Rushing Towards Semiconductor Nanowires: New Platform For Ultrafast Transistors

Sub-stiffness nanowires give rise to the idea of ​​superfast transistors.

Smaller chip, faster computer system, much less power consumption. Novel ideas based mainly on semiconductor nanowires are predicted to make transistors in microelectronic circuits taller and more environmentally friendly. Electron mobility plays an important role in this: The faster electrons can accelerate in these tiny wires, the faster the transistor can change, and much less life. A group of researchers from Helmholtz-Zentrum Dresden-Rossendorf (HZDR), TU Dresden and NaMLab have now succeeded in experimentally demonstrating that electron mobility in nanowires is significantly enhanced when the shell places the wire core under tensile stress. This phenomenon provides new alternatives to the case of superfast transistors.

Nanowires have an uncanny property: These ultrathin wires can sustain excessive elastic deformations without damaging the fabric’s crystalline structure. And but the supplies themselves will not be uncommon. For example, gallium arsenide is widely used in industrial production and is understood to have excessive intrinsic electronic mobility.

Rigidity creates speed

To further improve this mobility, the Dresden researchers manufactured the nanowire consisting of a gallium arsenide core and an aluminum arsenide indium shell. As a result, completely different chemical compositions inside the crystalline buildings inside the shell and core have hardly completely different lattice spacings. This causes the shell to put undue mechanical stress on the much thinner core. The gallium arsenide in the core changes its digital properties. “We influence the effective mass of the electrons in the core. Dr. Emmanouil Dimakis, a scientist at HZDR’s Institute for the Analysis of Ion Beam Materials and Physics, and the initiator of the recently revealed test, determined.

What started as a theoretical prediction has now been confirmed experimentally by researchers in the recently revealed survey. “We know that the electrons in the core must have more cells than in the tensile crystal structure. What we don’t know, however, is how much influence the wire shell has on electron mobility in the core. The core is extremely thin, allowing electrons to work together with the shell and be scattered by it,” commented Dimakis. A collection of measurements and tests demonstrate this effect: Regardless of the interaction with the shells, the electrons in the cores of the below wires examined move about 30% faster at room temperature. compared with electrons in equivalent nanowires with no strain or in the form of gallium arsenide. .

Core Disclosure

The researchers measured electron mobility using non-contact optical spectroscopy: Using optical laser pulses, they released free electrons inside the fabric. The scientists chose the pulse of light so that the shell is mostly clear in sunlight and free electrons are generated only in the core of the wire. The subsequent high-frequency terahertz pulses cause the free electrons to oscillate. “We almost give the electrons a kick that they would normally start oscillating in the wire,” determined PD Dr. Alexej Pashkin, who optimized the measurements to test the core-shell nanowires below with HZDR research group collaboration.

Judging the results by fashion shows how electrons move: The higher their speed and the fewer obstacles they encounter, the longer the oscillations last. “It’s really a normal method. This time, however, we’re not measuring the entire wire – core and case included – but only the small core. This is a completely new problem for us. The core takes up 1% of the loop of the fabric. In different assemblies, we excite the electron a few hundred times less and get a sign that can be hundreds of times weaker,” says Pashkin.

Therefore, sample selection is also an important step. A typical sample incorporates an average of 20,000 to 100,000 circular nanowires over a segment of substrate approximately one square millimeter in size. If the wires are spaced even closer together on the sample, an undesirable effect can occur: Neighboring wires work together, producing the same signature as a single wire, thicker and misaligned. deviation of the measurements. If this effect is not detected, the resulting electron velocity is simply too low. To rule out such interference, the Dresden analysis team carried out further modeling in addition to collecting measurements for nanowires of completely different densities.

Prototype for fast transistor

Features in the microelectronics and semiconductor business increasingly require smaller transistors that change faster than ever. Experts predict that new ideas about nanowires for transistors could also make their way into industrial production in the next few years. The event achieved in Dresden is particularly promising for ultrafast transistors. The researchers’ next step may be to develop major prototypes based mainly on the already studied nanowires and test their suitability for use. To do that, they intend to use, review and improve the metal contacts on the nanowires, in addition to testing the doping of the nanowires with silicon and optimizing the manufacturing process.

Reference: “Excessive mobility of electrons in strained GaAs nanowires” by Leila Balaghi, Si Shan, Ivan Fotev, Finn Moebus, Rakesh Rana, Tommaso Venanzi, René Hübner, Thomas Mikolajick, Harald Schneider, Manfred Helm, Alexej Pashkin and Emmanouil Dimakis, November 17, 2021, Nature Communications.
DOI: 10.1038 / s41467-021-27006-z