Global ETD Search

41	TWO-DIMENSIONAL NANO-TRANSISTORS FOR STEEP-SLOPE DEVICES AND HARDWARE SECURITY Peng Wu (11691256) 22 November 2021 (has links) <p>Since the discovery of graphene, two-dimensional (2D) materials have attracted broad interests for transistor applications due to their atomically thin nature. This thesis studies nano-transistors based on 2D materials for several novel applications, including tunneling transistors for low-power electronics and reconfigurable transistors for hardware security.</p><p>The first part of the thesis focuses on tunneling field-effect transistors (TFETs). Since the current injection in a conventional MOSFET depends on thermionic injection over a gate-controlled barrier, the subthreshold swing (SS) of MOSFET is fundamentally limited to 60 mV/dec at room temperature, hindering the supply voltage scaling of integrated circuits (ICs). Utilizing band-to-band tunneling (BTBT) as current injection mechanism, TFETs overcome the SS limit by filtering out the Fermi tail in the source and achieve steep-slope switching. However, existing demonstrations of TFETs are plagued by low on-currents and degraded SS, largely due to the large tunneling distances caused by non-scaled body thicknesses, making 2D materials a promising candidate as channel materials for TFETs. In this thesis, we demonstrate a prototype TFET based on black phosphorus (BP) adopting electrostatic doping that is tuned by multiple top-gates, which allows the device to be reconfigured into multiple operation modes. The band-to-band tunneling mechanism is further confirmed by source-doping-dependent and temperature-dependent measurements, and the performance improvement of BP TFETs with further body and oxide thicknesses scaling is projected by atomistic simulation. In addition, a vertical BP TFET with a large tunneling area is also demonstrated, and negative differential resistance (NDR) is observed in the device.</p><p>The second part of the thesis focuses on reconfigurable nano-transistors with tunable p- and n-type operations and the implementation of hardware security based on such transistors. Polymorphic gate has been proposed as a hardware security primitive to protect the intellectual property of ICs from reverse engineering, and its operation requires transistors that can be reconfigured between p-type and n-type. However, a traditional CMOS transistor relies on substitutional doping, and thus its polarity cannot be altered after the fabrication. By contrast, 2D nano-transistors can attain both electron and hole injections. In this thesis, we review the Schottky-barrier injection in 2D transistors and demonstrate the feasibility of achieving complementary p-type and n-type transistors using BP as channel material by adopting metal contacts with different work functions. In this design, however, the discrepancy in the p-FET and n-FET device structures makes it unsuitable for reconfigurable transistors. Therefore, we continue to modify the device design to enable reconfigurable p-type and n-type operations in the same BP transistor. Finally, a NAND/NOR polymorphic gate is experimentally demonstrated based on the reconfigurable BP transistors, showing the feasibility of using 2D materials to enable hardware security.</p><p>In the last part, we demonstrate an artificial sub-60 mV/dec switching in a metal-insulator-metal-insulator-semiconductor (MIMIS) transistor. Negative capacitance FETs (NC-FETs) have attracted wide interest as promising candidates for steep-slope devices. However, the detailed mechanisms of the observed steep-slope switching are under intense debate. We show that sub-60 mV/dec switching can be observed in a WS2 transistor with an MIMIS structure – without any ferroelectric component. Using a resistor-capacitor (RC) network model, we show that the observed steep-slope switching can be attributed to the internal gate voltage response to the chosen varying gate voltage scan rates. Our results indicate that the measurement-related artefacts can lead to observation of sub-60 mV/dec switching and that experimentalists need to critically assess their measurement setups.</p> Nanoelectronics Nanomaterials TFET 2D material black phosphorus hardware security steep slope nanoelectronics
42	Self-assembled nanoelectronic networks with tunable molecule-nanoparticle ratios: experiment, modeling, and applications Venkataraman, Anusha 04 October 2021 (has links) Replacing electronic components with molecule-sized analogs or hybrids is often seen as a promising alternative to further miniaturization of conventional electronics in the effort to achieve functional nanoscale circuit elements. In this thesis, electronic transport through self-assembled networks with tunable thiolated (alkane(di)thiol and benzenedithiol) molecule-to-colloidal gold (Au) nanoparticle ratios (1:5–50:1) is studied using a combination of broad area and scanning probe microscope-based measurements. The electronic transport paths through the network can be altered by adjusting the (di)thiol molecule–gold nanoparticle ratio and/or type of molecules in the network. Resistance can be controllably tuned by several orders of magnitude (~105 to 1011 ohms for the Au-thiolated structures studied). Two-terminal current–voltage (I-V) measurements of the Au-thiolated networks display linear behavior at low bias. High bias measurements in case of benzenedithiol networks show nonlinear negative differential resistance (NDR) and hysteresis behavior for different benzenedithiol concentrations, which can be attributed to a combination of field-assisted tunneling and charge trapping occurring in the nanoscale networks. Circuit simulations that account for different network morphologies, tunable via molecule-to-nanoparticle ratio, and defects show good agreement with the experiment and provide a guide to engineer network properties using different molecules. In addition, electronic transport properties of nanoscale networks, which are composed of Au metal clusters interconnected with thiolated molecules (benzene/alkanedithiol) and connected in linear chains and branched extended networks, are examined via first-principles density functional theory-based simulations. Calculated I-V characteristics of the metal-molecular networks exhibited nonlinearities and rectification with NDR peaks that became more pronounced with increasing chain length. The transmission spectra of the linear chains and branched networks showed an increase in the number and width of transmission peaks near the Fermi energy, as the structures were extended, indicating enhanced transmission. Peak-to-valley current NDR ratios as large as ~ 500 and rectification ratios of ~ 10 (0.25 V) were shown for linear and branched circuit elements, respectively, illustrating how charge transport through molecular-scale devices could be controlled with precision by modifying the structure and geometry of molecule-nanoparticle networks. These experimental and simulation results are utilized to propose molecular-scale circuits in applications such as memory, switching, and hardware security. The metal nanoparticle molecular electronic networks presented in this thesis provide an avenue for engineering electronics at the molecular level. / Graduate Nanoparticles self-assembly negative differential resistance hysteresis electronic transport molecules charge transport random key generation hardware security
43	Analysis of Machine Learning Modeling Attacks on Ring Oscillator based Hardware Security Kumar, Sharad, Kumar January 2018 (has links) No description available. Artificial Intelligence Computer Science Technology
44	Hardware Security and VLSI Design Optimization Xue, Hao January 2018 (has links) No description available. Engineering Electrical Engineering Microelectronic circuit microelectronic supply chain integrated circuit production IC Hardware Trojan HT VLSI design optimization hardware security
45	A Security Framework for Logic Locking Through Local and Global Structural Analysis Taylor, Christopher P. 28 September 2020 (has links) No description available. Electrical Engineering Computer Engineering Hardware Security Logic Locking Obfuscation Function Locking Hardware Trojan Intellectual Property Theft Structural Analysis Security Metric
46	DEFEATING CYBER AND PHYSICAL ATTACKS IN ROBOTIC VEHICLES Hyungsub Kim (17540454) 05 December 2023 (has links) <p dir="ltr">The world is increasingly dependent on cyber-physical systems (CPSs), e.g., robotic vehicles (RVs) and industrial control systems (ICSs). CPSs operate autonomously by processing data coming from both “cyberspace”—such as user commands—and “physical space”—such as sensors that measure the physical environment in which they operate. However, even after decades of research, CPSs remain susceptible to threats from attackers, primarily due to the increased complexity created by interaction with cyber and physical space (e.g., the cascading effects that changes in one space can impact on the other). In particular, the complexity causes two primary threats that increase the risk of causing physical damage to RVs: (1) logic bugs causing undesired physical behavior from the developers expectations; and (2) physical sensor attacks—such as GPS or acoustic noise spoofing—that disturb an RV’s sensor readings. Dealing with these threats requires addressing the interplay between cyber and physical space. In this dissertation, we systematically analyze the interplay between cyber and physical space, thereby tackling security problems created by such complexity. We present novel algorithms to detect logic bugs (PGFuzz in Chapter 2), help developers fix them (PGPatch in Chapter 3), and test the correctness of the patches attempting to address them (PatchVerif in Chapter 4). Further, we explain algorithms to discover the root causes and formulate countermeasures against physical sensor attacks that target RVs in Chapter 5.</p> Hardware security Software and application security System and network security Cybersecurity Robotic vehicle Cyber–physical system Logic bug Physical sensor attack
47	<b>Measurements for TEG based Energy Harvesting for </b><b>EQS-HBC Body Nodes and </b><b>EM Emanations for Hardware Security</b> Yi Xie (17683731) 20 December 2023 (has links) <p dir="ltr">Sensing and communication circuits and systems are crucial components in various electronic devices and technologies. These systems are designed to acquire information from the surrounding environment through sensors, process that information, and facilitate communication between different devices or systems. It plays a vital role in modern electronic devices, enabling them to collect, process, and exchange information to perform various functions in applications such as IoB (Internet of Body), healthcare, hardware security, industrial automation, and more.</p><p dir="ltr">This work focuses on innovations in sensing and communication circuits spanning two independent application areas – human body communication and hardware emanations security.</p><p dir="ltr">First, an ultra-low power ECG monitoring system is implemented to perpetually power itself using Thermoelectric Generator (TEG) to harvest body energy while securely transmitting sensed data through on-body communication, achieving closed-loop operation without external charging or batteries. Custom circuits allow demonstrated feasibility of self-sustaining wearables leveraging Human Body Communication’s advantages.</p><p dir="ltr">Second, investigations reveal vulnerabilities introduced when repairing broken cables, with unintended monopole antennas boosting electromagnetic emissions containing signal correlations. Experiments characterize long-range detection regimes post-repair across USB keyboard cables. Further circuit and structural innovations provide localized shielding at repair points as a potential mitigation. Advancements offer contributions in understanding hardware emission security risks to inform protection strategies.</p><p dir="ltr">The two separate research work demonstrate specialized circuits advancing the state-of-the-art in sensing and communication for wearable body-based systems and hardware security through greater awareness of vulnerabilities from unintended emissions.</p><p><br></p> Electrical circuits and systems Human Body Communications IoB Sensing and Communication Thermoelectric Generator (TEG) Harvest Energy form Body Hardware Security ELECTROMAGNETIC EMISSIONS
48	Hardware Security through Design Obfuscation Chakraborty, Rajat Subhra 04 May 2010 (has links) No description available. Electrical Engineering Hardware security design obfuscation hardware Trojan statistical logic testing secure scan design software obfuscation secure system-on-chip design
49	Logic Encryption Methods for Hardware Security Sekar, Sanjana January 2017 (has links) No description available. Engineering Logic Encryption SAT Attack SAT Tolerant Encryption Hardware Security Probabilistic Sub-circuit selection sub-circuit hiding
50	BDD Based Synthesis Flow for Design of DPA Resistant Cryptographic Circuits Chakkaravarthy, Manoj 19 April 2012 (has links) No description available. Computer Engineering Hardware Security Differential Power Analysis (BDD) Side channel Attacks (SCA) Cryptographic Circuits BDD Based Synthesis Flow DPA Countermeasures

Search results