ナノエレクトロニクス市場における半導体材料・製造会社のビジネスチャンス

Summary:

In this report, NanoMarkets identifies the present and future opportunities for semiconductor materials and manufacturing equipment companies targeting the budding nanoelectronics industry. The report analyzes and comments on the efforts of both established and start-up companies in the nanoelectronics field, evaluates the viability of competing technology "approaches" for nanoelectronics and pinpoints current and future market potential.

Background:

As the chipmakers push manufacturing into the realm of nanotechnology - and state-of-the-art fabs are already producing sub-100 nm electronic devices - they are finding that conventional chip making techniques are running out of steam. Specifically, the devices that the semiconductor industry believes it will be building in a couple of years are too small to be built using standard lithography techniques. Since, for more than 30 years, the economics of the semiconductor industry has been centered around Moore's Law -- the idea that the number of transistors on a chip will double every 18 months -- this has sent research teams and commercial firms scurrying to find betters ways of making nanodevices.

Nanoelectronics encompasses both new silicon-based manufacturing processes and entirely new approaches involving nanotubes, nanowires, polymers and organic molecules. The potential revenues from new electronics manufacturing and materials processes are huge, because they must be widely adopted by the semiconductor industry if it is to continue on the same growth path as it did in past decades.

The semiconductor industry, however, is notoriously production oriented and what is seldom discussed, is whether there will be any real demand from the top of the value chain to justify the electronics industry's investment in nanotechnology. After all, the demand driver behind Moore's Law in the past was that millions of users were waiting for a chip that could run their favorite software at a faster speed than the current generation chip. Today, nobody is waiting for the next generation of Pentiums to run their Windows OS faster. Similarly, most mobile phones, consumer electronics, and home appliances use embedded electronics devices that are well within the capability of standard microelectronics.

The commercial justification for nanoelectronics would seem to lie in entirely new trends in computing, communications and IT. In this unique report, NanoMarkets enables readers to better understand drivers and demand patterns for nanoelectronics products, such as the trend towards "pervasive computing," "electronic paper" and super smart mobile devices. Which of these trends are real? Which are hype? Taking our demand-side analysis as a starting point, the report digs down to what requirements nanoelectronics devices will have to meet over the next few years and which of the R&D programs and commercial companies seem best prepared to seize the available opportunities.

The report will include forecasts of revenues generated by the nanoelectronics business broken out by component function (processor, logic, etc.) and by materials platform. As with all NanoMarkets reports, this report will also profile and analyze the activities of both public companies and start-ups active in this space.

Table of Contents

Executive Summary

Chapter One: Introduction

• Objective of this Report
• Scope of this Report
• Methodology of this Report

Chapter Two: Why Nanoelectronics?

• Introduction
• Key Drivers for Nanoelectronics:
• Pervasive computing
• Intelligent appliances
• Supercomputing, quantum computing and artificial intelligence
• Better displays and the replacement of paper
• Improved inputs for computers and IT systems
• Need for more security, monitoring and control
• The future of quantum encryption
• High-speed networking

Chapter Three: Technology Assessment

• Platforms for Nanoelectronics
• Platforms and Materials:
• Silicon nanoelectronics and the new lithography processes
• Nanotubes and nanowires
• Polymers
• Organic electronics
• Quantum dots and entanglement
• Components and Devices:
• Transistors
• CPUs
• Embedded processors
• Memory devices
• Logic devices
• Analog devices
• Sensors
• Emerging standards and standards groups

Chapter Four: The Players

• Agere
• AMD
• California Molecular Electronics Corporation (CALMEC)
• DuPont
• EV Group
• Fujitsu
• Hewlett Packard
• Hitachi
• IBM
• Infineon
• Intel
• Kovio
• Molecular Electronics Corp. (MEC)
• Molecular Imprints
• Motorola
• Nanochip
• NanoInk
• Nanosys
• Nantero
• NEC
• NVE
• Obducat
• Plastic Logic Rolltronics
• STMicroelectronics
• SUSS MicroTec
• Texas Instruments
• Thin Film Electronics
• Xerox
• ZettaCore

Chapter Five: Opportunities from Nanoelectronics

• Projections of Revenues from Nanoelectronics by Material and Device Type
• How Big are the Opportunities for Manufacturing Equipment Makers?