Transmissionselektronmikroskopbild av silicon-28 nanotråd med ett lager av kiseldioxid på ytan. Kredit:Matthew R. Jones och Muhua Sun/Rice University
Forskare har visat ett nytt material som leder värme 150 % mer effektivt än konventionella material som används i avancerad chipteknologi.
Enheten – en ultratunn nanotråd av kisel – skulle kunna möjliggöra mindre, snabbare mikroelektronik med en värmeöverföringseffektivitet som överträffar nuvarande teknologier. Elektroniska enheter som drivs av mikrochips som effektivt leder bort värme skulle i sin tur förbruka mindre energi – en förbättring som kan bidra till att minska förbrukningen av energi som produceras genom att förbränna kolrika fossila bränslen som har bidragit till den globala uppvärmningen.
"Genom att övervinna kiselns naturliga begränsningar i dess förmåga att leda värme, tar vår upptäckt ett hinder i mikrochipsteknik", säger Junqiao Wu, vetenskapsmannen som ledde Physical Review Letters studie som rapporterar den nya enheten. Wu är en fakultetsforskare vid Materials Sciences Division och professor i materialvetenskap och teknik vid UC Berkeley.
Värmens långsamma flöde genom kisel
Vår elektronik är relativt prisvärd eftersom kisel – det valda materialet för datorchips – är billigt och rikligt. Men även om kisel är en bra ledare av elektricitet, är det inte en bra ledare av värme när det reduceras till mycket små storlekar - och när det kommer till snabb beräkning utgör det ett stort problem för små mikrochips.
Inom varje mikrochip finns tiotals miljarder kiseltransistorer som styr flödet av elektroner in och ut ur minnesceller och kodar databitar som ettor och nollor, datorernas binära språk. Elektriska strömmar går mellan dessa hårt arbetande transistorer, och dessa strömmar genererar oundvikligen värme.
Värme flödar naturligt från ett varmt föremål till ett kallt föremål. Men värmeflödet blir knepigt i kisel.
I sin naturliga form består kisel av tre olika isotoper - former av ett kemiskt element som innehåller lika många protoner men olika antal neutroner (därav olika massa) i deras kärnor.
Cirka 92% av kisel består av isotopen silicon-28, som har 14 protoner och 14 neutroner; cirka 5 % är kisel-29, med en vikt på 14 protoner och 15 neutroner; och bara 3% är kisel-30, en relativ tungviktare med 14 protoner och 16 neutroner, förklarade medförfattaren Joel Ager, som innehar titlar som senior vetenskapsman vid Berkeley Labs Materials Sciences Division och adjungerad professor i materialvetenskap och ingenjörsvetenskap vid UC Berkeley.
As phonons, the waves of atomic vibration that carry heat, wind their way through silicon's crystalline structure, their direction changes when they bump into silicon-29 or silicon-30, whose different atomic masses "confuse" the phonons, slowing them down.
"The phonons eventually get the idea and find their way to the cold end to cool the silicon material," but this indirect path allows waste heat to build up, which in turn slows your computer down, too, Ager said.
A big step toward faster, denser microelectronics
For many decades, researchers theorized that chips made of pure silicon-28 would overcome silicon's thermal conductivity limit, and therefore improve the processing speeds of smaller, denser microelectronics.
But purifying silicon down to a single isotope requires intense levels of energy which few facilities can supply—and even fewer specialize in manufacturing market-ready isotopes, Ager said.
Fortunately, an international project from the early 2000s enabled Ager and leading semiconductor materials expert Eugene Haller to procure silicon tetrafluoride gas—the starting material for isotopically purified silicon—from a former Soviet-era isotope manufacturing plant.
This led to a series of pioneering experiments, including a 2006 study published in Nature , whereby Ager and Haller fashioned silicon-28 into single crystals, which they used to demonstrate quantum memory storing information as quantum bits or qubits, units of data stored simultaneously as a one and a zero in an electron's spin.
Subsequently, semiconducting thin films and single crystals made with Ager's and Haller's silicon isotope material were shown to have a 10% higher thermal conductivity than natural silicon—an improvement, but from the computer industry's point of view, probably not enough to justify spending a thousand times more money to build a computer from isotopically pure silicon, Ager said.
But Ager knew that the silicon isotope materials were of scientific importance beyond quantum computing. So he kept what remained in a safe place at Berkeley Lab, just in case other scientists might need it, because few people have the resources to make or even purchase isotopically pure silicon, he reasoned.
A path toward cooler tech with silicon-28
About three years ago, Wu and his graduate student Penghong Ci were trying to come up with new ways to improve the heat transfer rate in silicon chips.
One strategy to make more efficient transistors involves using a type of nanowire called a Gate-All-Around Field Effect Transistor. In these devices, silicon nanowires are stacked to conduct electricity, and heat is generated simultaneously, Wu explained. "And if the heat generated is not extracted out quickly, the device would stop working, akin to a fire alarm blaring in a tall building without an evacuation map," he said.
But heat transport is even worse in silicon nanowires, because their rough surfaces—scars from chemical processing—scatter or "confuse" the phonons even more, he explained.
"And then one day we wondered, 'What would happen if we made a nanowire from isotopically pure silicon-28?'" Wu said.
Silicon isotopes are not something one can easily buy on the open market, and word had it that Ager still had some silicon isotope crystals in storage at Berkeley Lab—not a lot, but still enough to share "if someone has a great idea about how to use it," Ager said. "And Junqiao's new study was such a case."
A surprising big reveal with nano tests
"We're really fortunate that Joel happened to have the isotopically enriched silicon material ready to use for the study," Wu said.
Using Ager's silicon isotope materials, the Wu team tested the thermal conductivity in bulk 1-millimeter-size silicon-28 crystals versus natural silicon—and again, their experiment confirmed what Ager and his collaborators discovered years ago—that bulk silicon-28 conducts heat only 10% better than natural silicon.
Now for the nano test. Using a technique called electroless etching, Ci made natural silicon and silicon-28 nanowires just 90 nanometers (billionths of a meter) in diameter—about a thousand times thinner than a single strand of human hair.
To measure the thermal conductivity, Ci suspended each nanowire between two microheater pads outfitted with platinum electrodes and thermometers, and then applied an electrical current to the electrode to generate heat on one pad that flows to the other pad via the nanowire.
"We expected to see only an incremental benefit—something like 20%—of using isotopically pure material for nanowire heat conduction," Wu said.
But Ci's measurements astonished them all. The Si-28 nanowires conducted heat not 10% or even 20%, but 150% better than natural silicon nanowires with the same diameter and surface roughness.
This defied everything that they had expected to see, Wu said. A nanowire's rough surface typically slows phonons down. So what was going on?
High-resolution TEM (transmission electron microscopy) images of the material captured by Matthew R. Jones and Muhua Sun at Rice University uncovered the first clue:a glass-like layer of silicon dioxide on the silicon-28 nanowire surface.
Computational simulation experiments at the University of Massachusetts Amherst led by Zlatan Aksamija, a leading expert on the thermal conductivity of nanowires, revealed that the absence of isotope "defects"—silicon-29 and silicon-30—prevented phonons from escaping to the surface, where the silicon dioxide layer would drastically slow down the phonons. This in turn kept phonons on track along the direction of heat flow—and therefore less "confused"—inside the silicon-28 nanowire's "core." (Aksamija is currently an associate professor of materials science and engineering at the University of Utah.)
"This was really unexpected. To discover that two separate phonon-blocking mechanisms—the surface versus the isotopes, which were previously believed to be independent of each other—now work synergistically to our benefit in heat conduction is very surprising but also very gratifying," Wu said.
"Junqiao and the team discovered a new physical phenomenon," Ager said. "This is a real triumph for curiosity-driven science. It's quite exciting."
Wu said that the team next plans to take their discovery to the next step:by investigating how to "control, rather than merely measure, heat conduction in these materials." + Utforska vidare