Abstract
Single-electron tunneling transistors (SETs) and boxes (SEBs) exploit the phenomenon of Coulomb blockade to achieve unprecedented charge sensitivities. Single-electron boxes, however, despite their simplicity compared to SETs, have rarely been used for practical applications. The main reason for that is that unlike a SET where the gate voltage controls conductance between the source and the drain, an SEB is a two terminal device that requires either an integrated SET amplifier or high-frequency probing of its complex admittance by means of radio frequency reflectometry (RFR). The signal to noise ratio (SNR) for a SEB is small, due to its much lower admittance compared to a SET and thus matching networks are required for efficient coupling ofSEBs to an RFR setup. To boost the signal strength by a factor of N (due to a random offset charge) SEBs can be connected in parallel to form arrays sharing common gates and sources. The smaller the size of the SEB, the larger the charging energy of a SEB enabling higher operation temperature, and using devices with a small footprint (<0.01 µm2), a large number of devices (>1000) can be assembled into an array occupying just a few square microns. We show that it is possible to design SEB arrays that may compete with an SET in terms of sensitivity. In this, we tested SETs using RF reflectometry in a configuration with no DC through path (“DC-decoupled SET” or DCD SET) along with SEBs connected to the same matching network. The experiment shows that the lack of a path for a DC current makes SEBs and DCD SETs highly electrostatic discharge (ESD) tolerant, a very desirable feature for applications. We perform a detailed analysis of experimental data on SEB arrays of various sizes and compare it with simulations to devise several ways for practical applications of SEB arrays and DCD SETs.
Highlights
Single-electron transistors (SETs) and single-electron boxes (SEB) belong to a family of nanoscale electronic devices that operate on the effect of a Coulomb blockade of electron transport [1]
To perform a reflectometry measurement of one SEB we used a matching Π network discussed in Section 3, Figure 7a
The results of the experiments show that the concept of using arrays of SEB for sensing applications is comparable to other devices, such as single-electron transistor (SET), and it brings several important advantages, such as elevated operating temperatures, a smaller device footprint and inherent protection from electrostatic discharge (ESD) damage
Summary
Single-electron transistors (SETs) and single-electron boxes (SEB) belong to a family of nanoscale electronic devices that operate on the effect of a Coulomb blockade of electron transport [1].Electrometers employing SETs have demonstrated unprecedented charge sensitivities down toAppl. Single-electron transistors (SETs) and single-electron boxes (SEB) belong to a family of nanoscale electronic devices that operate on the effect of a Coulomb blockade of electron transport [1]. Electrometers employing SETs have demonstrated unprecedented charge sensitivities down to. Sci. 2020, 10, 8797; doi:10.3390/app10248797 www.mdpi.com/journal/applsci using the so called Niemeyer–Dolan bridge technique [15,16]. They are composed of a nanoscale “island” coupled to the outside world by two (SET), Figure 1a, or one (SEB), Figure 1b, tunnel junctions (TJs) and a non-leaky capacitive gate. The key parameters are the charging energy, EC = e /2CΣ
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