Silicon on ferroelectric insulator field effect transistor (SOF-FET) a new device for the next generation ultra low power circuits

Title from PDF of title page, viewed on March 12, 2014Thesis advisor: Masud H. ChowdhuryVitaIncludes bibliographical references (pages 116-131)Thesis (M. S.)--School of Computer and Engineering. University of Missouri--Kansas City, 2013Field effect transistors (FETs) are the foundation for all electronic circuits and processors. These devices have progressed massively to touch its final steps in subnanometer level. Left and right proposals are coming to rescue this progress. Emerging nano-electronic devices (resonant tunneling devices, single-atom transistors, spin devices, Heterojunction Transistors rapid flux quantum devices, carbon nanotubes, and nanowire devices) took a vast share of current scientific research. Non-Si electronic materials like III-V heterostructure, ferroelectric, carbon nanotubes (CNTs), and other nanowire based designs are in developing stage to become the core technology of non-classical CMOS structures. FinFET present the current feasible commercial nanotechnology. The scalability and low power dissipation of this device allowed for an extension of silicon based devices. High short channel effect (SCE) immunity presents its major advantage. Multi-gate structure comes to light to improve the gate electrostatic over the channel. The new structure shows a higher performance that made it the first candidate to substitute the conventional MOSFET. The device also shows a future scalability to continue Moor’s Law. Furthermore, the device is compatible with silicon fabrication process. Moreover, the ultra-low-power (ULP) design required a subthreshold slope lower than the thermionic-emission limit of 60mV/ decade (KT/q). This value was unbreakable by the new structure (SOI-FinFET). On the other hand most of the previews proposals show the ability to go beyond this limit. However, those pre-mentioned schemes have publicized a very complicated physics, design difficulties, and process non-compatibility. The objective of this research is to discuss various emerging nano-devices proposed for ultra-low-power designs and their possibilities to replace the silicon devices as the core technology in the future integrated circuit. This thesis proposes a novel design that exploits the concept of negative capacitance. The new field effect transistor (FET) based on ferroelectric insulator named Silicon-On-Ferroelectric Insulator Field Effect Transistor (SOF-FET). This proposal is a promising methodology for future ultra-lowpower applications, because it demonstrates the ability to replace the silicon-bulk based MOSFET, and offers subthreshold swing significantly lower than 60mV/decade and reduced threshold voltage to form a conducting channel. The SOF-FET can also solve the issue of junction leakage (due to the presence of unipolar junction between the top plate of the negative capacitance and the diffused areas that form the transistor source and drain). In this device the charge hungry ferroelectric film already limits the leakage.Abstract -- List of illustrations - List of tables -- Acknowledgements -- Dedication -- Introduction -- Carbon nanotube field effect transistor -- Multi-gate transistors -FinFET -- Subthreshold swing -- Tunneling field effect transistors -- I-mos and nanowire fets -- Ferroelectric based field effect transistors -- An analytical model to approximate the subthreshold swing for soi-finfet -- Silicon-on-ferroelectric insulator field effect transistor (SOF-FET) -- Current-voltage characteristics of sof-fet -- Advantages, manufacturing process and future work of the proposed device -- Appendix -- Reference

Silicon on Ferroelectric Insulator Field Effect Transistor (SOFFET): A Radical Alternative to Overcome the Thermionic Limit

Title from PDF of title page viewed January 3,2018Dissertation advisor: Masud H ChowdhuryVitaIncludes bibliographical references (pages 165-180)Thesis (Ph.D.)--School of Computing and Engineering and Department of Physics and Astronomy. University of Missouri--Kansas City, 2016The path of down-scaling traditional MOSFET is reaching its technological, economic and, most importantly, fundamental physical limits. Before the dead-end of the roadmap, it is imperative to conduct a broad research to find alternative materials and new architectures to the current technology for the MOSFET devices. Beyond silicon electronic materials like group III-V heterostructure, ferroelectric material, carbon nanotubes (CNTs), and other nanowire-based designs are in development to become the core technology for non-classical CMOS structures. Field effect transistors (FETs) in general have made unprecedented progress in the last few decades by down-scaling device dimensions and power supply level leading to extremely high numbers of devices in a single chip. High density integrated circuits are now facing major challenges related to power management and heat dissipation due to excessive leakage, mainly due to subthreshold conduction. Over the years, planar MOSFET dimensional reduction was the only process followed by the semiconductor industry to improve device performance and to reduce the power supply. Further scaling increases short-channel-effect (SCE), and off-state current makes it difficult for the industry to follow the well-known Moore’s Law with bulk devices. Therefore, scaling planar MOSFET is no longer considered as a feasible solution to extend this law. The down-scaling of metal-oxide-semiconductor field effect transistors (MOSFETs) leads to severe short-channel-effects and power leakage at large-scale integrated circuits (LSIs). The device, which is governed by the thermionic emission of the carriers injected from the source to the channel region, has set a limitation of the subthreshold swing (S) of 60 / at room temperature. Devices with ‘S’ below this limit is highly desirable to reduce the power consumption and maintaining a high / current ratio. Therefore, the future of semiconductor industry hangs on new architectures, new materials or even new physics to govern the flow of carriers in new switches. As the subthreshold swing is increasing at every technology node, new structures using SOI, multi-gate, nanowire approach, and new channel materials such as III–V semiconductor have not satisfied the targeted values of subthreshold swing. Moreover, the ultra-low-power (ULP) design required a subthreshold slope lower than the thermionic emission limit of 60 /. This value was unbreakable by the new structure (SOI FinFET). On the other hand, most of the preview proposals show the ability to go beyond this limit. However, those pre-mentioned schemes have publicized very complicated physics, design difficulties, and process non-compatibility. The objective of this research is to discuss various emerging nano-devices proposed for sub-60 mV/decade designs and their possibilities to replace the silicon devices as the core technology in the future integrated circuit. This dissertation also proposes a novel design that exploits the concept of negative capacitance. The new field-effect-transistor (FET) based on ferroelectric insulator named Silicon-On-Ferroelectric Insulator Field effect-transistor (SOFFET). This proposal is a promising methodology for future ultra low-power applications because it demonstrates the ability to replace the silicon-bulk based MOSFET, and offers a subthreshold swing significantly lower than 60 / and reduced threshold voltage to form a conducting channel. The proposed SOFFET design, which utilizes the negative capacitance of a ferroelectric insulator in the body-stack, is completely different from the FeFET and NCFET designs. In addition to having the NC effect, the proposed device will have all the advantages of an SOI device. Body-stack that we are intending in this research has many advantages over the gate-stack. First, it is more compatible with the existing processes. Second, the gate and the working area of the proposed SOFFET is like the planar MOSFET. Third, the complexity and ferroelectric material interferences are shifted to the body of the device from the gate and the working area. The proposed structure offers better scalability and superior constructability because of the high-dielectric buried insulator. Here we are providing a very simplified model for the structure. Silicon-on-ferroelectric leads to several advantages including low off-state current and shift in the threshold voltage with the decrease of the ferroelectric material thickness. Moreover, having an insulator in the body of the device increases the controllability over the channel, which leads to the reduction in the short-channel-effect (SCE). The proposed SOFFET offers low value of subthreshold swing (S) leading to better performance in the on-state. The off-state current is directly related to S. So, the off-state current is also minimum in the proposed structure.Introduction -- Subthreshold swing -- Multi-gate devices -- Tunneling field effect transistors -- I-mos & FET transistors -- Ferroelectric based field effect transistors -- An analytical model to approximate the subthreshold swing for SOI-FINFET -- Multichannel tunneling carbon nanotube FET -- Partially depleted silicon-on-Ferroelectric insulator FET -- Fully depleted silicon-on-ferroelectric insulator FET -- Advantages, manufacturing process, and future work of the proposed devices -- Appendix A. Estimation of the body factor (n) [eta] of SOI FinFET -- Appendix B. Solution for the Poisson Equation of MT-CNTFE

Magnetic order in the SeffS_{\mathrm{eff}} = 1/2 triangular-lattice compound NdCd3_3P3_3

We present and characterize a new member of the $R$Cd$_3$P$_3$ ($R$= rare earth) family of materials, NdCd$_3$P$_3$, which possesses Nd$^{3+}$ cations arranged on well-separated triangular lattice layers. Magnetic susceptibility and heat capacity measurements demonstrate a likely $S_{\mathrm{eff}}$ = 1/2 ground state, and also reveal the formation of long-range antiferromagnetic order at $T_{N} = 0.34$ K. Via measurements of magnetization, heat capacity, and electrical resistivity, we characterize the electronic properties of NdCd$_3$P$_3$ and compare results to density functional theory calculations.Comment: Accepted for publication at Physical Review Material

Interdomain Traffic Engineering Techniques to Overcome Undesirable Connectivity Incidents

Part 6: Poster Sessions; International audience; The importance of Internet availability is supported by the overwhelming dependence of government services and financial institutions upon said availability. Unfortunately, the Internet is facing different level of undesirable connectivity incidents. So, it is imperative to take serious measures in order to increase Internet connectivity resilience. We consider a scenario where a concerned region is facing an undesirable connectivity incident by its primary Internet Service Provider (ISP) which still advertises reachability to the concerned region. Assuming that connectivity to a secondary ISP is available, software is designed to implement different traffic engineering techniques in order to enhance internet connectivity resilience and send the traffic through the secondary ISP. The work is characterized by the implementation of these traffic engineering techniques in the laboratory through a detailed set of experiments. Document type: Part of book or chapter of boo

Mitigating Denial of Service Attacks in RPL-Based IoT Environments: Trust-Based Approach

In domains such as telehealth, intelligent transportation, and autonomous agriculture, ensuring secure routing of collected and exchanged data is paramount. Since its inception, there have been many research challenges for the RPL routing protocol that operates in resource-constrained environments and utilizes battery-powered IoT devices. Hence, researchers have focused on this crucial challenge by advising solutions to mitigate attacks that deplete nodes’ energy and hence create energy gaps in the network. In this article, we study the impact of two energy exhaustion attacks (hello flooding and version number modification) on the RPL protocol and we present a novel mitigation solution based on behavioural trust. We present an in-depth study of the impact on radio energy consumption of the hello flooding and version number modification attacks in RPL as the number of network nodes increases. We showed that the impact of the former is localized to nodes in the vicinity of the attacker while the latter has a global impact that extends to the entire network. The obtained results from our simulations show that version number modification attack in particular has devastating impact on the network. We also propose a trust-based solution to mitigate these attacks and demonstrate its effectiveness. Accordingly, we conduct comparative study of these attacks and empirically investigate their impact on network performance by running extensive evaluation experiments. Our findings verify the effectiveness of our proposed trust system in mitigating both attacks

Classifying and Tracking Free Riders in Multimedia-Based Systems

The ever growing explosion in technological advancements is paving the way to the expansion of multimedia applications. Unfortunately, current multimedia applications use centralized architectures. Before decentralized architectures are utilized and used, some issues related to decentralization must be addressed. In this paper, we focus on the problem of free riding in decentralized collaborative environments. We propose a novel taxonomy of free riders in multimedia systems based on trustworthiness. To the best of our knowledge, no existing literature considers trustworthiness, which we believe is a vital dimension that should be considered when identifying free riders. We also propose a new mechanism to filter out and isolate free riders. Our extensive simulation experiments show that our proposed algorithm is reasonably successful in identifying free riders in multimedia-based systems