QT-PUF: Quantum Tunneling Leakage Based PUF for Implantable IoMT Devices

Abstract

The Internet of Medical Things (IoMT) marks a shift toward decentralized healthcare, enabling continuous monitoring and personalized care through connected wearable and implantable devices. However, ensuring the trust and integrity of these devices themselves remains a major challenge, as physical compromise or counterfeiting can directly endanger patient safety, privacy, and data integrity. This work presents QT-PUF, a gate-tunneling-leakage-based physical unclonable function (PUF) that leverages quantum-mechanical gate leakage resulting from process-induced variations in standard CMOS devices. A differential readout circuit with a pseudo-resistor I-to-V frontend is proposed to convert the picoampere-level leakage variations into digital responses. Unlike existing PUFs such as those based on memory, ring oscillators, or arbiters, which are less suitable for ultralow-power IoMT devices (due to additional circuitry, power overhead, or poor stability), QT-PUF requires no external excitation or stabilization and operates under static bias. Simulation-based measurements for a 65~nm CMOS process demonstrate an entropy of 0.9999998, an FHD of 0.5001, and an average power (energy) consumption of 96.04~nW/bit (19.21~fJ/bit, respectively) at 1.2\,V and 35\,C for the proposed PUF. It operates reliably across 0.9--1.3~V and 0--100\,C with an average BER below 0.000163 across 1.0--1.3~V and 10--70\,C within the operating conditions of typical implantable devices.