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电子探针、扫描电镜显微分析
中国科学院上海硅酸盐所
上海电子显微镜学会讲座 2002-11 微束分析 微束分析 Microbeam Analysis
: 利用一束细电子束、离子束、光束或粒子 束作用于试样产生的各种信息,进行成分、 形貌、结构及其他物理和化学特性的分析。 束班大小:微米-纳米。 主要功能:成分分析;结构分析;图像分析。 主要指标:束班大小、分辨率、空间分辨率、灵敏度、准确度等。 定量分析:微束分析是物理方法,由于物理过程的复杂性,成分定量基本都用标样比较法并进行修正计算。 典型微束分析仪器 1.? 电子束: 电子探针 EPMA ;扫描电镜 SEM-EDS ;分析电镜 AEM ;俄歇电子 谱 AES ;电子能量损失谱 EELS 。 2.离子微束: 离子探针 IMMA ;二次离子
SIMS . 3.光子束: 显微激光光谱 LMCES ,光电子 谱 ESCA,
质子探针 PIXA
常用微区分析仪器 俄歇电子谱仪(AES:Auger Electron Spectroscope ,也称扫描俄歇显微镜。表面分析仪器,可进行元素定量分析(能做三维元素分析)、形貌观察、价态分析。分析深度一般为1nm-2nm,分析H, He以外元素,对轻元素灵敏度高。 Al Z 13 , X射线产额:?k=0.4,
Auger电子产额:?k 0.96 C Z 6 , ?k
0.001, ?k 0.999
离子探针 IMMA Ion Microprobe Mass Analyser 全元素分析(H, He….. ,灵敏度高(10-8-10-14),分析直径1?m-2 ?m,有损分析。定量分析模型不完善,主要用作微量元素分析,绝对感量为10-18-10-19g,分析表面要剥离。
透射电镜 分辨率高 JEM-2010F点分辨率:0.19nm ,放大倍率高,可放大一百多万倍。可进行形貌观察,成分分析,微区晶体结构 晶格像,结构像 ,晶界分析。 制样困难,分析区域小,代表性差。 定量结果准确度较差,无标准样品。 扫描探针显微镜
正在加载中,请稍后...TEM-SN-透射电镜(TEM)用氮化硅薄膜窗口-上海纳腾仪器有限公司
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上海纳腾仪器有限公司
扫描探针显微镜$r$n光学显微镜$r$n纳米光学轮廓仪$r$n教学型凝固点测定仪$r$n日本原装桌面式隔振平台
您所在位置:&>>>&&TEM-SN透射电镜(TEM)用氮化硅薄膜窗口
TEM-SN透射电镜(TEM)用氮化硅薄膜窗口
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【简单介绍】
透射电镜(TEM)用氮化硅薄膜窗口
【详细说明】
&SHNTI的X-射线薄膜窗能够实现软X-射线(如真空紫外线)的最大透射率。主要用于同步辐射X射线透射显微成像时承载样品。 X-射线越软(能量越低),穿透能力越差,所需氮化硅薄膜窗越薄。特别在&离轴&状态工作(即薄膜与光束成一定角度)时,也需要较薄的薄膜窗口,便于X射线更好地穿透。&SHNTI提供的氮化硅薄膜窗口是利用现代MEMS技术制备而成,由于此种氮化硅窗口选用低应力氮化硅(0-250MP)薄膜,因此比计量式和ST氮化硅薄膜更坚固耐用。SHNTI提供的氮化硅薄膜窗口非常适合应用于透射成像和透射能谱等广泛的科学研究领域,例如,X-射线(上海光源透射成像/能谱线站)、TEM、SEM、IR、UV等。&现在SHNTI可以提供X-射线显微成像/能谱(同步辐射)用氮化硅薄膜窗系列产品,规格如下:&外框尺寸 (4种标准规格):&5 mm x 5 mm (窗口尺寸:1.0 mm 或和 1.5 mm 方形)&7.5 mm x 7.5 mm (窗口尺寸:2.0 mm 或 2.5 mm)&10 mm x 10 mm (窗口尺寸:3.0 mm 或 5 mm 方形)&边框厚度: 200&m、381&m、525&m。&Si3N4薄膜厚度:50、100、150和200nm&SHNTI也可以为用户定制产品(30-500nm),但要100片起订。&本产品为一次性产品,SHNTI不建议用户重复使用,本产品不能进行超声清洗,适合化学清洗、辉光放电和等离子体清洗。与X射线用氮化硅窗口类似,透射电镜(TEM)用氮化硅薄膜窗口也使用低应力氮化硅薄膜基底。但整体尺度更小,适合TEM装样的要求。窗口有单窗口和多窗口阵列等不同规格。同时SHNTI也定制多孔氮化硅薄膜窗口。&现在SHNTI可以提供透射电镜(TEM)用氮化硅薄膜窗系列产品,规格如下:&外框尺寸:&3 mm x 3 mm (窗口尺寸:0.5 mm,薄膜厚度:50 nm) 3 mm x 3 mm (窗口尺寸:1.0 mm,薄膜厚度:50 nm) 3 mm x 3 mm (窗口尺寸:1.0 mm,薄膜厚度:100 nm) 边框厚度: 200&m、381&m。&Si3N4薄膜厚度: 50nm、100nm&SHNTI也可以为用户定制产品(30-200nm),但要100片起订。&本产品为一次性产品,SHNTI不建议用户重复使用,本产品不能进行超声清洗,适合化学清洗、辉光放电和等离子体清洗。&技术指标:&表面平整度:&我们认为薄膜与其下的硅片同样平整, TEM用氮化硅薄膜窗口的表面粗糙度为:0.6-2nm。完全适用于TEM表征。&亲水性&该窗格呈疏水性,如果样品取自水悬浮液,悬浮微粒则不能均匀地分布在薄膜上。用等离子蚀刻机对薄膜进行亲水处理,可暂时获得亲水效果。虽然没有对其使用寿命进行过测试,但预期可以获得与同样处理的镀碳TEM网格相当的寿命。我们可以生产此种蚀刻窗格,但无法保证其使用寿命。如果实验室有蚀刻工具也可对其进行相应的处理提高其亲水性能。&温度特性:&氮化硅薄膜窗口产品是耐高温产品,能够承受1000度高温,非常适合在其表面利用CVD方法生长各种纳米材料。&化学特性:&氮化硅薄膜窗口是惰性衬底。&应用简介和优点:&1、 适合TEM、SEM、AFM、XPS、EDX等的对同一区域的交叉配对表征。&2、 大窗口尺寸,适合TEM大角度转动观察。&3、 无碳、无杂质的清洁TEM观测平台。&4、 背景氮化硅无定形、无特征。&5、 耐高温、惰性衬底,适应各种聚合物、纳米材料、半导体材料、光学晶体材料和功能薄膜材料的制备环境,(薄膜直接沉积在窗口上)。&6、 生物和湿细胞样本的理想承载体。特别是在等离子体处理后,窗口具有很好的亲水性。。&7、 耐高温、惰性衬底,也可以用于化学反应和退火效应的原位表征。&8、 适合做为胶体、气凝胶、有机材料和纳米颗粒等的表征实验承载体。&氮化硅薄膜应用范围非常广,甚至有时使不可能变为可能,但所有应用都有无氮要求(因样本中有氮存在):&惰性基片可用于高温环境下,通过TEM、SEM或AFM(某些情况下)对反应进行动态观察。&作为耐用基片,首先在TEM下,然后在SEM下对同一区域进行&匹配&。&作为耐用匹配基片,对AFM和TEM图像进行比较。&聚焦离子束(FIB)样本的装载,我们推荐使用多孔薄膜,而非不间断薄膜。&许多研究纳米微粒,特别是含氮纳米微粒的人员发现此种薄膜窗格在他们实验中不可缺少。气凝胶和干凝胶的基本组成微粒尺寸极小,此项研究人员也同样会发现氧化硅薄膜窗格的价值。&优点:&& SEM应用中,薄膜背景不呈现任何结构和特点。&& x-射线显微镜中,装载多个分析样的唯一方法。&& 无氮&高温应用,氮化硅薄膜在1000&C高温下仍能保持稳定的性能。&使用前清洁:&氮化硅薄膜窗格在使用前不需进行额外清洁。有时薄膜表面边角处会散落个别氧化物或氮化物碎片。由于单片网格需要从整个硅片中分离,并对外框进行打磨,因此这些微小碎片不可避免。尽管如此,我们相信这些碎片微粒不会对您的实验产生任何影响。&如果用户确实需要对这些碎片进行清理,我们建议用H2SO4 : H2O2 (1:1)溶液清洁有机物,用H2O:HCl: H2O2 (5:3:3)溶液清洁金属。&通常不能用超声波清洗器清洁薄膜,因超声波可能使其粉碎性破裂。&详细情况,您可以与我们取得联系。我们为您一一解答。&
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中国福建省福州市仓山万达广场B6-1302 邮编:350028全球电子显微镜市场-光学・穿透式(TEM)・扫描式(SEM)-:占有率・策略・预测(2009年至2015年)
Worldwide Optical, Transmission TEM, and Scanning SEM Electron Microscope Market Shares, Strategies, and Forecasts, 2009 to 2015
出版日期: 日
内容信息: 英文 723
335 TABLES AND FIGURES
本报告已在日停止出版
本报告书内容包括:全球电子显微镜市场调查、电子显微镜市场概要、动向、促进成长因素、、市场占有率、预测、主要企业的电子显微镜技术等分析、主要产品説明、主要企业介绍等。包含图表共计723页的。内容纲要摘记如下:
显微镜市场预测
显像研究・产业利用
所有主要先进国家投资的必要性
奈米科技显微镜
第1章 显微镜市场概要・动向
电子显微镜
原子间力显微镜法
显微镜法及显微镜分析的新主题
显微镜主机及配件模组
显微镜市场区隔
解剖显微观察需要在轴上测量
复合显微镜
显微镜用照明设备
显微镜用显像技术
奈米技术开创材料革命的道路
第2章 显微镜市场的占有率・预测
显微镜市场的促进因素
显微镜市场的占有率
显微镜市场的预测
光学显微镜及电子显微镜市场区隔
穿透式电子显微镜(TEM)及扫描式电子显微镜(SEM)市场
TEM及SEM的研究用电子显微镜市场预测
光学显微镜的市场占有率
光学显微镜的市场预测
聚焦离子束及电子扫描式客置化显微镜
显微镜市场的地区别市场
第3章 显微镜产品説明
Carl Zeiss
Meiji Techno
American Optical
Diagnostic Instruments
Meiji Techno Microscopes
FEI 的电子显微镜SEM及TEM
Alicona的Imaging、等
第4章 显微镜技术
IBM的显微镜有比现在MRI细上1亿倍的分辨率
显微镜商业的技术动向
表面科学技术
第5章 网路相机企业介绍
Alicona Imaging
Angstrom Advanced
Asylum Research
Bausch and Lomb
Carl Zeiss
Danaher Corporation
JPK Instruments
Nanotec Electronica / Nanonics
Olympus、等
Breakthrough technology in microscopy brings advancements that provide
customers with the power to discover things they have never seen before, and
to solve problems never before solvable.
Microscope markets are segmented as optical microscopes, electron microscopes,
scanning probe microscopes, and focused ion beam microscopy. Optical
microscopes are light microscopes. The optical microscope is limited in the
minimum size and nature of the features it can resolve by manufacturability
constraints and the physics of light. While optical microscopes once accounted
for the bulk of all microscopes sold in the world, today their percentage of
total revenue is shrinking.
New microscopy technologies have been developed to overcome the limitations of
light microscopes. Electron, scanning probe, and focused ion beam microscopy
are essential aspects of different approaches to visualization at the
nanoparticle level. The field of microscopy continues to evolve rapidly, as
new requirements and imaging technologies are developed.
Technology integration, marking the convergence of information technology and
digital imaging, is expected to change standard laboratories into advanced
research centers. Current innovations in the microscopy industry are towards
development of microscopes with higher precision and resolution. Developments
in image restoration, reconstruction, and other related fields will continue
to influence the industry.
Innovations in electronics, engineering and industrial materials permit the
industry to effectively overcome conventional barriers, allowing new systems
to evolve based on new technologies.
Custom-assembled systems are based on modular approaches to product delivery.
Platforms are implemented as frameworks that accept any of a variety of
modules. In this manner customization is supported in the microscope industry.
These custom-assembled systems enable end users incorporate existing workflow.
The microscope markets are driven by the need for research facilities to
attract the most qualified researchers. The best researchers are attracted to
good equipment. They will move to where the best equipment is. For enterprises
and universities to land and hang on to leading researchers, they have to
upgrade their equipment or those people are gone in a year.
The research and industrial use of imaging has shifted rapidly with the
increasing significance of nanotechnology. To look at particles on the
nano-scale requires increased sophistication and use of more expensive imaging
equipment. This means that fewer organizations can afford the imaging
equipment needed to stay competitive and that those organizations that can
afford the very expensive imaging equipment will tend to be quite large.
Nanotechnology funding at $8.5 billion in 2008 is anticipated to increase
rapidly as countries respond ot the economic meltdown. Every dollar invested
in nanotechnology research turns $5 in tax dollars within a year and continues
to provide that level of taxes for the next 20 to 50 years. This is a very
good investment.
Countries are learning that they need to compete at a level of industrial
development in the new global economy. The financial meltdown represents at
its core the disintegration of national boundaries in the traditional sense.
In its place are global enterprises based in a particular country, providing
tax dollars to that base nation.
In this global economy, innovation is central. Innovation is based on software
systems that improve productivity. Software is used to manage information and
make it more accessible. Innovation improves enterprise and business decision
making. Nanotechnology and electron microscopes are a central aspect of this
global initiative.
Table of Contents
Microscope Executive Summary
Microscope Market Driving Forces
Microscope Market Shares
Carl Zeiss
Microscope Market Forecasts
Research And Industrial Use Of Imaging
Japan' s Leading National Institute Orders Powerful Microscope from FEI
Every Major Developed Country Needs To Invest Nanotechnology
Microscopes
King Abdullah University of Science and Technology and FEI Team for
Nanoscience Facility
Japan' s Leading National Institute Orders Powerful Microscope from FEI
FEI' s Titan Krios TEM Selected by Leading Life Science Research Centers
IBM Microscope 100 Million Times Finer Resolution Than Current MRI
1. Microscopes Market Description and Market Dynamics
1.1 Electron Microscope
1.1.1 Electron Microscope Economic Driving Forces
1.1.2 Transmission Electron Microscope (TEM)
1.1.3 TEM Uses Magnetic Lenses Guide the Electrons
1.1.4 Scanning Electron Microscope
1.1.5 TEM and SEM used for Nanotechnology
1.1.6 Nanotechnology: Using a Bottom-Up Approach
Larger Structures Are Built Or Grown Atom By Atom Or Molecule By
1.2 Atomic Force Microscopy
1.2.2 Force Spectroscopy
1.3 Emerging Topics In Microscopy And Microanalysis
1.3.1 Intravital Two-Photon Microscopy
1.3.2 Understanding Of Interactions Between Organic And Mineral
Interfaces
1.3.3 Routine Application Of Imaging, Spectroscopy And Diffraction
Techniques For The Analysis Of Individual Nanostructured Materials
1.3.4 Irradiation By Energetic Electrons
1.3.5 Focused Ion Beam (FIB) Science And Technology
1.3.6 Semiconductor Quantum Dots (QDs)
1.3.7 Advances of Electron Backscatter Diffraction
1.3.8 Development Of Nano-Materials
1.3.9 Approaches To Achieve Sub-Light Wavelength Resolution
1.3.10 Advanced Coating Stability
1.3.11 Quantitative Atom-Probe Tomography (APT)
1.3.12 Electron Microscopy Structural Issues
1.4 Microscope Frames And Accessory Modules
1.4.1 Fluorescent Or Phase Microscope Modules
1.4.2 Modern Materials, Lubricants And Machine Tools
1.5 Microscope Market Segments
1.5.1 Bio-Med Microscope Market
1.5.2 Clinical Microscope Market
1.5.3 Industrial Microscope Market
1.5.4 Electronics Market Microscopes
1.5.5 Metalurgical Microscopes
1.6 Stereomicroscopy Need To Measure On-Axis
1.6.1 Stereo Microscopes
1.7 Compound Microscopes
1.8 Microscopy Illumination Methods
1.9 Microscopy Imaging Techniques
1.10 Nanotechnology Paves The Way For A Revolution In Materials
2. Microscope Market Shares and Market Forecasts
2.1 Microscope Market Driving Forces
2.2 Microscope Market Shares
2.2.1 Carl Zeiss
2.3 Microscope Market Forecasts
2.4 Optical Microscope and Electron Microscope Market Segments
2.5 Electron Microscope Transmission (TEM) and Scanning (SEM)
2.5.1 Electron Microscope Transmission Electron Microscopy (TEM) and
Scanning Electron Microscope (SEM) Market Shares
2.5.2 Electron Microscope Transmission Electron Microscopy (TEM) and
Scanning Electron Microscope (SEM) Market Forecasts
2.5.3 Hitachi S-5500 In-lens FE-SEM
2.5.5 Japan' s Leading National Institute Orders Powerful Microscope from
2.5.6 King Abdullah University of Science and Technology and FEI Company
Team to Create Major Nanoscience Facility
2.5.7 Jeol Scanning Electron Microscopes
2.5.8 JEOL
2.5.9 JEOL Electron Optics
2.5.10 JEOL Analytical Electron Microscope Instruments
2.5.11 Carl Zeiss ORION& Helium Ion Microscope
2.6 TEM and SEM Research Electron Microscope Market Forecasts
2.6.1 Electron Microscopes Are Helping Materials Scientists
2.6.2 Electron Microscope TEM and SEM Research Markets
2.6.3 Electron Microscope TEM and SEM Life Sciences Market Shares
2.6.4 Electron Microscope TEM and SEM Life Sciences Market Forecasts
2.6.5 Nanoparticles for Drug Delivery
2.6.6 Electronics Electron Microscope TEM and SEM Market Shares
2.6.7 Electron Microscope TEM and SEM Electronics Market Forecasts
2.6.8 Electron Microscope SEM and TEM Industry Market Shares
2.6.9 Electron Microscope SEM and TEM Industry Market Forecasts
2.7 Optical Microscopes Market Shares
2.7.1 Olympus Group
2.7.2 Nikon Sales Strength
2.7.3 Nikon Biological Microscopes Coolscope II
2.7.4 Nikon Inverted Microscopes (For Research) Eclipse Ti-E
2.7.5 Danaher / Leica Microsystems
2.7.6 Leica M80 Stereomicroscope
2.7.7 Carl Zeiss
2.8 Optical Microscopes Market Forecasts
2.8.1 Worldwide Optical Research Microscope Shipments, Market Shares
2.8.2 Olympus SZX Research Stereomicroscope System
2.8.3 Worldwide Optical Research Microscope Shipments, Market Forecasts
2.8.4 Worldwide Bio-Med And Life Science Optical Microscope Market Shares
2.8.5 Worldwide Bio-Med And Life Science Optical Microscope Market
2.8.1 Worldwide Optical Clinical and Surgical Microscope Market Shares
2.8.1 Worldwide Optical Clinical and Surgical Microscope Market Forecasts
2.8.1 Worldwide Optical Industrial and Semiconductor Microscope Market
2.8.1 Nikon Advanced Integration With Peripherals Via Intelligent
2.8.2 Nikon Motorized Laser TIRF Illumination Unit
2.8.3 Nikon ECLIPSE L300D Episcopic Illumination Type
2.8.4 Worldwide Optical Industrial and Semiconductor Microscope Market
2.8.5 Carl Zeiss
2.8.6 Olympus Materials Research Imaging Solutions
2.9 Customized Focused Ion And Electron Beam Columns Microscopes
2.9.1 Orsay Physics
2.10 Lensless Microscope Technology Electron Microscopy And Optical
Microscopy Markets
2.10.1 Phase Focus
2.11 Microscope Market Regional Segments
2.11.1 Carl Zeiss Revenue By Region
2.11.2 Carl Zeiss Regional Revenue Segments
2.11.3 FEI Revenue by Region
2.11.4 Agilent Revenue by Region
3. Microscope Product Description
3.1 Olympus
3.1.1 Olympus SZX Research Stereomicroscope System
3.1.2 Olympus Integration of Apochromatic System
3.1.3 Olympus Vertical Observation
3.1.4 Olympus Multiphoton Microscope
3.1.5 Olympus Confocal Microscope
3.1.6 Olympus Confocal Microscope Laser Monitoring Function
3.1.7 Olympus Photo Stimulation
3.1.8 Olympus Unmixing
3.1.9 Olympus Colocalization
3.1.10 Olympus Industrial Micro-Imaging Segments
3.1.11 Olympus Materials Research Imaging Solutions
3.1.12 Olympus Ceramics
3.1.13 Olympus Plastics Microscopes
3.1.14 Olympus Materials Forming
3.1.15 Olympus Semiconductor Imaging Solutions
3.1.16 Olympus - Bacus Laboratories - Virtual Microscopy
3.2.1 Nikon ECLIPSE L300D Episcopic
3.2.2 Nikon CFI60
3.2.3 Nikon Biological Microscopes COOLSCOPE II
3.2.4 Nikon Low Magnification Model
3.2.5 Nikon ECLIPSE E200POL
3.2.6 Nikon Inverted Microscopes (For Research) Eclipse Ti-E
3.2.7 Nikon High-Speed Motorized Control And Acquisition
3.2.8 Nikon Advanced Integration With Peripherals Via Intelligent
3.2.9 Nikon Motorized Laser TIRF Illumination Unit
3.2.10 Nikon Photo Activation Illumination Unit
3.2.11 Nikon Multiport Design With A Maximum Of Five Imaging Ports
3.2.12 Nikon Industrial Microscopes
3.2.13 Nikon ECLIPSE L300D Episcopic Illumination Type
3.2.14 Nikon Stereoscopic Microscopes
3.2.15 Nikon Semiconductor Inspection Equipment
3.2.16 Nikon Inspection Equipment
3.3 Carl Zeiss
3.3.1 Carl Zeiss Axio
3.3.2 Zeiss Stereo Microscopes
3.3.3 Zeiss SteREO Discovery.V20
3.3.4 Zeiss SteREO Discovery Final Assembly Of The Stereomicroscope
3.3.5 Zeiss SteREO Discovery
3.3.6 Zeiss AxioVision Microscope Software
3.3.7 Carl Zeiss SteREO Discovery.V20 Provides Depth Perception
3.3.8 Carl Zeiss SteREO Discovery.V12
3.3.9 Zeiss Confocal Microscopes
3.3.10 Zeiss Confocal Systems Axio CSM 700
3.3.11 Carl Zeiss Axio CSM 700 Reliably Assesses Surface Quality
3.3.12 Carl Zeiss Topography for LSM
3.3.13 Carl Zeiss ORION& Helium Ion Microscope
3.4.1 Leica M80 Stereomicroscope
3.4.2 Leica M400 E Surgical Microscope
3.4.3 Detailed Description
3.4.4 Leica M80
3.4.5 Leica TCS SP5 X Supercontinuum Confocal Microscope
3.5 Unitron
3.6 Meiji Techno
3.8 American Optical
3.9 Lumenera
3.10 Diagnostic Instruments
3.11 Meiji Techno Microscopes
3.11.1 Meiji MT4000 Series Laboratory and Student Compound Microscopes
in Transmitted Light Brightfield and Phase Contrast.
3.11.2 Meiji MT4200 Binocular & MT4300 Trinocular
3.11.3 Meiji MT5000 Series Laboratory Compound Microscopes in
Transmitted Light Brightfield and Phase Contrast
3.11.4 Meiji IM7000 Series and Meiji MT9000 Series
3.11.5 Meiji RZ Research Zoom Stereomicroscope:
3.11.6 Meiji EMZ Zoom Stereomicroscopes:
3.12 FEI Electron Microscopes SEM and TEM
3.12.1 FEI Phenom Applications
3.12.2 Metallurgical Applications Using The FEI Phenom
3.12.3 Forensic Applications of FEI Scanning Electron Microscopy
3.12.4 FEI Micron Scale Insect Anatomy
3.12.5 FEI Phenom Use for Pharmaceutical Particle Inspection
3.12.6 FEI Topography Imaging With Phenom
3.12.7 FEI Product Offerings
3.12.8 FEI SEM Transition in Imaging
3.12.9 FEI TEM Product Positioning
3.13 Hitachi
3.13.1 Hitachi S-5500 In-lens FE-SEM
3.14 Jeol Scanning Electron Microscopes
3.14.1 Jeol JXA-8500F Electron Probe Microanalyzer (EPMA)
3.14.2 JEOL Electron Microscope Semiconductor Equipment
3.15 Alicona Imaging
3.15.1 Alicona Imaging InfiniteFocus
3.15.2 Alicona Imaging InfiniteFocusRobot
3.15.3 Alicona Imaging InfiniteFocus Real 3D
3.15.4 Alicona Imaging InfiniteFocus Inline
3.15.5 Alicona Imaging EdgeMaster
3.15.6 Alicona Imaging MeX
3.16 Anderson Materials Evaluation EDS, XRF, and FTIR
3.16.1 Anderson Materials XPS Surface Analysis Technique
3.16.2 Anderson Materials XPS System Capabilities
3.16.3 Anderson Materials XPS Applications
3.16.4 Anderson Materials ESCA Surface Analysis Applications
3.16.5 Anderson Materials X-ray Photoelectron Spectroscopy
3.17 Westover Scientific Telecommunications Fiber Optic Network
3.18 AIST-NT Co
3.18.1 AIST-NT Co Products
3.19 Angstrom - Advanced
3.20 Angstrom Advanced
3.21 Agilent Technologies Atomic Force Microscopes
3.21.1 Agilent Technologies In Particle Analysis
3.21.2 Agilent Particle Analysis Target Markets
3.21.3 Agilent Inks And Pigments
3.21.4 Agilent Specialty Chemicals
3.22 Veeco
3.23 Asylum Research
3.23.1 Asylum Cypher AFM Features
3.23.2 Asylum Nanoindenting
3.23.3 Asylum Research Atomic Force Microscope (AFM)
3.23.4 Asylum Research Atomic Force Microscope Technical Innovations
3.24 JPK Instruments
3.25 Nanosurf FlexAFM easyScan 2
3.26 Bruker AXS
3.27 Nanonics
3.27.1 Nanonics Confocal Microscope
3.27.2 Nanonics Confocal Microscope
3.27.3 Nanonics Dual Microscope
3.27.4 Nanonics Dual Microscope Combined Upright and Inverted Systems
3.27.5 Nanonics SPM & NSOM Systems
3.27.6 Nanonics Transparent Correlation of Raman and SPM Imaging.
3.27.7 Nanonics Parallel Imaging
3.27.8 Nanonics Raman Mapping with Z-Control
3.27.9 Nanonics Examples of the Power of Integrated Raman/AFM
3.27.10 Nanoindentation Correlated with Material Properties
3.27.11 Local Stress of MEMs Devices
3.27.12 Intermittent Contact Mode in Liquids
3.28 Nanotec Electr&nica
3.28.1 Nanotec Products
3.29 Cervantes AFM System
3.30 Dulcinea Control System
3.31 Omicron Multiprobe MBE and S System For Thin Film Deposition
3.31.1 Omicron Multiprobe MXPS Thin Film Studies With Pulsed Laser
Deposition (PLD) System
3.31.2 Omicron Multiscan LAB:
3.31.3 Omicron Customized Solution for 2.5 - 350 K STM Operation in 3D
Magnetic Fields
3.32 Veeco
3.32.1 Veeco BioScope II Atomic Force Microscope -
Combining atomic
force And Optical Microscopy
3.32.2 Veeco BioScope SZ Atomic Force Microscope Designed For Life
Sciences Research
3.32.3 Veeco Caliber Atomic Force Microscope AFM with Research-Quality
3.32.4 Veeco Dimension 3100 Scanning Probe Microscope -
research versatility
3.32.5 Veeco Dimension 5000 Scanning Probe Microscope Large-Sample
Metrology And Imaging
3.32.6 Veeco Dimension V Scanning Probe Microscope -
High-Resolution Research Performance And Versatility
3.32.7 Veeco Electrochemical SPM Real-Time Electrochemical Processes
3.32.8 Veeco EnviroScope Atomic Force Microscope -
Combined AFM Imaging
With Sample Environmental Control
3.32.9 Veeco Innova Scanning Probe Microscope Low Noise, High Resolution
3.32.10 Veeco MultiMode V Scanning Probe Microscope High Resolution SPM
3.32.11 NanoMan VS Scanning Probe Microscope Enabling Advanced Nanoscale
Surface Manipulation
3.32.12 Veeco Scanning Probe Microscope Force Spectroscopy Research
3.33 Agilent
3.34 Orsay Physics S.A.
3.34.1 Orsay Physics S.A. COBRA-FIB Column
3.35 Seiko
3.35.1 Seiko SUPRA 55VP Versatile High Performance VP SEM
3.35.2 Carl Zeiss NVision 40 FIB-SEM
3.35.3 Carl Zeiss NVision DES100 1540XB CrossBeam/
4. Microscope Technology
4.1 IBM Microscope 100 Million Times Finer Resolution Than Current
4.1.1 IBM Research
4.2 Technological Trends in the Microscopy Business
4.3 Industry Overview
4.3.1 Key Trends in the Laboratory Equipment Market
4.3.2 Semiconductor Industry
4.4 Surface Science Technologies
4.4.1 Surface Analyzers
5. Microscope Company Profiles
5.1 Alicona Imaging
5.2 Aligent
5.2.1 Agilent Technologies Inc. (NYSE: A) High-Precision Atomic Force
Microscopes (AFM)
5.2.2 Agilent Technologies Atomic Force Microscopes
5.2.3 Agilent Buys Nano Instruments
5.2.4 Agilent Technologies Atomic Force Microscopes Consumables
5.2.5 Agilent Gold Mica Substrates
5.2.6 Agilent Hydrogen Flame Annealing
5.2.7 Agilent Net Revenue Fiscal Year 2008
5.2.8 Agilent Electronic and Communications Measurement
5.2.9 Agilent Bio-Analytical Measurement
5.2.10 Agilent Laboratories
5.2.11 Agilent Technologies Fourth Quarter 2008 Revenue
5.2.12 Agilent Electronic Measurement
5.2.13 Agilent Technologies Revenue
5.3 Angstrom Advanced
5.4 Asylum Research
5.5 Bausch and Lomb
5.6 Bruker
5.6.1 Bruker Acquires S.I.S. Surface Imaging System In the AFM Market
5.7 Carl Zeiss
5.7.1 Carl Zeiss Regional Revenue Segments
5.7.2 Carl Zeiss Foundation Organizational Structure
5.7.3 Carl Zeiss Reorganization of Business Units
5.7.4 Carl Zeiss AxioVision Physiology Microscope System
5.7.5 Carl Zeiss Meditec
5.7.6 Carl Zeiss Revenue By Strategic Business Segment
5.7.7 Carl Zeiss Revenue By Region
5.7.8 Zeiss Outlook
5.7.9 Zeiss Clinical Diagnostics ACIS III System Developed by Clarient
5.8 Danaher Corporation
5.8.1 Danaher Revenue For Fourth Quarter And Full Year 2008
5.8.2 Danaher Operating Segments
5.8.3 Danaher Third Quarter Revenue
5.8.4 Danaher / Leica Brand
5.8.5 Danaher / Leica Microsystems
5.8.6 Leica Microsystems'
Life Science Division
5.8.7 Leica Professional Instrumentation
5.8.8 Leica Industrial Technologies
5.8.9 Danaher Tools & Components
5.8.10 Leica Microsystems Acquires Surgipath Medical Industries, Inc.
5.8.11 Leica Microsystems'
Life Science Division
5.8.12 Danaher Leica Microsystems'
Industry Division
5.8.13 Danaher Leica Microsystems'
Biosystems Division
5.8.14 Danaher Leica Microsystems'
Surgical Division
5.8.15 Danaher / Leica MM AF Imaging Systems and MetaMorph Software
5.9.1 FEI Acquires Intellection Holdings
5.9.2 FEI Suppliers
5.9.3 FEI Technologies And Applications
5.9.4 FEI Worldwide Presence
5.9.5 Japan' s Leading National Institute Orders Powerful Microscope from
5.9.6 FEI' s Titan Krios TEM Selected by Leading Life Science Research
Centers in Asia
5.9.7 King Abdullah University of Science and Technology and FEI Company
Team to Create Major Nanoscience Facility
5.9.8 FEI Revenue
5.9.9 FEI Strategic Positioning
5.9.10 FEI Life Sciences Instrument Positioning
5.9.11 FEI Three major markets -
Research & Industry, Electronics and
Life Sciences Segment Information
5.9.12 FEI Electronics Segments
5.9.13 FEI Research and Industry
5.9.14 FEI Life Sciences
5.9.15 FEI Service and Components
5.9.16 FEI Electronics Market
5.9.17 FEI Research And Industry Market
5.9.18 FEI Life Sciences
5.9.19 FEI Order Cancellations
5.9.20 FEI Sales by Geographic Region
5.9.21 FEI North America
5.9.22 FEI Europe
5.9.23 FEI Asia-Pacific Region
5.9.24 FEI SEM Phenom Scope
5.9.25 FEI Fits in the Semiconductor Microscope Equipment Supply Chain
5.9.26 FEI Leader in Tools for Nanotechnology
5.9.27 FEI Titan Electron Microscope (TEM) Designed By Philips Design
5.10 Hitachi
5.11.1 Jeol Electron Optics
5.11.2 Jeol Analytical Instruments
5.11.3 Jeol Semiconductor Equipment
5.11.4 Jeol Thin Film Coating Systems
5.11.5 Jeol Medical Equipment
5.12 JPK Instruments
5.12.1 JPK Instruments Business units
5.12.2 Molecular Analytics Division
5.13 Kaust
5.14 Labomed
5.15 Motic
5.15.1 Motic Contract With Carl Zeiss
5.16 Nanotec Electr&nica / Nanonics
5.17 Nanosurf
5.17.1 Nanosurf Integrated Microscopy
5.17.2 Nanosurf Technology
5.18 NIKON
5.18.1 Nikon Revenue
5.18.2 Nikon Instruments Business
5.18.3 Nikon Geographical Segments
5.18.4 Nikon Instrument Product Line
5.18.5 Nikon Stereoscopic Microscopes
5.18.6 Nikon Cameras for Microscopy
5.18.7 Nikon Bioscience Field Market Environment and Business Trends
5.18.8 Nikon Business Strategy
5.18.9 Nikon Instruments and Biosciences Business
5.19 Olympus
5.19.1 Olympus Microscopes For Industrial Applications
5.19.2 Olympus Micro-Imaging
5.19.3 Olympus Centre Strengthens R&D In Lab Equipment
5.20 Omicron
5.20.1 Omicron High-Performance STM Operation
5.20.2 Omicron Customized Solution
5.21 Orsay Physics S.A.
5.22 Phase Focus
5.22.1 Phase Focus ' Lenless'
Optical Microscope
5.22.2 Phase Focus / Fusion IP &250k Funding
5.23 Raith
5.23.1 Raith Secure Customers Investments
5.24 Seiko Instruments Inc. (SII)
5.24.1 Seiko Holdings
5.24.2 Seiko Watch Corporation
5.24.3 Seiko Clock
5.24.4 Seiko Precision
5.24.5 Seiko Instruments (SII)
5.24.6 Seiko Epson
5.25 Thermo Fisher Scientific
5.26 Veecro
5.26.1 Veeco Third Quarter and Nine Month 2008 Revenue
5.27 Westover Scientific
5.28 Selected Microscopy Vendors
5.28.1 Atomic Force Microscope Manufacturers
5.28.2 Grandeye
5.28.3 BioTek
5.28.4 Avo Photonics
List of Tables and Figures
Table ES-1
Microscope Market Driving Forces
Table ES-1 (Continued)
Microscope Market Driving Forces
Table ES-2
Technology Impact on Microscope Market Driving Forces
Table ES-3
Worldwide Microscope Shipments Market Shares, Dollars, 2008
Figure ES-4
Worldwide Optical and Electron Microscope Market Forecasts, Dollars,
Figure ES-5
FEI From Wafer to Atomic Resolution
Figure ES-6
FEI Industry Transition in Imaging
Figure 1-1
Platinum Electrode Measuring One Hundredth Of A Nanometer Deposited On
Pyramid Shaped AFM Tip Via Focused Ion Beam (Fib) Deposition
Emerging Topics In Microscopy And Microanalysis
Commercial Microscope Modules
Microscope Market Segments
Stereo Microscope Features
Table 1-5 (Continued)
Stereo Microscope Features
Microscope Market Driving Forces
Table 2-1 (Continued)
Microscope Market Driving Forces
Technology Impact on Microscope Market Driving Forces
Worldwide Microscope Shipments Market Shares, Dollars, 2008
Worldwide Microscope Shipments Market Shares, Dollars, 2008
Figure 2-5
Worldwide Optical and Electron Microscope Market Forecasts, Dollars,
Worldwide Total Optical and Electron Microscope Market Forecasts,
Figure 2-7
Worldwide Optical and Electron Microscope Market Segments, 2008
Figure 2-8
Worldwide Optical and Electron Microscope Market Segments, 2015
Worldwide Optical and Electron Microscope Market Segments, Dollars,
Figure 2-10
FEI Magellan Nanoscale Characterization Down To The Level of Atoms
Figure 2-11
Improvements in Visualization from SEM to TEM
Figure 2-12
FEI Titan Nanoscale Visualization Down To The Level Of Atoms
Table 2-13
Comparison of AFM, TEM, SEM, and Optical Microscopy Techniques
Table 2-14
Worldwide TEM and SEM Electron Microscope Shipments Market Shares,
Dollars, 2008
Table 2-15
Worldwide TEM and SEM Electron Microscope Shipments Market Shares,
Dollars, 2008
Table 2-16
Worldwide Electron Microscope Market Forecasts, Dollars,
Table 2-17
Worldwide Electron Microscope Market Forecasts, Dollars,
Figure 2-18
Worldwide TEM and SEM Electron Microscope Shipments, Research, Bio-Med
and Life Sciences, Clinical and Surgical, Industrial, Mining and Materials,
Electronics and Semiconductor, and Ion Beam Market Forecasts, Units and
Figure 2-19
Worldwide Research TEM and SEM Electron Microscope Shipments Market
Shares, Dollars, 2008
Table 2-20
Worldwide Research TEM and SEM Electron Microscope Shipments Market
Shares, Dollars, 2008
Table 2-21
JEOL Electron Microscope Products
Table 2-22
JEOL Analytical Instrument Products
Figure 2-23
Carl Zeiss ORION& Helium Ion Microscope
Figure 2-24
Worldwide Research TEM and SEM Electron Microscope Market Forecasts,
Figure 2-25
Nanotechnology Funding of National Programs
Table 2-26
FEI Electron Microscope Research Positioning
Table 2-27
Worldwide Research TEM and SEM Electron Microscope Shipments Market
Forecasts, Units and Dollars,
Table 2-28
Electron Microscope TEM and SEM Research Segment Growth Drivers
Table 2-29
Worldwide Bio-Med and Life Science Shipments TEM and SEM Electron
Microscope Market Shares, Dollars, 2008
Table 2-30
Worldwide Bio-Med and Life Science Shipments TEM and SEM Electron
Microscope Market Shares, Dollars, 2008
Figure 2-31
Worldwide Bio-Med and Life Science TEM and SEM Electron Microscope
Market Forecasts, Dollars,
Figure 2-32
Worldwide Bio-Med and Life Science TEM and SEM Electron Microscope
Market Forecasts, Dollars,
Table 2-33
TEM and SEM Life Sciences Market Growth Factors
Table 2-33 (Continued)
TEM and SEM Life Sciences Market Growth Factors
Figure 2-34
Life Sciences Market Growth
Table 2-35
FEI Solutions For Structural Biology
Table 2-36
University and Government Lab Life Science Applications
Figure 2-37
Nanoparticles for Drug Delivery
Table 2-38
Nanotechnology Life Sciences Market Growth Factors
Table 2-39
Worldwide Electronics and Semiconductor TEM and SEM Electron Microscope
Shipments Market Shares, Dollars, 2008
Table 2-40
Worldwide Electronics and Semiconductor TEM and SEM Electron Microscope
Shipments Market Shares, Dollars, 2008
Figure 2-41
Worldwide Electronics TEM and SEM Electron Microscope Market Forecasts,
Table 2-42
Worldwide Electronics and Semiconductor TEM and SEM Electron Microscope
Shipments Market Forecasts, Units and Dollars,
Table 2-43
Electron Microscope Semiconductor Equipment Products
Table 2-44
Electron Microscope TEM and SEM Electronics Market Growth Drivers
Table 2-45
Electron Microscope TEM and SEM Electronics Market Tactics:
Table 2-46
Worldwide Industrial Mining and Materials TEM and SEM Electron
Microscope Shipments Market Shares, Dollars, 2008
Table 2-47
Worldwide Industrial Mining and Materials TEM and SEM Electron
Microscope Shipments Market Shares, Dollars, 2008
Table 2-48
Worldwide Industrial, Mining and Materials TEM and SEM Electron
Microscope Shipments Market Forecasts, Units and Dollars,
Table 2-49
Worldwide Industrial, Mining and Materials TEM and SEM Electron
Microscope Shipments Market Forecasts, Units and Dollars,
Table 2-50
Thin Film Coating System Products
Table 2-51
Worldwide Optical Microscopes Market Shares, Dollars, 2008
Table 2-52
Worldwide Optical Microscope Shipments Market Shares, Dollars, 2008
Figure 2-53
Worldwide Optical Microscope Market Forecasts, Dollars,
Figure 2-54
Worldwide Optical Microscope Market Forecasts, Dollars,
Figure 2-55
Worldwide Optical Microscope Shipments, Research, Bio-Med and Life
Sciences, Clinical and Surgical, Industrial and Semiconductor, Market
Forecasts, Units and Dollars,
Figure 2-56
Worldwide Optical Research Microscope Shipments, Market Shares, Dollars,
Figure 2-57
Worldwide Optical Research Microscope Shipments, Market Shares, Dollars,
Figure 2-57
Worldwide Optical Research Microscope Market Forecasts, Dollars,
Figure 2-58
Worldwide Bio-Med and Life Science Optical Microscope Shipments, Market
Shares, Dollars, 2008
Figure 2-59
Worldwide Bio-Med and Life Science Optical Microscope Shipments, Market
Shares, Dollars, 2008
Figure 2-60
Worldwide Bio-Med And Life Science Optical Microscope Forecasts,
Figure 2-61
Worldwide Optical Clinical and Surgical Microscope Shipments Market
Shares, Dollars, 2008
Table 2-62
Worldwide Optical Clinical and Surgical Microscope Shipments Market
Shares, Dollars, 2008
Figure 2-61
Worldwide Optical Clinical and Surgical Microscope Shipments Market
Forecasts, Dollars,
Figure 2-62
Worldwide Optical Industrial and Semiconductor Microscope Shipments
Market Shares, Dollars, 2008
Figure 2-63
Worldwide Optical Industrial and Semiconductor Microscope Shipments
Market Shares, Dollars, 2008
Figure 2-64
Worldwide Optical Industrial and Semiconductor Microscope Market
Forecasts, Dollars,
Table 2-65
Customized Focused Ion And Electron Beam Column Microscope Market
Competitive Factors
Figure 2-66
Worldwide Customized Focused Ion and Electron Beam Columns Microscope
Shipments Market Shares, Dollars, 2008
Table 2-67
Worldwide Customized Focused Ion and Electron Beam Columns Microscope
Shipments Market Shares, Dollars, 2008
Figure 2-68
Worldwide Focused Ion Beam and Electron Beam Columns Electron Microscope
Market Forecasts, Dollars,
Figure 2-69
Worldwide Focused Ion Beam and Electron Beam Columns SEM and TEM
Electron Microscope Market Forecasts, Dollars,
Table 2-70
Regional Microscope Shipment Analysis Market Shares, Dollars, 2008
Table 2-71
Regional Microscope Shipment Analysis Market Shares, Dollars, 2008
Figure 5-72
FEI Growth and Regional Diversity
Table 2-73
FEI Nanotechnology Research Center Penetration
Figure 3-1
Olympus SZX16 Advanced Research Microscope
Olympus SZX16 Research Microscope Benefits
Table 3-2 (Continued)
Olympus SZX16 Research Microscope Benefits
Olympus SDF Objective Lenses Features
Figure 3-4
Olympus Multiphoton Microscope
Olympus FV1000MPE TWIN Features
Olympus Confocal Microscope Benefits
Olympus Confocal Microscope Evolved Laser Light Stimulation
Olympus Confocal Microscope Evolved Basic Performance
Olympus Confocal Microscope Quantification
Table 3-10
Olympus Confocal Microscope High Sensitivity
Figure 3-11
Olympus Confocal Microscope
Table 3-12
Olympus Industrial Micro-Imaging Segments
Figure 3-13
Olympus Semiconductor Imaging Solutions
Table 3-14
Olympus Virtual Microscopy Applications
Table 3-15
Nikon CFI60 Features
Figure 3-16
Nikon CFI60
Figure 3-17
Nikon COOLSCOPE2 Main Screen And Controller
Table 3-18
Nikon Low Magnification Features
Table 3-19
Nikon Low Magnification Microscope Features
Table 3-19 (Continued)
Nikon Low Magnification Microscope Features
Figure 3-20
Nikon ECLIPSE E200POL
Figure 3-21
Nikon Inverted Microscopes For Research ECLIPSE Ti-E
Table 3-22
ECLIPSE L300D Episcopic Illumination Type
Figure 3-23
Nikon ECLIPSE L300D Episcopic Illumination Type
Table 3-24
Selected Nikon Industrial Microscopes and Accessories and Other
Table 3-25
Nikon Stereoscopic Zoom Microscope SMZ1500 Features Olympus
Semiconductor Imaging Solutions
Table 3-14
Olympus Virtual Microscopy Applications
Table 3-15
Nikon CFI60 Features
Figure 3-16
Nikon CFI60
Figure 3-17
Nikon COOLSCOPE2 Main Screen And Controller
Table 3-18
Nikon Low Magnification Features
Table 3-19
Nikon Low Magnification Microscope Features
Table 3-19 (Continued)
Nikon Low Magnification Microscope Features
Figure 3-20
Nikon ECLIPSE E200POL
Figure 3-21
Nikon Inverted Microscopes For Research ECLIPSE Ti-E
Table 3-22
ECLIPSE L300D Episcopic Illumination Type
Figure 3-23
Nikon ECLIPSE L300D Episcopic Illumination Type
Table 3-24
Selected Nikon Industrial Microscopes and Accessories and Other
Table 3-25
Nikon Stereoscopic Zoom Microscope SMZ1500 Features
Figure 3-26
SMZ1500 With Epi-Fluorescence Attachment
Table 3-27
Stereoscopic Zoom Microscope Products
Table 3-28
Nikon Wafer Edge Bevel Inspection System WES-3000 Major Features
Figure 3-29
Nikon Wafer Edge Bevel Inspection System WES-3000
Table 3-30
Nikon Wafer Edge Bevel Inspection System Applications and Functions
Table 3-31
Nikon Wafer Edge Bevel Inspection System Products
Table 3-32
Nikon Inspection Equipment
Figure 3-33
Zeiss Axio
Figure 3-34
Zeiss Stereo Microscope
Figure 3-35
Zeiss SteREO Lumar
Table 3-36
Zeiss SteREO Discovery.V20
Table 3-37
Zeiss SteREO Discovery.V20 Features
Table 3-38
Zeiss SteREO Discovery.V20 Microscopic Sharper Images Benefits
Table 3-39
Zeiss SteREO Discovery Stereomicroscope Final Assembly Process
Figure 3-40
Zeiss Final Assembly Of The Stereomicroscope
Figure 3-41
Zeiss Benefits of Sharper Image From Computer Based Alignment
Figure 3-42
Carl Zeiss SteREO Discovery.V20 Image Quality
Table 3-43
Carl Zeiss Stereomicroscopy Benefits
Table 3-44
Carl Zeiss SteREO Discovery.V12 Stereomicroscopy Applications
Figure 3-45
Axio Observer
Table 3-46
Zeiss Live Cell Imaging under Physiological Conditions
Table 3-47
Zeiss Imaging
Figure 3-48
Zeiss Confocal Microscopes Support Fluorescence Correlation Spectroscopy
To Visualize Dynamics At The Molecular Level
Figure 3-49
Carl Zeiss Axio CSM 700
Figure 3-50
Carl Zeiss LSM 700 Confocal Laser Scanning Microscope 3D Topography &
Fluorescence Measurements
Figure 3-51
Zeiss High-End Confocal Microscope
Figure 3-52
Carl Zeiss LSM 5 Macros
Figure 3-53
Carl Zeiss AxioVision Physiology Microscope System
Figure 3-54
Carl Zeiss ORION& Helium Ion Microscope
Table 3-55
Leica Microscope Product Positioning
Figure 3-56
Leica M80 stereomicroscope
Table 3-57
Leica M400 E Surgical Microscope Key Features
Figure 3-58
Leica M125 Trinocular Zoom Stereomicroscope with Ergonomic Tilting
Figure 3-59
Leica Transmitted Light Darkfield Example
Table 3-60
Leica Microsystems GmbH Wetzlar, Germany
Table 3-61
Leica Optical Microscope Product Set
Figure 3-62
Leica M205 A Stereomicroscope
Table 3-63
Leica M205 A Key Features
Table 3-64
American Optical Cycloptic Stereomicroscope
Figure 3-65
American Optical Cycloptic Microscope
Table 3-66
Meiji' s EMZ Stereomicroscope Models
Figure 3-67
Meiji Microscopes
Table 3-68
Meiji EMZ13TR Trinocular Zoom Stereo
Table 3-69
FEI' s Phenom& Desktop SEM Key Specifications
Figure 3-70
FEI Scanning Microscope
Table 3-71
FEI Phenom Desktop SEM Modules
Figure 3-72
FEI Broad Product Positioning
Figure 3-73
FEI Throughput Solution
Figure 3-74
Microscope Industry Transition in Imaging
Figure 3-75
FEI SEM Magellan Extreme High Resolution
Figure 3-76
FEI Magellan SEM Semi Process Development Application
Figure 3-77
FEI Magellan Nanoscale Characterization Down To The Level Of Atoms
Figure 3-78
FEI Titan Nanoscale Visualization Down To The Level Of Atoms
Figure 3-79
FEI TEM Titan For Biology
Figure 3-80
FEI Solutions for Cellular Biology: 3D Tomography Software
Figure 3-81
FEI Emerging Solutions for Biology
Figure 3-82
FEI Solutions for Nanoparticles
Table 3-83
Hitachi Electron Microscopes
Figure 3-84
Hitachi H-kV TEM
Table 3-85
Hitachi S-5500 In-lens FE-SEM Features
Table 3-86
Hitachi S-5500 In-lens FE-SEM Product Number:S-5500 Features
Figure 3-87
Hitachi S-5500 In-lens FE-SEM
Figure 3-88
Hitachi TEM
Table 3-89
Hitachi FIB + SEM TM-1000 Tabletop Microscope Benefits
Table 3-90
Hitachi TEM System Specifications
Figure 3-91
Jeol Scanning Electron Microscope
Table 3-92
Jeol JXA-8500FThe Electron Microscope Benefits
Table 3-93
Jeol Electron Microscope Semiconductor Products
Figure 3-94
Alicona Imaging InfiniteFocus Robot
Table 3-95
Anderson Materials XPS Surface Analysis Technique
Table 3-96
Anderson Materials ESCA Samples and Materials
Figure 3-97
Westover Scientific Telecommunications Fiber Optic Network Probe
Microscope
Figure 3-98
Westover Scientific FiberChek2 Probe
Figure 3-99
Westover Scientific Fiber Probes
Table 3-100
AIST-NT Co Products
Figure 3-101
AIST-NT Images
Figure 3-102
AIST-NT Piezo Response Imaging
Figure 3-103
AIST-NT Topography image of PZT
Figure 3-104
AIST-NT Images Piezo response image (normal force). Left - amplitude.
Right - phase.
Figure 3-105
AIST-NT Polymer Images
Figure 3-106
AIST-NT Images
Figure 3-107
AIST-NT Images Nanolithography
Figure 3-108
AIST-NT Images Diamond Materials
Figure 3-109
AIST-NT MaterialsImages Kelvin Probe Microscopy image
Figure 3-110
Angstrom Advanced Atomic Force Microscope and Scanning Probe Microscope
Figure 3-111
Angstrom Advanced Ellipsometer
Table 3-112
Agilent Atomic Force Microscopes industry segments
Table 3-113
Agilent Atomic Force Microscopes Applications
Figure 3-114
Veeco AFMs for Research
Figure 3-115
Veeco AFMs
Figure 3-116
Asylum' s MFP-3D AFM
Table 3-117
Asylum Cypher AFM Features
Figure 3-118
Asylum Research Closed loop STM Showing Graphite Atoms, 6nm Scan
Figure 3-119
Asylum Research Automated Laser Alignment
Figure 3-120
Asylum Research Loop Image Of Domains Of Surfactant Hemi-Micelles
Surrounding A Defect On Graphite, 200nm Scan
Figure 3-121
Asylum Research. Closed Loop Image Of Extracellular Face Of
Bacteriorhodopsin In Buffer
Table 3-122
Asylum Research Modules
Table 3-123
Asylum Types of Microscopy
Table 3-124
Asylum Cypher AFM
Table 3-125
Asylum Specifications
Table 3-126
Asylum Scanner Modules
Table 3-127
Asylum Standard View Module Specifications
Table 3-128
Asylum Research Atomic Force Microscope Technical Innovation
Figure 3-129
Asylum Research Atomic Force Microscope
Figure 3-130
Asylum Research Atomic Force Microscope MFP-3D Head
Figure 3-131
Asylum Research Atomic Force Microscope Nano-Positioning System
Figure 3-132
Asylum Research Atomic Force Microscope MFP-3D XY Scanner
Figure 3-133
Asylum Research Atomic Force Microscope MFP-3D XY
Figure 3-134
Asylm Image Of A Hard Disk, 20&m scan Science Applications
Figure 3-135
Lithography Nanografting of thiols on a Au(111) surface. 1.5&m Scan
Table 3-136
JPK Instruments Solutions
Table 3-137
JPK Instruments Applications
Table 3-138
JPK Instruments Major AFM Modes
Figure 2-139
Nanosurf easyScan 2Product Lines
Figure 3-140
Nanosurf Mobile S Provides Portable, All-in-One AFM System
Figure 3-141
Nanosurf Nanite
Table 3-142
Nanosurf Nanite Features
Figure 3-143
Bruker AXS
Figure 3-144
Nanonics Confocal Microscope
Table 3-145
Nanonics Confocal Microscope Features
Table 3-146
Nanonics Dual (upright/inverted) Microscope
Table 3-147
Nanonics Dual Microscope
Figure 3-148
Nanonics Dual Microscope Combined Upright and Inverted Systems
Figure 3-149
Nanonics Dual Microscope Combined Upright and Inverted Systems
Figure 3-150
Nanonics Systems Combining AFM and Raman
Figure 3-151
Nanonics AFM without Optical Obstruction
Figure 3-152
Nanonics Parallel Imaging of a Silicon Semiconductor
Table 3-153
Nanonics Difference Between Raman Mapping With And Without Z-Control
Vibration Mode of Diamond at 1334cm-1
Figure 3-154
Raman Shift as a Function of Local Stress Location
Figure 3-155
Omicron Multiprobe MXPS System For Thin Film Studies
Figure 3-156
Omicron Multiscan LAB Combined With a Multiprobe MXPS System
Figure 3-157
Omicron Customized Solution for 2.5 -
350 K STM Operation in 3D
Magnetic Fields
Figure 3-158
Omicron Customized Microscope
Table 3-159
Veeco BioScope II Atomic Force Microscope Product Description
Table 3-160
Veeco BioScope SZ Atomic Force Microscope Product Features:
Table 3-161
Veeco Caliber Atomic Force Microscope Product Features:
Table 3-162
Veeco Dimension 3100 Scanning Probe Microscope Product Features:
Table 3-163
Veeco Dimension 5000 Scanning Probe Microscope Product Features:
Table 3-164
Veeco Dimension V Scanning Probe Microscope Product Features:
Table 3-165
Veeco Electrochemical SPM Product Features:
Table 3-166
Veeco EnviroScope Atomic Force Microscope Product Features & Benefits:
Table 3-167
Veeco Innova Scanning Probe Microscope Product Features:
Table 3-168
Veeco MultiMode V Scanning Probe Microscope Product Features:
Table 3-169
NanoMan VS Scanning Probe Microscope Product Features:
Table 3-170
Veeco Scanning Probe Microscope Product Features & Benefits:
Figure 3-171
Agilent 5500 AFM (N9410S)
Figure 3-172
Agilent 5500 AFM Imaging Modes
Figure 3-173
Agilent Photodetector Atomic Visualization
Figure 3-174
Agilent Region Where The Tip Approaches The Surface
Figure 3-175
Orsay Physics S.A. COBRA-FIB Column
Table 3-176
Seiko ULTRA 55 Transmission Electron Microscope Features
Figure 3-177
Zeiss NVision 40 FIB-SEM NVision 40 FIB-SEM Cross Beam System
Table 3-178
Carl Zeiss NVision 40 FIB-SEM Features
Computerization Of Microscopic Manufacturing Procedure Benefits
Alicona Microscope Applications Research And Development
Agilent Electronic And Bio-Analytical Measurement Positioning
Agilent Nanotechnology Microscope Instruments
Table 5-3 (Continued)
Agilent Nanotechnology Microscope Instruments
Agilent Nanotechnology Microscope Instruments Agilent Applications
Table 5-4 (Continued)
Agilent Nanotechnology Microscope Instruments Agilent Applications
Table 5-4 (Continued)
Agilent Nanotechnology Microscope Instruments Agilent Applications
Agilent Imagining Modes
Agilent Technologies Atomic Force Microscopes Consumables
Figure 5-7
Agilent Revenue by Market Segment Q4 2008
Figure 5-8
Agilent Revenue by Market Segment FY 2008
Figure 5-9
Agilent Revenue by Geographical Region Q4 2008
Figure 5-10
Agilent Revenue by Geographical Region FY 2008
Table 5-11
Agilent Networks Communications Measurement Types
Table 5-12
Agilent General Purpose Test Products
Table 5-13
Agilent Communications Technology Addressed with Test Equipment
Table 5-14
Agilent Bio-Analytical Measurement Business Application-Focused Solutions
Table 5-15
Agilent Chemical and Segment Analysis Market Focus
Table 5-16
Agilent Key Product Categories For The Bio-Analytical Measurements
Table 5-17
Markets In Which Carl Zeiss Participates
Figure 5-18
Carl Zeiss AxioVision Physiology Microscope System
Figure 5-19
Leica Microsystems Latest Products
Table 5-20
Life Science Division Products
Table 5-21
Danaher Leica Microsystems'
Life Science Division Products
Table 5-22
Danaher Leica Microsystems'
Industry Division Products
Table 5-23
Danaher Leica Microsystems'
Biosystems Division Products
Table 5-24
Danaher Leica Microsystems'
Surgical Division Products
Figure 5-25
FEI Growth and Regional Diversity
Table 5-26
FEI Overall Revenue Levels, Electronics vs. Other Levels
Table 5-27
FEI Nanotechnology Research Center Penetration
Figure 5-28
FEI Life Sciences Instrument Landscape
Table 5-29
FEI Strategic Positioning
Table 5-30
FEI Q3 2008 Summary Results
Table 5-31
FEI Broad Product Line That Creates And Measures Nanostructures
Figure 5-32
FEI Product Track
Table 5-33
FEI Titan - World' s Most Powerful Electron Microscope Features
Table 5-34
FEI Imago Scientific Instruments Collaboration
Figure 5-35
FEI Industry Transition in Imaging
Figure 5-36
FEI From Wafer to Atomic Resolution
Figure 5-37
FEI Life Sciences Instrument Landscape
Figure 5-38
FEI Role in Life Sciences
Figure 5-39
FEI Titan Krios and Titan Global Life Sciences Regional Activity
Figure 5-40
FEI Segment Analysis
Table 5-41
Jeol Electron Optic Products
Table 5-42
Jeol Analytical Instruments Products
Table 5-43
Jeol Semiconductor Equipment Products
Table 5-44
Jeol Thin Film Coating System Products
Table 5-45
Jeol Medical Equipment Products
Table 5-46
Jeol Priority Fields Of The Basic Plan For Scientific Technologies
Table 5-47
Selected Jeol Microscope Products
Table 5-48
Motic Products
Figure 5-49
Nikon Segment and Regional Revenue Analysis Source: Nikon.
Figure 5-50
Nikon Imaging Segment Revenue Analysis
Figure 5-51
Nikon Imaging, Precision Equipment, and Instruments Segment Revenue
Table 5-52
Nikon Imaging, Precision Equipment, and Instruments Segment Revenue
Figure 5-53
Nikon Regional Segment Revenue Analysis
Table 5-54
Nikon Regional Segment Revenue Analysis
Figure 5-55
Nikon Financial Results by Quarter
Table 5-56
Nikon Financial Results by Quarter
Table 5-57
Nikon Consolidated Financial Results
Table 5-58
Nikon Instrument Product Line
Table 5-59
Nikon Biological Microscopes
Table 5-60
Nikon Industrial Microscopes
Table 5-61
Nikon Stereoscopic Microscope Products
Table 5-62
Nikon Cameras for Microscopy
Table 5-63
Nikon Microscopic Image Recording Equipment
Figure 5-64
Nikon Product Development Strategy
Table 5-65
Nikon Wafer Edge Chips And Damage Microscopes Features
Figure 5-66
Olympus Microscopes
Table 5-67
Orsay Physics S.A. Customers
Table 5-67 (Continued)
Orsay Physics S.A. Customers
Table 5-68
Veeco Instruments
Table 5- 69
Selected Microscopy Vendors
Table 5-70
Selected Atomic Force Microscope Manufacturers
