring to changes in the polarity?
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Mr. Yalcintas: Yes indeed. You can change the polarity of the molecule
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or you can identify that molecule as plus or minus, zeroes or ones
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becoming information.
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V.C.: How do you read back the information?
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Mr. Yalcintas: Whatever source we use to change that information at the
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molecular level is the same source that receives it back.
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V.C.: We currently use lasers to do that. Are you using a laser?
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Mr. Yalcintas: Yes. In fact, the laser we use has much lower power that
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modifies the molecule.
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V.C.: Is this technology erasable?
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Mr. Yalcintas: This is WORM technology. You sensitize the substrate and
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place the information covered with the plastic coating and the
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information is going to stay there.
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V.C.: Has anyone talked about the possibility of making it erasable?
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Mr. Yalcintas: No. Let me go one step back. ORNL is a government
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laboratory. It is operated by Martin Marietta for the Department of
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Energy. What goes on over here every day with 5,000 plus scientists is
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basic research. The research this group of scientists is working on is
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a project to identify a trace amount of organic compounds in order to be
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able to develop a sensor, a detecting system for minute amounts of
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organic compounds. We have developed very nice operating radiation
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detectors. While they were working on that research, they figured out
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that they could leave information on a substrate with a laser. The
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research was not directed at optical discs to store information as
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WORM or erasable. One day, other research may find some easy way to
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deal with that. Right now it's not the topic. Right now we are
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finding out every day that WORM technology is in great demand. The
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IRS wants WORM technology, the Navy wants WORM technology. The nuclear
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regulatory commission wants to check data on reactors. It doesn't want
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that data to be changed. For one reason, there is no funding for that,
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and second, we don't believe there is any reason to erase. With this
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volume of storage you don't need to erase, you just keep on storing.
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V.C.: How much data can you store?
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Mr. Yalcintas: Roughly, the size of the molecule is 10 -6E (0.000001)
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centimeters, in one square centimeter you then have 10 12E molecules.
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If each molecule is a potential storage spot for the data, then you
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have 10 12E bytes in one square centimeter (1,000,000,000,000... one
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trillion bytes per centimeter!). If you pick up a disc with 500 million
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storage spots (present day CD-ROM), in the same size storage disc you are
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going to have probably 500 million times one million storage spots.
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That's why people are really fascinated.
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V.C.: I take it that the technology is at a fundamental level of
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research. Have you done a "blackbox" yet?
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Mr. Yalcintas: No, and we are probably not going to. This office
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receives 15 to 20 inventions per month. We analyze them and try to
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license them. If there is a stumbling block with industry, we can go
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out one more step to develop. We have maturation funding we can use
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for further study, but for this project I don't believe it will be
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necessary. When we show the data, people are fascinated.
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V.C.: Have you licensed the technology yet?
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Mr. Yalcintas: We have been talking to over 40 companies, 15 of which
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requested non-disclosure information. Four of them have already signed,
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and we have released full information to them.
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V.C.: What are other advantages of your new technology?
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Mr. Yalcintas: You can specify what part of the information can be
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accessed for security purposes. It can be made secure, so the
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military will be delighted. You can identify an access frequency for
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someone and he can't read the rest of the disc. Also, much more
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information can be entered at current optical disc speeds. The speed
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for current optical discs is identified at somewhere near 1800 to 1900
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rpm. I have heard of some to 3000 rpm. Winchesters are somewhere near
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3600 rpm. This is just a concept, it has not been tried, but we have
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reason to believe very strongly that you can apply two substrates instead
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of one. With the same laser, or frequency, you will be receiving two
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different signals from two different substrates. At the same speed at
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the same spot, two sets of information will be coming to you. Two
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different molecules, with two different signals.
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