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Â鶹ԭ´´ > NanoRobotics - Global Â鶹ԭ´´ Outlook (2017-2026)

NanoRobotics - Global Â鶹ԭ´´ Outlook (2017-2026)

Publication ID: 
SMRC0519040
Publication Date: 
May 1, 2019
Pages: 
180
Publisher: 
Stratistics MRC
Countries: 
Global [1]
USD 4,150.00

Please choose the suitable license type from above. More details are given under tab "Report License Types" below.

Robotics [2]
Industry & Manufacturing [3]
Description: 

Global Nanorobotics Â鶹ԭ´´ is accounted for $4.10 Billion in 2017 and is expected to reach $11.88 Billion by 2026 growing at a CAGR of 12.5% during the forecast period. Growing application of nanotechnology and regenerative medicine, rising acceptance and preferment of entrepreneurship and increasing investments by government and universities are the key factors fuelling the market growth. However, high manufacturing cost may hinder the growth of the market.

Nanorobotics is an evolving technology arena that creates robots or machines which have machinery near to the scale of a nanometre (10−9 meters). It denotes the nanotechnology engineering regulation of planning, designing, and building nanorobots, primarily from molecular components. Nanorobotics is an attractive new field, especially in medicine, which focus on directed drug delivery using nanoscale molecular machines.

By Type, Nanomanipulator is expected to hold considerable market growth during the forecast period. Nanomanipulator is a specialized nanorobot and microscopic viewing system for working with objects on an extremely small scale. Nanomanipulators are mainly used to influence the atoms and molecules and were among the first nanorobotic systems to be commercially accessible. By geography, Europe dominated the highest market share due to rising aging population and rising governmental healthcare expenditure.

Some of the key players in Nanorobotics include Bruker, JEOL, Thermo Fisher Scientific, Ginkgo Bioworks, Oxford Instruments, EV Group, Imina Technologies, Toronto Nano Instrumentation, Klocke Nanotechnik, Kleindiek Nanotechnik, Xidex, Synthace, Park Systems, Smaract and Nanonics Imaging

Types Covered:
• Nanomanipulator
• Magnetically Guided
• Bacteria-Based
• Bio-Nanorobotics

Applications Covered:
• Biomedical
• Nanomedicine
• Mechanical
• Other Applications

Regions Covered:
• North America
o US
o Canada
o Mexico
• Europe
o Germany
o UK
o Italy
o France
o Spain
o Rest of Europe
• Asia Pacific
o Japan
o China
o India
o Australia
o New Zealand
o South Korea
o Rest of Asia Pacific
• South America
o Argentina
o Brazil
o Chile
o Rest of South America
• Middle East & Africa
o Saudi Arabia
o UAE
o Qatar
o South Africa
o Rest of Middle East & Africa

What our report offers:
- Â鶹ԭ´´ share assessments for the regional and country level segments
- Â鶹ԭ´´ share analysis of the top industry players
- Strategic recommendations for the new entrants
- Â鶹ԭ´´ forecasts for a minimum of 9 years of all the mentioned segments, sub segments and the regional markets
- Â鶹ԭ´´ Trends (Drivers, Constraints, Opportunities, Threats, Challenges, Investment Opportunities, and recommendations)
- Strategic recommendations in key business segments based on the market estimations
- Competitive landscaping mapping the key common trends
- Company profiling with detailed strategies, financials, and recent developments
- Supply chain trends mapping the latest technological advancements

Free Customization Offerings:
All the customers of this report will be entitled to receive one of the following free customization options:
• Company Profiling
o Comprehensive profiling of additional market players (up to 3)
o SWOT Analysis of key players (up to 3)
• Regional Segmentation
o Â鶹ԭ´´ estimations, Forecasts and CAGR of any prominent country as per the clients interest (Note: Depends of feasibility check)
• Competitive Benchmarking
o Benchmarking of key players based on product portfolio, geographical presence, and strategic alliances

Table Of Contents: 

1 Executive Summary

2 Preface
2.1 Abstract
2.2 Stake Holders
2.3 Research Scope
2.4 Research Methodology
2.4.1 Data Mining
2.4.2 Data Analysis
2.4.3 Data Validation
2.4.4 Research Approach
2.5 Research Sources
2.5.1 Primary Research Sources
2.5.2 Secondary Research Sources
2.5.3 Assumptions

3 Â鶹ԭ´´ Trend Analysis
3.1 Introduction
3.2 Drivers
3.3 Restraints
3.4 Opportunities
3.5 Threats
3.6 Application Analysis
3.7 Emerging Â鶹ԭ´´s
3.8 Futuristic Â鶹ԭ´´ Scenario

4 Porters Five Force Analysis
4.1 Bargaining power of suppliers
4.2 Bargaining power of buyers
4.3 Threat of substitutes
4.4 Threat of new entrants
4.5 Competitive rivalry

5 Nanorobotics Â鶹ԭ´´ by Type
5.1 Introduction
5.2 Nanomanipulator
5.2.1 Scanning Probe Microscope (SPM)
5.2.1.1 Scanning Tunneling Microscope (STM)
5.2.1.2 Atomic Force Microscopes (AFM)
5.2.2 Electron Microscope (EM)
5.2.2.1 Transmission Electron Microscope (TEM)
5.2.2.2 Scanning Electron Microscope (SEM)
5.3 Magnetically Guided
5.4 Bacteria-Based
5.5 Bio-Nanorobotics

6 Nanorobotics Â鶹ԭ´´ by Application
6.1 Introduction
6.2 Biomedical
6.3 Nanomedicine
6.4 Mechanical
6.5 Other Applications

7 Global Nanorobotics Â鶹ԭ´´, By Geography
7.1 Introduction
7.2 North America
7.2.1 US
7.2.2 Canada
7.2.3 Mexico
7.3 Europe
7.3.1 Germany
7.3.2 UK
7.3.3 Italy
7.3.4 France
7.3.5 Spain
7.3.6 Rest of Europe
7.4 Asia Pacific
7.4.1 Japan
7.4.2 China
7.4.3 India
7.4.4 Australia
7.4.5 New Zealand
7.4.6 South Korea
7.4.7 Rest of Asia Pacific
7.5 South America
7.5.1 Argentina
7.5.2 Brazil
7.5.3 Chile
7.5.4 Rest of South America
7.6 Middle East & Africa
7.6.1 Saudi Arabia
7.6.2 UAE
7.6.3 Qatar
7.6.4 South Africa
7.6.5 Rest of Middle East & Africa

8 Key Developments
8.1 Agreements, Partnerships, Collaborations and Joint Ventures
8.2 Acquisitions & Mergers
8.3 New Product Launch
8.4 Expansions
8.5 Other Key Strategies

9 Company Profiling
9.1 Bruker
9.2 JEOL
9.3 Thermo Fisher Scientific
9.4 Ginkgo Bioworks
9.5 Oxford Instruments
9.6 EV Group
9.7 Imina Technologies
9.8 Toronto Nano Instrumentation
9.9 Klocke Nanotechnik
9.10 Kleindiek Nanotechnik
9.11 Xidex
9.12 Synthace
9.13 Park Systems
9.14 Smaract
9.15 Nanonics Imaging

List of Tables
Table 1 Global Nanorobotics Â鶹ԭ´´ Outlook, By Region (2016-2026) (US $MN)
Table 2 Global Nanorobotics Â鶹ԭ´´ Outlook, By Type (2016-2026) (US $MN)
Table 3 Global Nanorobotics Â鶹ԭ´´ Outlook, By Nanomanipulator (2016-2026) (US $MN)
Table 4 Global Nanorobotics Â鶹ԭ´´ Outlook, By Scanning Probe Microscope (SPM) (2016-2026) (US $MN)
Table 5 Global Nanorobotics Â鶹ԭ´´ Outlook, By Electron Microscope (EM) (2016-2026) (US $MN)
Table 6 Global Nanorobotics Â鶹ԭ´´ Outlook, By Magnetically Guided (2016-2026) (US $MN)
Table 7 Global Nanorobotics Â鶹ԭ´´ Outlook, By Bacteria-Based (2016-2026) (US $MN)
Table 8 Global Nanorobotics Â鶹ԭ´´ Outlook, By Bio-Nanorobotics (2016-2026) (US $MN)
Table 9 Global Nanorobotics Â鶹ԭ´´ Outlook, By Application (2016-2026) (US $MN)
Table 10 Global Nanorobotics Â鶹ԭ´´ Outlook, By Biomedical (2016-2026) (US $MN)
Table 11 Global Nanorobotics Â鶹ԭ´´ Outlook, By Nanomedicine (2016-2026) (US $MN)
Table 12 Global Nanorobotics Â鶹ԭ´´ Outlook, By Mechanical (2016-2026) (US $MN)
Table 13 Global Nanorobotics Â鶹ԭ´´ Outlook, By Other Applications (2016-2026) (US $MN)
Table 14 North America Nanorobotics Â鶹ԭ´´ Outlook, By Country (2016-2026) (US $MN)
Table 15 North America Nanorobotics Â鶹ԭ´´ Outlook, By Type (2016-2026) (US $MN)
Table 16 North America Nanorobotics Â鶹ԭ´´ Outlook, By Nanomanipulator (2016-2026) (US $MN)
Table 17 North America Nanorobotics Â鶹ԭ´´ Outlook, By Scanning Probe Microscope (SPM) (2016-2026) (US $MN)
Table 18 North America Nanorobotics Â鶹ԭ´´ Outlook, By Electron Microscope (EM) (2016-2026) (US $MN)
Table 19 North America Nanorobotics Â鶹ԭ´´ Outlook, By Magnetically Guided (2016-2026) (US $MN)
Table 20 North America Nanorobotics Â鶹ԭ´´ Outlook, By Bacteria-Based (2016-2026) (US $MN)
Table 21 North America Nanorobotics Â鶹ԭ´´ Outlook, By Bio-Nanorobotics (2016-2026) (US $MN)
Table 22 North America Nanorobotics Â鶹ԭ´´ Outlook, By Application (2016-2026) (US $MN)
Table 23 North America Nanorobotics Â鶹ԭ´´ Outlook, By Biomedical (2016-2026) (US $MN)
Table 24 North America Nanorobotics Â鶹ԭ´´ Outlook, By Nanomedicine (2016-2026) (US $MN)
Table 25 North America Nanorobotics Â鶹ԭ´´ Outlook, By Mechanical (2016-2026) (US $MN)
Table 26 North America Nanorobotics Â鶹ԭ´´ Outlook, By Other Applications (2016-2026) (US $MN)
Table 27 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Country (2016-2026) (US $MN)
Table 28 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Type (2016-2026) (US $MN)
Table 29 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Nanomanipulator (2016-2026) (US $MN)
Table 30 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Scanning Probe Microscope (SPM) (2016-2026) (US $MN)
Table 31 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Electron Microscope (EM) (2016-2026) (US $MN)
Table 32 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Magnetically Guided (2016-2026) (US $MN)
Table 33 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Bacteria-Based (2016-2026) (US $MN)
Table 34 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Bio-Nanorobotics (2016-2026) (US $MN)
Table 35 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Application (2016-2026) (US $MN)
Table 36 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Biomedical (2016-2026) (US $MN)
Table 37 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Nanomedicine (2016-2026) (US $MN)
Table 38 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Mechanical (2016-2026) (US $MN)
Table 39 Europe Nanorobotics Â鶹ԭ´´ Outlook, By Other Applications (2016-2026) (US $MN)
Table 40 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Country (2016-2026) (US $MN)
Table 41 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Type (2016-2026) (US $MN)
Table 42 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Nanomanipulator (2016-2026) (US $MN)
Table 43 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Scanning Probe Microscope (SPM) (2016-2026) (US $MN)
Table 44 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Electron Microscope (EM) (2016-2026) (US $MN)
Table 45 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Magnetically Guided (2016-2026) (US $MN)
Table 46 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Bacteria-Based (2016-2026) (US $MN)
Table 47 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Bio-Nanorobotics (2016-2026) (US $MN)
Table 48 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Application (2016-2026) (US $MN)
Table 49 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Biomedical (2016-2026) (US $MN)
Table 50 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Nanomedicine (2016-2026) (US $MN)
Table 51 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Mechanical (2016-2026) (US $MN)
Table 52 Asia Pacific Nanorobotics Â鶹ԭ´´ Outlook, By Other Applications (2016-2026) (US $MN)
Table 53 South America Nanorobotics Â鶹ԭ´´ Outlook, By Country (2016-2026) (US $MN)
Table 54 South America Nanorobotics Â鶹ԭ´´ Outlook, By Type (2016-2026) (US $MN)
Table 55 South America Nanorobotics Â鶹ԭ´´ Outlook, By Nanomanipulator (2016-2026) (US $MN)
Table 56 South America Nanorobotics Â鶹ԭ´´ Outlook, By Scanning Probe Microscope (SPM) (2016-2026) (US $MN)
Table 57 South America Nanorobotics Â鶹ԭ´´ Outlook, By Electron Microscope (EM) (2016-2026) (US $MN)
Table 58 South America Nanorobotics Â鶹ԭ´´ Outlook, By Magnetically Guided (2016-2026) (US $MN)
Table 59 South America Nanorobotics Â鶹ԭ´´ Outlook, By Bacteria-Based (2016-2026) (US $MN)
Table 60 South America Nanorobotics Â鶹ԭ´´ Outlook, By Bio-Nanorobotics (2016-2026) (US $MN)
Table 61 South America Nanorobotics Â鶹ԭ´´ Outlook, By Application (2016-2026) (US $MN)
Table 62 South America Nanorobotics Â鶹ԭ´´ Outlook, By Biomedical (2016-2026) (US $MN)
Table 63 South America Nanorobotics Â鶹ԭ´´ Outlook, By Nanomedicine (2016-2026) (US $MN)
Table 64 South America Nanorobotics Â鶹ԭ´´ Outlook, By Mechanical (2016-2026) (US $MN)
Table 65 South America Nanorobotics Â鶹ԭ´´ Outlook, By Other Applications (2016-2026) (US $MN)
Table 66 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Country (2016-2026) (US $MN)
Table 67 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Type (2016-2026) (US $MN)
Table 68 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Nanomanipulator (2016-2026) (US $MN)
Table 69 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Scanning Probe Microscope (SPM) (2016-2026) (US $MN)
Table 70 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Electron Microscope (EM) (2016-2026) (US $MN)
Table 71 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Magnetically Guided (2016-2026) (US $MN)
Table 72 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Bacteria-Based (2016-2026) (US $MN)
Table 73 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Bio-Nanorobotics (2016-2026) (US $MN)
Table 74 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Application (2016-2026) (US $MN)
Table 75 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Biomedical (2016-2026) (US $MN)
Table 76 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Nanomedicine (2016-2026) (US $MN)
Table 77 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Mechanical (2016-2026) (US $MN)
Table 78 Middle East & Africa Nanorobotics Â鶹ԭ´´ Outlook, By Other Applications (2016-2026) (US $MN)

Companies Mentioned: 

Bruker
JEOL
Thermo Fisher Scientific
Ginkgo Bioworks
Oxford Instruments
EV Group
Imina Technologies
Toronto Nano Instrumentation
Klocke Nanotechnik
Kleindiek Nanotechnik
Xidex
Synthace
Park Systems
Smaract
Nanonics Imaging

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