Advanced CMOS Technology
(The 32/22/16nm Nodes)

The course has been newly updated to include all of the latest developments in CMOS processing and is technically current through October 2010.

The relentless drive in the semiconductor industry for smaller, faster and cheaper integrated circuits has brought the industry to the 32 nm technology node. The speed, computational power, and enhanced functionality of ICs based on this advanced technology promise to transform both our work and leisure environments. However the implementation of this technology has opened a Pandora’s box of manufacturing issues as well as set the stage for a range of manufacturing challenges that require revolutionary new process methodologies as well as innovative, new equipment for the 22 nm and 16 nm nodes. This seminar addresses all of these manufacturing issues with technical depth and conceptual clarity, and presents leading-edge process solutions to the new and novel set of problems presented by 32 nm node technology, as well as previews the upcoming manufacturing issues of the 22/16 nm nodes.

The central theme of this seminar is an in-depth presentation of the key 32/22/16 nm node technical issues: CD control, electrical leakage mitigation, high-k/metal gate integration, ultra-shallow junctions implementation, immersion lithography, mobility enhancement, Copper/low-k integration and other critical processing problems. Each section of the course will present the relevant technical issues in a clear and comprehensible fashion as well as discuss the proposed range of solutions and equipment requirements necessary to resolve each issue.

Date: October 18,19,20, 2010

Location: Hilton Santa Clara, Santa Clara California

Seminar Fee: $1,895.00

What's included:

1. Three days of instruction by industry experts with comprehensive, in-depth knowledge of the subject material
2. A high quality set of full-color lecture notes (a $395 value), including SEM & TEM micrographs of real- world IC structures that illustrate key points
3. Continental breakfast, hot buffet lunch, and coffee, beverages, & snacks served at both morning and afternoon breaks

Who is the seminar intended for?

• Process Development & Process Integration Engineers & Scientists
• Process Equipment Marketing, Applications, & Product Development Managers, Engineers, & Scientists
• Materials Supplier Marketing, Applications, & Product Development Managers, Engineers, & Scientists
• Fabless Design Engineers and Managers; Foundary Interface Engineers and Managers
• Process Engineers & Scientists
• Device Engineers & Scientists
• Semiconductor Manufacturing Engineers & Managers
• IC Product Engineering or Marketing Personnel
• VLSI Design Engineers

Download this seminar brochure as a .pdf file

Download Management Justification Letter

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DETAILED CONTENTS OF SEMINAR TOPICS:

1.  32nm Node Technology. The 32nm technology node represents a landmark in semiconductor manufacturing. It enables a 50% reduction in chip area compared to the 45nm node, and employs transistors that are substantially faster than anything ever previously fabricated. The 22/16 nm nodes will continue this performance trend. However, such performance comes at a significant increase in processing complexity and requires the solution of some very fundamental scaling issues, as well as the introduction of radical new approaches to semiconductor manufacturing. This section of the course highlights the key changes introduced at the 32nm node and describes the key technical issues that had to be resolved in order to make the 22/16nm nodes a reality.

• Technology node definition
• The promise of 32nm applications
• Technical roadblocks: problems and solutions
• Unique 32/22/16 nm manufacturing challenges

2.  Detailed 32nm Fabrication Sequence. The key to rapidly understanding any new technology is to view it in its entirety. This approach provides a context and a perspective that the study of isolated technical components cannot. Once a sense of technical perspective is established, the student can "drill-down" into each technical area of interest and expand their understanding of the subject matter. This portion of the seminar presents a detailed 32 nm Logic process flow from beginning-to-end (FEOL & BEOL). The underlying purpose of each process step will be explained and the processing options and equipment considerations in each major process module are highlighted. The purpose of this section of the course is to establish a baseline understanding of this new technology node and to provide a fundamental framework for the subsequent in-depth presentations on each technical issue. It includes:

• A detailed step-by-step 32nm fabrication process flow
• Front End Of Line (FEOL) processing options and technical considerations (new Hi-K o dielectric & metal gate, strain, and salicide integration techniques)
• Back End Of Line (BEOL) processing details (copper metallization, low-k dielectric, and barrier layer integration)
• The underlying purpose of each processing operation is discussed and the processing options and equipment considerations for each major module presented

3.  Flash & DRAM device module processing sequences. Logic processing often receives the most attention but this perspective overlooks the critical role played by DRAM, and increasingly, the ever-expanding role played by Flash technology. This section of the course describes in detail the device module fabrication sequence for these two important technologies, highlighting the key processing advances that have been made, and the processing issues remaining to be resolved for future technology nodes.

• Detailed step-by-step fabrication sequence for both the Flash and DRAM (trench and stacked capacitor) device modules
• The purpose of each processing step and the fabrication methodology used for each operation are explained in detail
• 3D packaging considerations and options are presented

4.  device architecture & materials for logic (HP, LP, ULP), memory (SRAM, DRAM, Flash), and Analog/RF/mixed signal applications. The electrical performance of CMOS devices & ICs is fundamentally determined by the CMOS physical structure (e.g., gate length), the 3D activated dopant profiles within the device, and the materials of construction employed for the device & contacts. This course will provide detailed descriptions and striking pictures of state-of-the-art CMOS devices for Logic (High Performance, Low Power, & Ultra-Low Power), Memory (DRAM, SRAM, Flash), and Analog/RF/mixed signal IC applications.

• Brief but technically comprehensive overview of CMOS device structure, function, and materials of construction for all these applications
• In-depth discussion of all key scaling and functional integration issues for all the applications
• Detailed device structure and technology roadmaps for all CMOS device applications

5.  Controlling sensitivity to process variation. Leading-edge (32/22/16nm) CMOS device technology is very sensitive to fab process and device layout/design variations. This section of the seminar provides a crisp review of the root cause of the increasing electrical performance sensitivity in CMOS devices to processing variations at 32/22/16nm. It will explain why these CMOS “nanotechnology” devices are so sensitive to fab process and design layout variations. It will also explain the leading-edge fab process and IC layout/design techniques that are required to control and reduce these yield-killing variations.

• Root causes of CMOS sensitivity to fab process and layout variations
• Detailed discussion of all traditional sources of variation (e.g., gate CD, other fab processes)
• Comprehensive explanation of new “CMOS nanotechnology” variations
• Techniques that effectively control or even reduce variation in state-of-the-art CMOS
• Lithography and etch process control issues: poly-gate, contact holes, and metal 1 CD process control and yield issues

6 . Controlling leakage and power dissipation. Leakage and active power dissipation have become "show-stopping" issues for further scaling of CMOS ICs. The challenge of device leakage and circuit power dissipation is so severe that both process and design solutions at the device level and circuit level design techniques are required in combination to effectively address the problem. This section of the seminar will: 1) describe all sources of device leakage and power dissipation, 2) describe the CMOS processing and design techniques that are employed to minimize leakage for low and ultra-low power logic and memory applications, and 3) identify and describe the most effective device and circuit level power management techniques that are employed at 32/22/16nm to mitigate device leakage/IC power dissipation.

• Leakage suppression techniques for subthreshold, junction, & gate dielectric leakage
• Power management techniques for active & passive power dissipation

7.  Key fabrication process control issues for 32/22/16 nm. Gate lithography, etch, and implant/anneal processing variations directly impact fundamental CMOS device structure, causing variation in device electrical function, IC performance variations, and lower yield. This section will explain the key CMOS device structure & functional variations that impact the performance quality (speed, power dissipation, timing closure, etc.) of digital ICs. The discussion will provide an intuitive conceptual linkage between CMOS device physical structure/function, manufacturing process variations, and final IC circuit performance variations. The scope of the discussion will include lithography, etch, thin film, and implant/thermal process control issues, and an in-depth discussion of state-of-the-art process control techniques (e.g., APC feed forward/feed back CD control methodology, other leading-edge parametric control techniques). It will also provide an in-depth discussion of state-of-the art processing techniques including lithography/etch CD control issues (e.g., 193 resist line-edge roughness, etch chamber control & matching, SEM (in-line) and IM (integrated metrology) CD metrology, etc.) and ultra-shallow junction formation techniques.

• Lithography/etch process control issues: polygate, contact hole, metal-1 CD control techniques
• Implant/thermal process control issues: Vt and other parametric variation control techniques
  • State-of-the-art ultra-shallow junction (USJ) formation techniques
• New sources of process sensitivity/yield impact and appropriate mitigation techniques

8.  State-of-the-art CMOS performance boosters (mobility enhancement techniques).
Conventional device performance scaling requires reducing the thickness of the gate oxide to increase the channel inversion charge density, which increases device drive current. However, gate oxide thickness scaling has been stalled at ~12Å due to rapidly increasing leakage (tunneling) as the gate oxide dielectric thickness is reduced. Also, as the device structure is scaled, device parasitic resistance is increasing and is robbing a significant fraction of the device performance increase (drive current) we expect with scaling. Alternate methods of increasing device performance (drive current) must be employed to compensate for this shortfall. Mobility enhancement technologies (strain, new channel orientations) are aggressively stepping forward to fill this requirement and are being widely implemented in 32/22/16nm fabrication processes. It is now clear that mobility enhancement technologies will be employed for all CMOS nodes through the end of the technology roadmap.

This section of the seminar will explain how mobility enhancement technologies work to improve mobility, drive current, and device performance. It will identify and describe all leading-edge mobility enhancement technologies and explain the details of how they are integrated into a CMOS manufacturing flow.

• How does strain work to improve carrier mobility and device performance?
• Leading-edge uniaxial tensile (NMOS) and compressive (PMOS) strain techniques
• Optimized channel orientation for NMOS & PMOS

9.  Lithography update: status and roadmap. The most important, fundamentally enabling technology for implementation of 32/22/16 node CMOS technology is a lithographic process capable of creating photoresist lines and spaces of appropriately small dimensions with adequate precision and reproducibility. Recently, immersion lithography technology has stepped into this role. This section of the seminar will provide an overview of the current status and future prospects for optical lithography for 32/22/16 node high-volume CMOS manufacturing.

• Current status and future prospects for optical lithography
• Double patterning techniques
• Future alternatives to optical lithography

10.  CMOS roadmap and device technology forecast. Ultimately, all good things must some to an end, and the end of classical CMOS has been predicted for at least the last two decades. Despite these dire predictions, the technology not only persists, it thrives. However, there is no avoiding the reality that with gate electrode dimensions of ~10nm and channel lengths well under 100 atoms in length, the end of classical CMOS if not at hand, is at least within sight. No discussion of advanced CMOS technology is complete without a peek into the future - 22nm and 16nm nodes. This final section of the course looks ahead to the 22/16 nm CMOS nodes and forecasts the evolution of CMOS device technology for all CMOS applications (logic, memory, and Analog/RF).

• Is the end of bulk, planar CMOS in sight?
• Key technology forecast issues and “nanoscale” effects - impact on CMOS device architecture/materials
• The two possible paths forward in CMOS device architecture

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The best instructors in the business will be teaching this course. Each instructor is a world-class expert in their respective field, with decades of industry experience. However, Threshold Systems has selected these presenters not just for their deep technical expertise, but also for their ability to present complex technical information in a clear and engaging manner. Each of these instructors is an experienced and skilled public speaker, and the accompanying course notes for this seminar are profusely illustrated with relevant graphics. It is our intention for you to leave this course with a clear understanding of the key enabling technologies that are revolutionizing semiconductor manufacturing.

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JERRY HEALEY BIOGRAPHY

Jerry Healey has been a technical professional in the semiconductor industry for 20 years, 8 years of which were spent as a Device Engineer at Motorola Semiconductor. He was formerly an instructor for UC Berkeley Extension (College of Engineering), and more recently was employed as a Process Integration Engineer at the Advanced Technology Development Facility, where he worked on 45 nm node development.

He is a renowned lecturer in the field of Silicon Processing, and his areas of expertise include process integration, technology transfer of new processes from R&D into manufacturing, embedded non-volatile memory processing, and mixed signal devices. His audiences remember him for the breadth of his knowledge regarding semiconductor manufacturing, his engaging lecture style, and the insightful color graphics he uses to illustrate his lectures.

An award winning public speaker, Mr. Healey has taught numerous courses to thousands of practicing engineers and scientists over the past 10 years. He has authored and co-authored numerous papers in the field of Silicon Processing, and is currently the president of Threshold Systems, a firm that provides consulting services and technical training seminars to the semiconductor industry.

“"Jerry Healey is a superb public speaker who has a knack for making complex technical subjects seem clear and understandable.”" - J. Blume, AMD

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ROBERT SIMONTON BIOGRAPHY

Robert Simonton is a widely recognized authority in the subjects of leading-edge CMOS front-end-of-line (FEOL) process integration trends and ion implantation process technology. With over thirty years experience in CMOS device and fabrication technology, Mr. Simonton brings unusual breadth and depth to his lecture topics.

Before 2000, Mr. Simonton has held senior product engineering, advanced product/process development, strategic marketing, and CMOS technology forecasting positions with leading semiconductor process equipment companies such as Varian and Eaton. In January 2000, Mr. Simonton founded Simonton Associates, a semiconductor technology consulting and educational services firm that specializes in resolving high-level product/technology development, technology/marketing management, and IP issues for leading-edge semiconductor IC fabrication companies, process equipment suppliers, and materials suppliers. His consulting and research activities keep him in close touch with key challenges and solutions at each new CMOS technology node.

Mr. Simonton has authored and co-authored over 40 technical papers and four book chapters on semiconductor process technology, and is a recipient of the SRC Outstanding Industrial Mentor Award. He has been a popular lecturer in the field of advanced silicon processing for over 15 years. His audiences remember him for his technical depth, broad industry experience, and his engaging, high-energy lecture style.

“"Mr. Simonton is a walking encyclopedia of information regarding semiconductor processing issues. His knowledge is both current and leading edge. I really enjoyed his talk immensely.”"
- T. Jamison, Intel

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