TCAD Simulation of Si and GaAs p-n Junction Devices at Cryogenic Temperatures, Down to 2 K

Introduction

Cryogenic electronics plays a fundamental role in several applications, such as spacecraft, high-energy physics experiments, metrology, superconductive astronomical detectors and, with the increased interest in quantum computing, the manipulation of quantum bits (qubits) [1]. Outstanding characteristics have been reported for advanced CMOS technologies operating at cryogenic temperature in terms of on-state current, leakage current, subthreshold swing, and transconductance [2]. This represents an excellent opportunity to use such advanced technologies to design and implement a quantum computing control system (including multiplexers, LNAs, and RF oscillators) and introduce it inside the refrigerator together with the qubits [3]. Another recently growing field of application is the cryogenic silicon photonics [4].

However, finding the optimal trade-off in the design of semiconductor devices, including p-n and p-i-n junction based devices, MOSFETs, and CMOS circuits is challenging due to the lack of efficient physics-based models valid down to cryogenic and deep-cryogenic temperatures&typically 4.2 K (liquid helium) or even below for quantum computing applications. Physics-based analysis and design of devices operating below 77 K have been held up by the numerical difficulties of modeling and simulation in this temperature range [5, 6]. The intrinsic carrier concentration becomes extremely small at cryogenic temperatures, which has its inevitable root in the exponential temperature scaling of the Fermi-Dirac and Boltzmann statistics.

TCAD simulations of devices operating at such low temperatures, especially below 50 K, have always posed a challenge. Below 50 K, carrier and ionization statistics develop sharp transitions which cause slower convergence. As the temperature (T) decreases, the intrinsic carrier concentration (n_i) dramatically decreases. For example, the silicon ni which at T=300K is around 1.5e+10 cm^-3, at T=10K becomes 1.2e-267 cm^-3, and at T=4.2K n_i= 2.7e-678 cm^-3 [3], lying outside the range of IEEE double precision arithmetic (1e-308 – 1e+308) starting from below T=8K. In wider-bandgap materials, such as GaAs, SiC, or GaN, the n_i values become even lower. Therefore, in quasi-neutral or depletion regions, the minority carrier concentration can easily underflow. This is computationally very demanding in numerical TCAD simulations [5]. Such situation requires using a significantly higher floating point precision, as well as special numerical techniques, which are available in Silvaco’s TCAD device simulation tools.