Resistive random access memory (RRAM) : from devices to array architectures / Shimeng Yu, Arizona State University.

Por:

Yu, Shimeng (Ingeniero electrico) [autor]

Tipo de material: Texto

TextoSeries Synthesis lectures on emerging engineering technologies ; # 6.Editor: San Rafael, California : Morgan & Claypool Publishers, 2016Fecha de copyright: ©2016Descripción: vii, 71 páginas : ilustraciones, diagramas, gráficas ; 24 cmTipo de contenido:

texto

Tipo de medio:

sin mediación

Tipo de soporte:

volumen

ISBN:

1627059296
9781627059299
162705930X
9781627059305

Tema(s):

Clasificación LoC:

TK 7895.M4 Y87.2016

Contenidos:

1. Introduction to RRAM technology -- 1.1 Overview of emerging memory technologies -- 1.2 RRAM basics -- 1.3 Recent research and development of RRAM technology --

2. Device fabrication and performances -- 2.1 Device fabrication: forming-free and scalability -- 2.2 Device performances -- 2.3 Device reliability --

3. RRAM characterization and modeling -- 3.1 Overview of RRAM physical mechanism -- 3.2 Materials and electrical characterization -- 3.3 Numerical modeling using kinetic Monte-Carlo method -- 3.4 Compact modeling for spice simulation --

4. RRAM array architecture -- 4.1 1T1R array -- 4.2 Cross-point array -- 4.3 Selector device -- 4.4 Peripheral circuits design -- 4.5 3D integration --

5. Outlook for RRAM's applications -- Bibliography -- Author biography.

Resumen: RRAM technology has made significant progress in the past decade as a competitive candidate for the next generation non-volatile memory (NVM). This lecture is a comprehensive tutorial of metal oxide-based RRAM technology from device fabrication to array architecture design. State-of-the-art RRAM device performances, characterization, and modeling techniques are summarized, and the design considerations of the RRAM integration to large-scale array with peripheral circuits are discussed. Chapter 2 introduces the RRAM device fabrication techniques and methods to eliminate the forming process, and will show its scalability down to sub-10 nm regime. Then the device performances such as programming speed, variability control, and multi-level operation are presented, and finally the reliability issues such as cycling endurance and data retention are discussed. Chapter 3 discusses the RRAM physical mechanism, and the materials characterization techniques to observe the conductive filaments and the electrical characterization techniques to study the electronic conduction processes. It also presents the numerical device modeling techniques for simulating the evolution of the conductive filaments as well as the compact device modeling techniques for circuit-level design. Chapter 4 discusses the two common RRAM array architectures for large-scale integration: one-transistor-one-resistor (1T1R) and cross-point architecture with selector. The write/read schemes are presented and the peripheral circuitry design considerations are discussed. Finally, a 3D integration approach is introduced for building ultra-high density RRAM array. Chapter 5 is a brief summary and will give an outlook for RRAM's potential novel applications beyond the NVM applications.

Existencias ( 1 )
Notas de título ( 7 )

Existencias
Tipo de ítem	Biblioteca actual	Colección	Signatura topográfica	Copia número	Estado	Fecha de vencimiento	Código de barras
Libros	Biblioteca Francisco Xavier Clavigero Acervo	Acervo General	TK 7895.M4 Y87.2016 (Navegar estantería(Abre debajo))	ej. 1	Disponible		UIA167428

Incluye bibliografía (páginas 57-69).

1. Introduction to RRAM technology -- 1.1 Overview of emerging memory technologies -- 1.2 RRAM basics -- 1.3 Recent research and development of RRAM technology --

2. Device fabrication and performances -- 2.1 Device fabrication: forming-free and scalability -- 2.2 Device performances -- 2.3 Device reliability --

4. RRAM array architecture -- 4.1 1T1R array -- 4.2 Cross-point array -- 4.3 Selector device -- 4.4 Peripheral circuits design -- 4.5 3D integration --

5. Outlook for RRAM's applications -- Bibliography -- Author biography.

RRAM technology has made significant progress in the past decade as a competitive candidate for the next generation non-volatile memory (NVM). This lecture is a comprehensive tutorial of metal oxide-based RRAM technology from device fabrication to array architecture design. State-of-the-art RRAM device performances, characterization, and modeling techniques are summarized, and the design considerations of the RRAM integration to large-scale array with peripheral circuits are discussed. Chapter 2 introduces the RRAM device fabrication techniques and methods to eliminate the forming process, and will show its scalability down to sub-10 nm regime. Then the device performances such as programming speed, variability control, and multi-level operation are presented, and finally the reliability issues such as cycling endurance and data retention are discussed. Chapter 3 discusses the RRAM physical mechanism, and the materials characterization techniques to observe the conductive filaments and the electrical characterization techniques to study the electronic conduction processes. It also presents the numerical device modeling techniques for simulating the evolution of the conductive filaments as well as the compact device modeling techniques for circuit-level design. Chapter 4 discusses the two common RRAM array architectures for large-scale integration: one-transistor-one-resistor (1T1R) and cross-point architecture with selector. The write/read schemes are presented and the peripheral circuitry design considerations are discussed. Finally, a 3D integration approach is introduced for building ultra-high density RRAM array. Chapter 5 is a brief summary and will give an outlook for RRAM's potential novel applications beyond the NVM applications.