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| Carbon nanotubes fit by the thousands onto a chip | Carbon nanotubes fit by the thousands onto a chip |
| (about 5 hours later) | |
| By Jason Palmer Science and technology reporter, BBC News | By Jason Palmer Science and technology reporter, BBC News |
| Scientists have demonstrated methods that could see higher-performance computer chips made from tiny straws of carbon called nanotubes. | Scientists have demonstrated methods that could see higher-performance computer chips made from tiny straws of carbon called nanotubes. |
| Carbon nanotubes have long been known to have electronic properties superior to current silicon-based devices. | Carbon nanotubes have long been known to have electronic properties superior to current silicon-based devices. |
| But difficulties in manipulating them have hampered nanotube-based chips. | But difficulties in manipulating them have hampered nanotube-based chips. |
| The experiments, reported in Nature Nanotechnology, show a kind of two-part epoxy approach to individually place the nanotubes at high density. | |
| The race is on in the semiconductor chip industry to replace current silicon technology - methods to make smaller and therefore faster devices will soon come up against physical limits on just how small a silicon device can be. | The race is on in the semiconductor chip industry to replace current silicon technology - methods to make smaller and therefore faster devices will soon come up against physical limits on just how small a silicon device can be. |
| Study co-author James Hannon, a materials scientist at IBM, said that there are few realistic successors to silicon's throne. | Study co-author James Hannon, a materials scientist at IBM, said that there are few realistic successors to silicon's throne. |
| "The problem is you have to put it in to production on a 10- or 15-year time scale, so the kinks have to be worked out in the next few years," he said. | "The problem is you have to put it in to production on a 10- or 15-year time scale, so the kinks have to be worked out in the next few years," he said. |
| "If you look at all the possibilities out there, there are very few that have actually produced an electronic device that would outperform silicon - there are exotic things out there but they're all still at the 'PowerPoint stage'." | "If you look at all the possibilities out there, there are very few that have actually produced an electronic device that would outperform silicon - there are exotic things out there but they're all still at the 'PowerPoint stage'." |
| Though single nanotubes have shown vastly superior speed and energy characteristics in lab demonstrations, the challenge has been in so-called integration - getting billions of them placed onto a chip with the precision the industry now demands. | Though single nanotubes have shown vastly superior speed and energy characteristics in lab demonstrations, the challenge has been in so-called integration - getting billions of them placed onto a chip with the precision the industry now demands. |
| Superior speed | Superior speed |
| Current chips are made using lithography, in which large wafers of silicon are layered with other materials of different electronic properties and then devices are simply "etched" out using a focused beam of electrons or charged atoms. | Current chips are made using lithography, in which large wafers of silicon are layered with other materials of different electronic properties and then devices are simply "etched" out using a focused beam of electrons or charged atoms. |
| To address the integration challenge, Dr Hannon and his colleagues came up with a solution - two of them in fact. | To address the integration challenge, Dr Hannon and his colleagues came up with a solution - two of them in fact. |
| The first was a chemical that coats nanotubes and makes them soluble in water. | The first was a chemical that coats nanotubes and makes them soluble in water. |
| The second was a solution that binds to the first chemical and to the element hafnium, but not to silicon. | The second was a solution that binds to the first chemical and to the element hafnium, but not to silicon. |
| The team used standard techniques to etch a pattern of channels in hafnium deposited on silicon. | The team used standard techniques to etch a pattern of channels in hafnium deposited on silicon. |
| Then they simply "double-dipped" the chip into the two solutions - one chemical stuck to the hafnium, and the other chemical acted as the second part of a two-part epoxy, tightly binding nanotubes to the hafnium regions on the chip but not to silicon. | Then they simply "double-dipped" the chip into the two solutions - one chemical stuck to the hafnium, and the other chemical acted as the second part of a two-part epoxy, tightly binding nanotubes to the hafnium regions on the chip but not to silicon. |
| The result was a series of neatly aligned nanotube devices, already wired up within the pattern, at a density of a billion per square centimetre. | The result was a series of neatly aligned nanotube devices, already wired up within the pattern, at a density of a billion per square centimetre. |
| Challenges remain | Challenges remain |
| "That's one nanotube every 150 or 200 (billionths of a metre) or so," explained Dr Hannon. "That's not good enough to make a microprocessor yet - it's a factor of 10 away. | "That's one nanotube every 150 or 200 (billionths of a metre) or so," explained Dr Hannon. "That's not good enough to make a microprocessor yet - it's a factor of 10 away. |
| "But it's a factor of 100 better than has been done previously." | "But it's a factor of 100 better than has been done previously." |
| The demonstration is a "huge improvement", but Dr Hannon said several issues are still to be solved. | The demonstration is a "huge improvement", but Dr Hannon said several issues are still to be solved. |
| They incude finding more efficient ways to sort through nanotubes - which are made in a wide variety of sizes and types - to select in large quantity and high accuracy the kind suitable for devices. | They incude finding more efficient ways to sort through nanotubes - which are made in a wide variety of sizes and types - to select in large quantity and high accuracy the kind suitable for devices. |
| The etching process that sets the ultimate size of a transistor on the chip must also be improved. | The etching process that sets the ultimate size of a transistor on the chip must also be improved. |
| For now, the team has modelled what it can do with the technique in its current form - a vast array of transistors, each comprising six nanotubes spaced 10 nanometres apart. | For now, the team has modelled what it can do with the technique in its current form - a vast array of transistors, each comprising six nanotubes spaced 10 nanometres apart. |
| Their models suggest a 10-fold jump in performance - a chip run at more than three times the frequency and consuming just a third the energy. | Their models suggest a 10-fold jump in performance - a chip run at more than three times the frequency and consuming just a third the energy. |
| However, in the longer term, nanotube chips would run up against the same limits that silicon faces; as Dr Hannon puts it, "we're limited by the size of an atom eventually". | However, in the longer term, nanotube chips would run up against the same limits that silicon faces; as Dr Hannon puts it, "we're limited by the size of an atom eventually". |
| "But this at least gives us a way to gain performance while shrinking the device." | "But this at least gives us a way to gain performance while shrinking the device." |
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