Scaling Opportunities for Bulk Accumulation and Inversion MOSFETs for Gigascale Integration

Murali, Raghunath

20 February 2004

The objective of this research is to comprehensively compare bulk accumulation and inversion MOSFETs, and find application areas where each is superior.Short channel effect (SCE) models for accumulation and inversion MOSFETs are derived that accurately predict threshold voltage, subthreshold swing, and subthreshold current. A source/drain junction depth dependent characteristic length is derived that can be used to rapidly assess the impact of junction depth scaling on minimum channel length. A fast circuit simulation methodology is developed that uses physically based I-V models to simulate inversion and accumulation MOSFET inverter chains, and is found to be accurate over a wide range of supply voltages. The simulation methodology can be used for rapid technology optimization, and performance prediction. Design guidelines are proposed for accumulation MOSFET design; the guidelines result in a low process sensitivity, low SCE, and a subthreshold current less than the allowable limit. The relative performance advantage of accumulation/inversion MOSFETs is gate-technology dependent. In critical comparisons, on-current is evaluated by means of a full band Monte Carlo device simulation. Gate-leakage, and band-to-band tunneling leakage at the drain-substrate region are included in the performance analysis. For mid-bandgap metal gate, accumulation MOSFETs perform better than inversion MOSFETs for hi-performance (HiP) and low-operating power (LOP) applications. For tunable metal gate technology, inversion MOSFETs always perform better than accumulation MOSFETs. For dual poly technology, accumulation MOSFETs perform better than inversion MOSFETs for low standby power (LSTP) applications. A comprehensive scaling analysis has been performed on accumulation and inversion MOSFETs using both SCE models and 2-D simulations. Results show that accumulation MOSFETs can scale better than inversion MOSFETs for mid-bandgap metal gate HiP, and LOP applications; and poly gate LSTP applications.

MOSFET

Buried channel

Inversion

Accumulation

Threshold voltage

Short channel effect

On-Chip Isotropic Microchannels for Cooling Three Dimensional Microprocessors

Renaghan, Liam Eamon

14 January 2010

This thesis reports the fabrication of three dimensionally independent on-chip microchannels using a CMOS-compatible single mask deep reactive ion etching (DRIE) process for cooling 3D ICs. Three dimensionally independent microchannels are fabricated by utilizing the RIE lag effect. This allows complex microchannel configurations to be fabricated using a single mask and single silicon etch step. Furthermore, the microchannels are sealed in one step by low temperature oxide deposition. The micro-fin channels heat transfer characteristics are similar to previously published channel designs by being capable of removing 185 W/cm2 before the junction temperatures active elements exceed 85°C. To examine the heat transfer characteristics of this proposed on-chip cooler, different channel geometries were simulated using computational fluid dynamics. The channel designs were simulated using 20°C water at different flow rates to achieve a laminar flow regime with Reynolds numbers ranging from 200 to 500. The steady state simulations were performed using a heat flux of 100 W/cm2. Simulation results were verified using fabricated test chips. A micro-fin geometry showed to have the highest heat transfer capability and lowest simulated substrate temperatures. While operating with a Reynolds number of 400, a Nusselt number per input energy (Nu/Q) of 0.24 W-1 was achieved. The micro-fin geometry is also capable of cooling a substrate with a heat flux of 100W/cm2 to 45ºC with a Reynolds number of 525. These channels also have a lower thermal resistance compared to external heat sinks because there is no heat spreader or thermal interface material layer. / Master of Science

Chip Cooling

3D IC

MEMS

CMOS Compatible

Microfluidics

Buried Channel

Novel concepts for advanced CMOS : Materials, process and device architecture

Wu, Dongping

January 2004

The continuous and aggressive dimensional miniaturization ofthe conventional complementary-metal-oxide semiconductor (CMOS)architecture has been the main impetus for the vast growth ofIC industry over the past decades. As the CMOS downscalingapproaches the fundamental limits, unconventional materials andnovel device architectures are required in order to guaranteethe ultimate scaling in device dimensions and maintain theperformance gain expected from the scaling. This thesisinvestigates both unconventional materials for the gate stackand the channel and a novel notched-gate device architecture,with the emphasis on the challenging issues in processintegration. High-κ gate dielectrics will become indispensable forCMOS technology beyond the 65-nm technology node in order toachieve a small equivalent oxide thickness (EOT) whilemaintaining a low gate leakage current. HfO2and Al2O3as well as their mixtures are investigated assubstitutes for the traditionally used SiO2in our MOS transistors. These high-κ filmsare deposited by means of atomic layer deposition (ALD) for anexcellent control of film composition, thickness, uniformityand conformality. Surface treatments prior to ALD are found tohave a crucial influence on the growth of the high-κdielectrics and the performance of the resultant transistors.Alternative gate materials such as TiN and poly-SiGe are alsostudied. The challenging issues encountered in processintegration of the TiN or poly-SiGe with the high-k are furtherelaborated. Transistors with TiN or poly-SiGe/high-k gate stackare successfully fabricated and characterized. Furthermore,proof-of-concept strained-SiGe surface-channel pMOSFETs withALD high-κ dielectrics are demonstrated. The pMOSFETs witha strained SiGe channel exhibit a higher hole mobility than theuniversal hole mobility in Si. A new procedure for extractionof carrier mobility in the presence of a high density ofinterface states found in MOSFETs with high-κ dielectricsis developed. A notched-gate architecture aiming at reducing the parasiticcapacitance of a MOSFET is studied. The notched gate is usuallyreferred to as a local thickness increase of the gatedielectric at the feet of the gate above the source/drainextensions. Two-dimensional simulations are carried out toinvestigate the influence of the notched gate on the static anddynamic characteristics of MOSFETs. MOSFETs with optimizednotch profile exhibit a substantial enhancement in the dynamiccharacteristics with a negligible effect on the staticcharacteristics. Notched-gate MOSFETs are also experimentallyimplemented with the integration of a high-κ gatedielectric and a poly-SiGe/TiN bi-layer gate electrode. Key words:CMOS technology, MOSFET, high-κ, gatedielectric, ALD, surface pre-treatment, metal gate, poly-SiGe,strained SiGe, surface-channel, buried-channel, notchedgate.

CMOS technology

MOSFET

high-k

gate dielectric

ALD

surface pre-treatment

metal gate

poly-SiGe

strained SiGe

surface-channel

buried-channel

notched gate

Low-frequency noise characterization, evaluation and modeling of advanced Si- and SiGe-based CMOS transistors

von Haartman, Martin

January 2006

A wide variety of novel complementary-metal-oxide-semiconductor (CMOS) devices that are strong contenders for future high-speed and low-noise RF circuits have been evaluated by means of static electrical measurements and low-frequency noise characterizations in this thesis. These novel field-effect transistors (FETs) include (i) compressively strained SiGe channel pMOSFETs, (ii) tensile strained Si nMOSFETs, (iii) MOSFETs with high-k gate dielectrics, (iv) metal gate and (v) silicon-on-insulator (SOI) devices. The low-frequency noise was comprehensively characterized for different types of operating conditions where the gate and bulk terminal voltages were varied. Detailed studies were made of the relationship between the 1/f noise and the device architecture, strain, device geometry, location of the conduction path, surface cleaning, gate oxide charges and traps, water vapour annealing, carrier mobility and other technological factors. The locations of the dominant noise sources as well as their physical mechanisms were investigated. Model parameters and physical properties were extracted and compared. Several important new insights and refinements of the existing 1/f noise theories and models were also suggested and analyzed. The continuing trend of miniaturizing device sizes and building devices with more advanced architectures and complex materials can lead to escalating 1/f noise levels, which degrades the signal-to-noise (SNR) ratio in electronic circuits. For example, the 1/f noise of some critical transistors in a radio receiver may ultimately limit the information capacity of the communication system. Therefore, analyzing electronic devices in order to control and find ways to diminish the 1/f noise is a very important and challenging research subject. We present compelling evidence that the 1/f noise is affected by the distance of the conduction channel from the gate oxide/semiconductor substrate interface, or alternatively the vertical electric field pushing the carriers towards the gate oxide. The location of the conduction channel can be varied by the voltage on the bulk and gate terminals as well by device engineering. Devices with a buried channel architecture such as buried SiGe channel pMOSFETs and accumulation mode MOSFETs on SOI show significantly reduced 1/f noise. The same observation is made when the substrate/source junction is forward biased which decreases the vertical electric field in the channel and increases the inversion layer separation from the gate oxide interface. A 1/f noise model based on mobility fluctuations originating from the scattering of electrons with phonons or surface roughness was proposed. Materials with a high dielectric constant (high-k) is necessary to replace the conventional SiO2 as gate dielectrics in the future in order to maintain a low leakage current at the same time as the capacitance of the gate dielectrics is scaled up. In this work, we have made some of the very first examinations of 1/f noise in MOSFETs with high-k structures composed by layers of HfO2, HfAlOx and Al2O3. The 1/f noise level was found to be elevated (up to 3 orders of magnitude) in the MOSFETs with high-k gate dielectrics compared to the reference devices with SiO2. The reason behind the higher 1/f noise is a high density of traps in the high-k stacks and increased mobility fluctuation noise, the latter possibly due to noise generation in the electron-phonon scattering that originates from remote phonon modes in the high-k. The combination of a TiN metal gate, HfAlOx and a compressively strained surface SiGe channel was found to be superior in terms of both high mobility and low 1/f noise. / QC 20100928

MOSFET

SOI

SiGe

strain

high-k

metal gate

1/f noise

low-frequency noise

mobility fluctuations

phonons

number fluctuations

traps

buried channel

mobility

substrate bias

Electronics

Elektronik

Novel concepts for advanced CMOS : Materials, process and device architecture

Wu, Dongping

January 2004

<p>The continuous and aggressive dimensional miniaturization ofthe conventional complementary-metal-oxide semiconductor (CMOS)architecture has been the main impetus for the vast growth ofIC industry over the past decades. As the CMOS downscalingapproaches the fundamental limits, unconventional materials andnovel device architectures are required in order to guaranteethe ultimate scaling in device dimensions and maintain theperformance gain expected from the scaling. This thesisinvestigates both unconventional materials for the gate stackand the channel and a novel notched-gate device architecture,with the emphasis on the challenging issues in processintegration.</p><p>High-κ gate dielectrics will become indispensable forCMOS technology beyond the 65-nm technology node in order toachieve a small equivalent oxide thickness (EOT) whilemaintaining a low gate leakage current. HfO₂and Al₂O₃as well as their mixtures are investigated assubstitutes for the traditionally used SiO₂in our MOS transistors. These high-κ filmsare deposited by means of atomic layer deposition (ALD) for anexcellent control of film composition, thickness, uniformityand conformality. Surface treatments prior to ALD are found tohave a crucial influence on the growth of the high-κdielectrics and the performance of the resultant transistors.Alternative gate materials such as TiN and poly-SiGe are alsostudied. The challenging issues encountered in processintegration of the TiN or poly-SiGe with the high-k are furtherelaborated. Transistors with TiN or poly-SiGe/high-k gate stackare successfully fabricated and characterized. Furthermore,proof-of-concept strained-SiGe surface-channel pMOSFETs withALD high-κ dielectrics are demonstrated. The pMOSFETs witha strained SiGe channel exhibit a higher hole mobility than theuniversal hole mobility in Si. A new procedure for extractionof carrier mobility in the presence of a high density ofinterface states found in MOSFETs with high-κ dielectricsis developed.</p><p>A notched-gate architecture aiming at reducing the parasiticcapacitance of a MOSFET is studied. The notched gate is usuallyreferred to as a local thickness increase of the gatedielectric at the feet of the gate above the source/drainextensions. Two-dimensional simulations are carried out toinvestigate the influence of the notched gate on the static anddynamic characteristics of MOSFETs. MOSFETs with optimizednotch profile exhibit a substantial enhancement in the dynamiccharacteristics with a negligible effect on the staticcharacteristics. Notched-gate MOSFETs are also experimentallyimplemented with the integration of a high-κ gatedielectric and a poly-SiGe/TiN bi-layer gate electrode.</p><p><b>Key words:</b>CMOS technology, MOSFET, high-κ, gatedielectric, ALD, surface pre-treatment, metal gate, poly-SiGe,strained SiGe, surface-channel, buried-channel, notchedgate.</p>

CMOS technology

MOSFET

high-k

gate dielectric

ALD

surface pre-treatment

metal gate

poly-SiGe

strained SiGe

surface-channel

buried-channel

notched gate

Développement d'un pixel innovant de type "temps de vol" pour des capteurs d'images 3D-CMOS / 3D image sensor, Time of flight pixel, Continuous-Wave modulation, buried channel transfer gate, gradual epitaxial layer

Rodrigues Gonçalves, Boris

09 January 2018

Dans l'objectif de développer des nouveaux capteurs d'image 3D pour des applications émergeantes, nous avons étudié un pixel de mesure de distance de type « temps de vol ». Nous avons proposé une nouvelle architecture de pixel basée sur la méthode « Continuous-Wave modulation » à trois échantillons par pixel. Cette méthode repose sur la mesure d'un déphasage entre la source lumineuse modulée en amplitude envoyée (source proche infrarouge) et le signal réfléchi par la scène à capturer. Le pixel de dimensions 6,2μm x 6,2μm intègre une photodiode pincée, trois chemins de transfert de charges pour l'échantillonnage successif du signal modulé reçu, et d'un quatrième chemin pour évacuer les charges excédentaires. Les différents chemins de transfert sont constitués d'une grille de transfert de charges de la photodiode vers une mémoire de stockage à canal enterré pour améliorer le rendement et la vitesse de transfert de charges; d'une mémoire à stockage en volume à base de tranchées capacitives profondes afin d'augmenter la dynamique; d'un substrat dont l'épaisseur et le profil de dopage ont été optimisés afin de collecter efficacement les charges photogénérées et ainsi augmenter les performances de démodulation. Un véhicule de test constitué d'une matrice de résolution de 464x197 pixels (QVGA) a été fabriqué, différentes variantes de pixels et différents essais technologiques ont été étudiées et analysées. La fonctionnalité du pixel a été vérifiée pour des fréquences de démodulation de 20MHz à 165MHz, utilisant une source laser de longueur d'onde 850nm ou 950nm. Une première image de profondeur acquise utilisant une matrice de test est une validation du pixel proposé / In order to develop new 3D image sensors for emerging applications, we studied “time of flight” pixel for distance measurement. We have proposed a new pixel architecture based on the "Continuous-Wave Modulation" method with three samples per pixel. This method is based on the measurement of a phase shift between the transmitted amplitude modulated light source (near-infrared source) and the signal reflected by the scene to be captured. The pixel of dimensions 6.2 μm x 6.2 μm integrates a pinned photodiode, three charge transfer paths for successive sampling of the received modulated signal, and a fourth path for anti-blooming purpose. The different paths are controlled by a buried-channel transfer gate for charges transfer from the photodiode to memory in order to improve the efficiency and speed of the charge transfer; A fully depleted memory based on capacitive deep trenches is used to increase the memory storage capacitance; thickness and doping profile of the substrate have been optimized to efficiently collect photogenerated and increase demodulation performance. The designed 464x197-pixel (QVGA) test chip has been fabricated, different pixel variants and different technology trials have been studied and analyzed. Pixel functionality has been verified for demodulation frequencies from 20 to 165MHz, using a laser source of wavelength 850nm or 950nm. A first acquired depth image using the test chip made is a validation of the proposed pixel

Capteurs d’image 3D

Pixel temps de vol

Modulation à onde continue

Grille de transfert à canal enterré

Substrat à profil de dopage graduel

3D image sensor

Time of flight pixel

Continuous-Wave modulation

Buried channel transfer gate

Gradual epitaxial layer

621.381