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Novel Spectrometry Platforms Market, 2022-2035: Distribution by Type of Spectrometers, Company Size, End User Industry, Key Geographical Regions: Industry Trends and Global Forecasts, 2022-2035

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    Report

  • 194 Pages
  • August 2022
  • Region: Global
  • Roots Analysis
  • ID: 5700723

Over time, spectroscopy has emerged as an important analytical tool for accurate and rapid analysis of compounds. It finds applications in research activities in food, biotechnology, pharmaceutical and environmental industry. Spectroscopic instruments provide information on electronic and optical properties, chemical composition and crystallinity of compounds. There are several types of spectrometers, such as mass spectrometer, atomic absorption spectrometer, nuclear magnetic resonance (NMR), Raman spectrometer, and X-Ray fluorescence (XRF), which can be used for various qualitative and quantitative analyses. Amongst various spectrometry platforms, mass spectrometry is the most popular technique owing to its high quantitative accuracy, which can be further combined with liquid chromatography (LC/MS) and gas chromatography (GC/MS) for better resolution. Having said that, there are several challenges associated with these conventional spectrometers, such as lack of automation, resulting in lesser reproducibility and sensitivity of the systems. Novel spectrometers, having demonstrated the potential to address a number of challenges associated with conventional spectrometers, have emerged as an appropriate solution. It is also worth highlighting that several advancements, such as miniaturization, portability to increase performance and throughput of the process, have been made in the instrumentation of novel spectrometers.

Around 30 companies are actively engaged in the manufacturing of novel spectrometry platforms that can be used for various analytical applications, quality control, structural biology, forensic investigations, material testing, and agriculture analysis. Further, various advanced technologies, such as new laser based system, have been introduced in the spectrometers to detect particular combination of compounds. Additionally, the field has witnessed several innovations in the data process, evolution in guidelines for processing of the instruments that are compliant with the regulatory standards, mainly based on data accuracy, speed of bioanalytical method and speed of the analysis. Moreover, in the last few years, stakeholders have undertaken several initiatives to augment their intellectual portfolio by filing 3000+ patents for latest technologies and products with advanced features. The growing popularity of novel spectrometry platforms is also evident from 60+ global events that have been organized in this field, since 2016. Given the rising interest of stakeholders towards technological advancements and growing adoption of novel spectrometers for various applications, we believe that the overall market for novel spectrometry platforms is anticipated to witness substantial growth in the coming years.

Scope of the Report

The ‘Novel Spectrometry Platforms Market, 2022-2035: Distribution by Type of Spectrometers (Atomic Absorption Spectrometer, Mass Spectrometer, Near Infrared Spectrometer, Nuclear Magnetic Resonance Spectrometer, Raman Spectrometer and X-Ray Fluorescence Spectrometer), Company Size (Small, Mid-Sized and Large), End User Industry (Agriculture / Pesticide Testing, Environmental Analysis, Food Biotechnology, Forensic Analysis, Pharmaceutical Analysis and other end users), Key Geographical Regions (North America, Europe, Asia-Pacific, Latin America and Middle East and North Africa (MENA)): Industry Trends and Global Forecasts, 2022-2035’ report features an extensive study on the current market landscape and future potential of novel spectrometers over the next decade. The study presents an in-depth analysis, highlighting the capabilities of various stakeholders engaged in this domain, across different geographies. In addition to other elements, the report includes:

  • A detailed assessment of the current market landscape of novel spectrometry platforms, featuring information on the type of spectrometer, software platform, type of technology used, type of detector, weight of spectrometer and type of end user industry. In addition, the chapter includes analysis of novel spectrometry manufacturers, along with information on their year of establishment, company size, location of headquarters and leading players (in terms of number of products being offered).
  • Elaborate profiles of the players offering novel spectrometry platforms (shortlisted on the basis of the year of experience of the company). Each profile features a brief overview of the company, financial information (if available), details on its product portfolio, and a section on recent developments and an informed future outlook.
  • An analysis of over 700 peer-reviewed scientific articles related to novel spectrometry, published since 2018, based on several parameters, such as year of publication, type of article, emerging focus areas, most popular journals, most popular publishers and most popular copyright holders.
  • A detailed analysis of global events attended by the participants, based on several relevant parameters, such as year of event, event platform, type of event, location of event, emerging focus areas, active organizers (in terms of number of events) and designation of participants. The chapter also highlights the geographical mapping of upcoming events.
  • An insightful analysis of the patents filed / granted for novel spectrometry platforms, since 2018, taking into consideration various relevant parameters, such as type of patent, publication year, geographical location, CPC symbols, emerging focus areas, type of organization, leading players (in terms of number of patents granted / filed in the given time period) and patent characteristics. In addition, the chapter includes a detailed patent benchmarking and an insightful valuation analysis.
  • An analysis of various developments / recent trends related to novel spectrometry, offering insights on partnerships and collaborations and recent initiatives being undertaken related to novel spectrometry platforms.
  • A discussion on affiliated trends, key drivers and challenges, under a SWOT framework, featuring a Harvey ball analysis, highlighting the relative impact of each SWOT parameter on the overall novel spectrometry platforms market.

One of the key objectives of the report was to estimate the existing market size and the future opportunity for novel spectrometry platforms, over the coming 13 years. We have provided informed estimates on the likely evolution of the market in the short to mid-term and long term, for the period 2022-2035. Our year-wise projections of the current and future opportunity have further been segmented based on relevant parameters, such as type of spectrometers (atomic absorption spectrometer, mass spectrometer, near infrared spectrometer, nuclear magnetic resonance spectrometer, Raman spectrometer and X-ray fluorescence spectrometer), company size (small, mid-sized and large), end-user industry (agriculture / pesticide testing, environmental analysis, food biotechnology, forensic analysis, pharmaceutical analysis and other end users), and key geographical regions (North America, Europe, Asia-Pacific, Latin America and MENA). In order to account for future uncertainties and to add robustness to our model, we have provided three market forecast scenarios, namely conservative, base and optimistic scenarios, representing different tracks of the anticipated industry’s growth.

The opinions and insights presented in the report were also influenced by discussions held with senior stakeholders in the industry.

The report features detailed transcripts of interviews held with the following individuals:

  • Nick Jones (Global Application and Development Director, LECO)
  • Nicole Zhang (Product Manager, Shimadzu)
  • Chris Henry (Senior Scientist, Waters)

All actual figures have been sourced and analyzed from publicly available information forums and primary research discussions. Financial figures mentioned in this report are in USD, unless otherwise specified.

Key Questions Answered

  • Who are the key players engaged in the development of novel spectrometry platforms?
  • How has the intellectual property landscape in the novel spectrometry platforms evolved over the years?
  • What are the key agenda items being discussed in various global events / conferences held novel spectrometry platforms?
  • What is the focus area of the ongoing research activities related to novel spectrometry platforms?
  • Which partnership models are most commonly adopted by stakeholders engaged in this industry?
  • How is the current and future market opportunity, likely to be distributed across key market segments? 

Please note: This report can be updated on request. Please contact our Customer Experience team using the Ask a Question widget on our website.

Table of Contents

1. PREFACE
1.1. Scope of the Report
1.2. Market Segmentation
1.3. Research Methodology
1.4. Key Questions Answered
1.5. Chapter Outlines

2. EXECUTIVE SUMMARY
3. INTRODUCTION
3.1. Chapter Overview
3.2. Overview of Spectrometry
3.3 Types of Spectrometry
3.4. Principle of Spectrometers
3.5. Specifications of Spectrometers
3.6. Types of Spectrometers
3.7. Comparison of Conventional and Novel Mass Spectrometers
3.8. Applications of Novel Spectrometry Platforms
3.9. Applications of Conventional Spectrometry Platforms
3.10. Future Prospects in Spectrometry

4. NOVEL SPECTROMETRY PLATFORMS: MARKET LANDSCAPE
4.1. Chapter Overview
4.2. Novel Spectrometry Platforms: Overall Market Landscape
4.2.1. Analysis by Type of Spectrometer
4.2.2. Analysis by Software Platform
4.2.3. Analysis by Type of Technology Used
4.2.4. Analysis by Type of Detector
4.2.5. Analysis by Weight of Spectrometer
4.2.6. Analysis by Type of End User Industry
4.3. Novel Spectrometry Platforms: Developer Landscape
4.3.1. Analysis by Year of Establishment
4.3.2. Analysis by Company Size
4.3.3. Analysis by Location of Headquarters
4.3.4. Analysis by Location of Headquarters and Company Size
4.3.5. Leading Players: Analysis by Number of Novel Spectrometry Platforms Manufactured

5. COMPANY PROFILES: NOVEL SPECTROMETRY PLATFORMS
5.1. Chapter Overview
5.2. Bruker
5.2.1. Company Overview
5.2.2. Financial Information
5.2.3. Product Portfolio
5.2.3.1. Recent Developments and Future Outlook
5.3. JEOL
5.3.1. Company Overview
5.3.2. Financial Information
5.3.3. Product Portfolio
5.3.4. Recent Developments and Future Outlook
5.4. Metrohm
5.4.1. Company Overview
5.4.2. Product Portfolio
5.4.3. Recent Developments and Future Outlook
5.4.4. PerkinElmer
5.4.5. Company Overview
5.4.6. Financial Information
5.4.7. Product Portfolio
5.4.8. Recent Developments and Future Outlook
5.5. Shimadzu
5.5.1. Company Overview
5.5.2. Financial Information
5.5.3. Product Portfolio
5.5.4. Recent Developments and Future Outlook
5.6. Thermo Fisher Scientific
5.6.1. Company Overview
5.6.2. Financial Information
5.6.3. Product Portfolio
5.6.4. Recent Developments and Future Outlook
5.7. Waters
5.7.1. Company Overview
5.7.2. Financial Information
5.7.3. Product Portfolio
5.7.4. Recent Developments and Future Outlook

6. PUBLICATION ANALYSIS
6.1. Chapter Overview
6.2. Scope and Methodology
6.2.1. Analysis by Year of Publication
6.2.2. Analysis by Type of Article
6.2.3. Most Popular Journals: Analysis by Number of Publications
6.2.4. Most Active Publishers: Analysis by Number of Publications
6.2.5. Most Popular Copyright Holders: Analysis by Number of Publications
6.2.6. Most Popular Journals: Analysis by Impact Factor
6.2.7. Analysis by Geography

7. GLOBAL EVENT ANALYSIS
7.1. Chapter Overview
7.2. Scope and Methodology
7.3. Global Events related to Novel Spectrometry
7.3.1. Analysis by Year of Event
7.3.2. Analysis by Event Platform
7.3.3. Analysis by Type of Event
7.3.4. Analysis by Location of Event
7.3.5. Word Cloud: Evolutionary Trends in Event Agenda / Key Focus Area
7.3.6. Most Active Event Organizers: Analysis by Number of Events
7.3.7. Analysis by Designation of Participants
7.3.8. Geographical Mapping of Upcoming Events

8. PATENT ANALYSIS
8.1. Chapter Overview
8.2. Scope and Methodology
8.2.1. Analysis by Type of Patent
8.2.2. Analysis by Patent Publication Year
8.2.3. Analysis by Annual Number of Granted Patents and Patent Applications
8.2.4. Analysis by Geographical Location
8.2.5. Analysis by CPC Symbols
8.2.6. Word Cloud: Emerging Focus Areas
8.2.7. Analysis by Type of Organization
8.2.8. Leading Industry Players: Analysis by Number of Patents
8.2.9. Leading Non-Industry Players: Analysis by Number of Patents
8.3. Patent Benchmarking Analysis
8.3.1. Analysis by Patent Characteristics
8.4. Patent Valuation Analysis
8.5. Leading Patents Based on Number of Citations

9. RECENT DEVELOPMENTS
9.1. Chapter Overview
9.2. Novel Spectrometry Platforms: Partnership Activity
9.2.1. Partnership Models
9.2.2. List of Partnerships and Collaborations
9.2.2.1. Analysis by Year of Partnership
9.2.2.2. Analysis by Type of Partnership
9.2.2.3. Analysis by Type of Spectrometer
9.2.2.4. Most Active Players: Analysis by Number of Partnership
9.2.2.5. Word Cloud Analysis: Emerging Focus Areas
9.2.2.6. Regional Analysis
9.2.2.7. Intercontinental and Intracontinental Agreements
9.3. Novel Spectrometry Platforms: Recent Initiatives
9.3.1. List of Initiatives
9.3.1.1 Analysis by Year of Initiatives
9.3.1.2. Analysis by Type of Initiatives
9.3.1.3. Analysis by Type of Spectrometers
9.3.1.4. Most Active Players: Analysis by Number of Initiatives
9.3.1.5. Analysis by Geography and Type of Initiative
9.3.1.6. Word Cloud Analysis: Emerging Focus Areas

10. SWOT ANALYSIS
10.1. Chapter Overview
10.2. Novel Spectrometry Platforms: SWOT Analysis
10.2.1. Comparison of SWOT Factors

11. MARKET FORECAST
11.1. Chapter Overview
11.2. Key Assumptions and Methodology
11.3. Global Demand for Novel Spectrometry Platforms, 2022-2035
11.4. Global Novel Spectrometry Platforms Market, 2022-2035
11.5. Novel Spectrometry Platforms Market, 2022-2035: Conservative, Base and Optimistic Scenario, 2022 and 2035
11.5.1. Novel Spectrometry Platforms Market, 2022-2035: Distribution by Type of Spectrometers, 2022 and 2035
11.5.1.1. Novel Spectrometry Platforms Market for Atomic Absorption Spectrometers, 2022-2035
11.5.1.2. Novel Spectrometry Platforms Market for Mass Spectrometers, 2022-2035
11.5.1.3. Novel Spectrometry Platforms Market for Near Infrared Spectrometers, 2022-2035
11.5.1.4. Novel Spectrometry Platforms Market for Nuclear Magnetic Resonance Spectrometers, 2022-2035
11.5.1.5. Novel Spectrometry Platforms Market for Raman Spectrometers, 2022-2035
11.5.1.6. Novel Spectrometry Platforms Market for X-Ray Fluorescence Spectrometers, 2022-2035
11.5.2. Novel Spectrometry Platforms Market, 2022-2035: Distribution by Company Size, 2022 and 2035
11.5.2.1. Novel Spectrometry Platforms Market for Small Companies, 2022-2035
11.5.3.1. Novel Spectrometry Platforms Market for Mid-Sized Companies, 2022-2035
11.5.3.1. Novel Spectrometry Platforms Market for Large Companies, 2022-2035
11.5.3. Novel Spectrometry Platforms Market, 2022-2035: Distribution by End User Industry, 2022 and 2035
11.5.3.1. Novel Spectrometry Platforms Market for Agriculture / Pesticide Testing, 2022-2035
11.5.3.2. Novel Spectrometry Platforms Market for Environmental Analysis, 2022-2035
11.5.3.3. Novel Spectrometry Platforms Market for Food Biotechnology, 2022-2035
11.5.3.4. Novel Spectrometry Platforms Market for Forensic Analysis, 2022-2035
11.5.3.5. Novel Spectrometry Platforms Market for Pharmaceutical Analysis, 2022-2035
11.5.3.6. Novel Spectrometry Platforms Market for Other End Users, 2022-2035
11.5.4. Novel Spectrometry Platforms Market, 2022-2035: Distribution by Key Geographical Regions, 2022 and 2035
11.5.4.1. Novel Spectrometry Platforms Market in North America, 2022-2035
11.5.4.2. Novel Spectrometry Platforms Market in Europe, 2022-2035
11.5.4.3. Novel Spectrometry Platforms Market in Asia-Pacific, 2022-2035
11.5.4.4. Novel Spectrometry Platforms Market in Latin America, 2022-2035
11.5.4.5. Novel Spectrometry Platforms Market in MENA, 2022-2035

12. CONCLUDING REMARKS
13. EXECUTIVE INSIGHTS
13.1. Chapter Overview
13.2. LECO
13.2.1. Company Snapshot
13.2.2. Interview Transcript: Nick Jones, Global Application and Development Director
13.3 Shimadzu
13.3.1. Company Snapshot
13.3.2. Interview Transcript: Nicole Zhang, Product Manager
13.4. Waters
13.4.1. Company Snapshot
13.4.2. Interview Transcript: Chris Henry, Senior Scientist

14. APPENDIX 1: TABULATED DATA15. APPENDIX 2: LIST OF COMPANIES AND ORGANIZATIONS
List Of Figures
Figure 2.1 Executive Summary: Overall Market Landscape of Novel Spectrometry Platforms
Figure 2.2 Executive Summary: Publication Analysis
Figure 2.3 Executive Summary: Global Event Analysis
Figure 2.4 Executive Summary: Patent Analysis
Figure 2.5 Executive Summary: Recent Developments
Figure 2.6 Executive Summary: Market Forecast and Opportunity Analysis
Figure 3.1 Principle of Spectrometers
Figure 3.2 Types of Spectrometers
Figure 4.1 Novel Spectrometry Platforms: Distribution by Type of Spectrometer
Figure 4.2 Novel Spectrometry Platforms: Distribution by Software Platform
Figure 4.3 Novel Spectrometry Platforms: Distribution by Type of Technology Used
Figure 4.4 Novel Spectrometry Platforms: Distribution by Type of Detector
Figure 4.5 Novel Spectrometry Platforms: Distribution by Weight of Spectrometer
Figure 4.6 Novel Spectrometry Platforms: Distribution by Type of End User Industry
Figure 4.7 Novel Spectrometry Platforms: Distribution by Year of Establishment
Figure 4.8 Novel Spectrometry Platforms: Distribution by Company Size
Figure 4.9 Novel Spectrometry Platforms: Distribution by Location of Headquarters
Figure 4.10 Novel Spectrometry Platforms: Distribution by Location of Headquarters and Company Size
Figure 4.11 Leading Players: Distribution by Number of Novel Spectrometry Platforms Manufactured
Figure 5.1 Bruker: Annual Revenues, FY 2017-Q1 2022 (USD Billion)
Figure 5.2 JEOL: Annual Revenues, FY 2017-Q1 2022 (USD Billion)
Figure 5.3 PerkinElmer: Annual Revenues, FY 2017-Q1 2022 (USD Billion)
Figure 5.4 Shimadzu: Annual Revenues, FY 2017-9M 2022 (JPY Billion)
Figure 5.5 ThermoFisher Scientific: FY 2017-Q1 2022 (USD Billion)
Figure 5.6 Waters: FY 2017-Q1 2022 (USD Billion)
Figure 6.1 Publication Analysis: Cumulative Year-wise Trend, 2016-2022 (till May)
Figure 6.2 Publication Analysis: Distribution by Type of Article
Figure 6.3 Most Popular Journals: Distribution by Number of Publications
Figure 6.4 Most Active Publishers: Distribution by Number of Publications
Figure 6.5 Most Popular Copyright Holders: Distribution by Number of Publications
Figure 6.6 Most Popular Journals: Distribution by Impact Factor
Figure 6.7 Publication Analysis: Distribution by Geography
Figure 7.1 Global Events: Cumulative Year-Wise Trend, 2016-H1 2022
Figure 7.2 Global Events: Distribution by Event Platform
Figure 7.3 Global Events: Distribution by Type of Event
Figure 7.4 Global Events: Distribution by Location of Event
Figure 7.5 Word Cloud: Evolutionary Trends in Event Agenda / Key Focus Area
Figure 7.6 Global Events: Historical Trend of Event Agendas, 2016-H1 2022
Figure 7.7 Most Active Event Organizers: Distribution by Number of Events
Figure 7.8 Global Events: Distribution by Seniority Level of Event Speakers
Figure 7.9 Global Events: Distribution by Affiliated Department of Event Speakers
Figure 7.10 Global Events: Geographical Mapping of Upcoming Events
Figure 8.1 Patent Analysis: Distribution by Type of Patent
Figure 8.2 Patent Analysis: Cumulative Distribution by Publication Year, 2018-2022 (till June)
Figure 8.3 Patent Analysis: Cumulative Distribution by Annual Number of Granted Patents and Patent Applications, 2016-2022 (till June)
Figure 8.4 Patent Analysis: Distribution by Geographical Location
Figure 8.5 Patent Analysis: Distribution by CPC Symbols
Figure 8.6 Word Cloud: Emerging Focus Areas
Figure 8.7 Patent Analysis: Cumulative Year-wise Distribution by Type of Organization, 2016-2022 (till June)
Figure 8.8 Leading Industry Players: Distribution by Number of Patents
Figure 8.9 Leading Non-Industry Players: Distribution by Number of Patents
Figure 8.10 Leading Individual Assignees: Distribution by Number of Patents
Figure 8.11 Leading Players: Benchmarking by Patent Characteristics (CPC Symbols)
Figure 8.12 Patent Analysis: Year-wise Distribution of Patents by Age, 2006-2021
Figure 8.13 Novel Spectrometry Platforms: Patent Valuation Analysis
Figure 9.1 Partnerships and Collaborations: Cumulative Year-wise Trend, Pre-2018-2022 (till June)
Figure 9.2 Partnerships and Collaborations: Distribution by Type of Partnership
Figure 9.3 Partnerships and Collaborations: Distribution by Year and Type of Partnership, Pre-2018-2022 (June)
Figure 9.4 Partnerships and Collaborations: Distribution by Type of Spectrometer
Figure 9.4 Most Active Players: Distribution by Number of Partnerships
Figure 9.6 Word Cloud: Emerging Focus Areas
Figure 9.7 Partnerships and Collaborations: Regional Distribution
Figure 9.8 Partnerships and Collaborations: Intercontinental and Intracontinental Agreements
Figure 9.9 Recent Initiatives: Analysis by Year of Initiatives
Figure 9.10 Recent Initiatives: Analysis by Type of Initiatives
Figure 9.11 Recent Initiatives: Analysis by Type of Spectrometers
Figure 9.12 Most Active Players: Distribution by Number of Initiatives
Figure 9.13 New Initiatives: Distribution by Geography and Type of Initiative
Figure 9.14 Word Cloud: Emerging Focus Areas
Figure 10.1 Novel Spectrometry: SWOT Analysis
Figure 10.2 SWOT Factors: Harvey Ball Analysis
Figure 11.1 Global Demand for Novel Spectrometry Platforms, 2022-2035 (USD Million)
Figure 11.2 Global Novel Spectrometry Platforms Market, 2022-2035 (USD Million)
Figure 11.3 Novel Spectrometry Platforms Market: Distribution by Type of Spectrometer, 2022 and 2035
Figure 11.4 Novel Spectrometry Platforms Market for Atomic Absorption Spectrometers, 2022-2035 (USD Million)
Figure 11.5 Novel Spectrometry Platforms Market for Mass Spectrometers, 2022-2035 (USD Million)
Figure 11.6 Novel Spectrometry Platforms Market for Near Infrared Spectrometers, 2022-2035 (USD Million)
Figure 11.7 Novel Spectrometry Platforms Market for Nuclear Magnetic Resonance Spectrometers, 2022-2035 (USD Million)
Figure 11.8 Novel Spectrometry Platforms Market for Raman Spectrometers, 2022-2035 (USD Million)
Figure 11.9 Novel Spectrometry Platforms Market for X-Ray Fluorescence Spectrometers, 2022-2035 (USD Million)
Figure 11.10 Novel Spectrometry Platforms Market: Distribution by Company Size, 2022 and 2035
Figure 11.11 Novel Spectrometry Platforms Market for Small Companies, 2022-2035 (USD Million)
Figure 11.12 Novel Spectrometry Platforms Market for Mid-Sized Companies, 2022-2035 (USD Million)
Figure 11.13 Novel Spectrometry Platforms Market for Large Companies, 2022-2035 (USD Million)
Figure 11.14 Novel Spectrometry Platforms Market: Distribution by End User Industry, 2022 and 2035
Figure 11.15 Novel Spectrometry Platforms Market for Agriculture / Pesticide Testing, 2022-2035 (USD Million)
Figure 11.16 Novel Spectrometry Platforms Market for Environmental Analysis, 2022-2035 (USD Million)
Figure 11.17 Novel Spectrometry Platforms Market for Food Biotechnology, 2022-2035 (USD Million)
Figure 11.18 Novel Spectrometry Platforms Market for Forensic Analysis, 2022-2035 (USD Million)
Figure 11.19 Novel Spectrometry Platforms Market for Pharmaceutical Analysis, 2022-2035 (USD Million)
Figure 11.20 Novel Spectrometry Platforms Market for Other End Users, 2022-2035 (USD Million)
Figure 11.21 Novel Spectrometry Platforms Market: Distribution by Key Geographical Regions, 2022 and 2035
Figure 11.22 Novel Spectrometry Platforms Market in North America, 2022-2035 (USD Million)
Figure 11.23 Novel Spectrometry Platforms Market in Europe, 2022-2035 (USD Million)
Figure 11.24 Novel Spectrometry Platforms Market in Asia-Pacific, 2022-2035 (USD Million)
Figure 11.25 Novel Spectrometry Platforms Market in Latin America, 2022-2035 (USD Million)
Figure 11.26 Novel Spectrometry Platforms Market in MENA, 2022-2035 (USD Million)
Figure 12.1 Concluding Remarks: Market Landscape of Novel Spectrometry Platforms
Figure 12.2 Concluding Remarks: Publication Analysis
Figure 12.3 Concluding Remarks: Global Event Analysis
Figure 12.4 Concluding Remarks: Patent Analysis
Figure 12.5 Concluding Remarks: Recent Developments
Figure 12.6 Concluding Remarks: Market Forecast and Opportunity Analysis

List Of Tables
Table 3.1 Comparison of Conventional and Novel Mass Spectrometry
Table 3.2 Summary of Spectrometry
Table 4.1 Novel Spectrometry Platforms: Information on Type of Spectrometer, Type of Technology Used and Software Platform
Table 4.2 Novel Spectrometry Platforms: Information on Type of Detector, Scan Rates, Weight, and Dimensions of Spectrometers
Table 4.3 List of Novel Spectrometry Platforms Developers
Table 5.1 Novel Spectrometry Platforms: List of Companies Profiled
Table 5.2 Bruker: Company Snapshot
Table 5.3 Bruker: Recent Developments and Future Outlook
Table 5.4 JEOL: Company Snapshot
Table 5.5 JEOL: Recent Developments and Future Outlook
Table 5.6 Metrohm: Company Snapshot
Table 5.7 Metrohm: Recent Developments and Future Outlook
Table 5.8 PerkinElmer: Company Snapshot
Table 5.9 PerkinElmer: Recent Developments and Future Outlook
Table 5.10 Shimadzu: Company Snapshot
Table 5.11 Shimadzu: Recent Developments and Future Outlook
Table 5.12 Thermo Fisher Scientific: Company Snapshot
Table 5.13 Thermo Fisher Scientific: Recent Developments and Future Outlook
Table 5.14 Waters: Company Snapshot
Table 5.15 Waters: Recent Developments and Future Outlook
Table 7.1 List of Global Events related to Novel Spectrometry
Table 8.1 Patent Analysis: Prominent CPC Symbols
Table 8.2 Patent Analysis: List of Top CPC Symbols
Table 8.3 Patent Analysis: Most Popular CPC Symbols
Table 8.4 Patent Analysis: Summary of Benchmarking Analysis
Table 8.5 Patent Analysis: Categorization based on Weighted Valuation Scores
Table 8.6 Patent Portfolio: List of Leading Patents (by Highest Relative Valuation)
Table 8.7 Patent Portfolio: List of Leading Patents (by Number of Citations)
Table 9.1 List of Partnerships and Collaborations, Pre-2018-2022 (till June)
Table 9.2 List of Recent Initiatives related to Novel Spectrometry Platforms
Table 14.1 Novel Spectrometry Platforms: Distribution by Type of Spectrometer
Table 14.2 Novel Spectrometry Platforms: Distribution by Software Platform
Table 14.3 Novel Spectrometry Platforms: Distribution by Technology Used
Table 14.4 Novel Spectrometry Platforms: Distribution by Type of Detector
Table 14.5 Novel Spectrometry Platforms: Distribution by Weight of Spectrometer
Table 14.6 Novel Spectrometry Platforms: Distribution by Type of End User Industry
Table 14.7 Novel Spectrometry Platforms: Distribution by Year of Establishment
Table 14.8 Novel Spectrometry Platforms: Distribution by Company Size
Table 14.9 Novel Spectrometry Platforms: Distribution by Region of Headquarters
Table 14.10 Novel Spectrometry Platforms: Distribution by Location of Headquarters and Company Size
Table 14.11 Novel Spectrometry Platforms: Distribution by Location of Headquarters
Table 14.12 Leading Players: Distribution by Number of Novel Spectrometry Platforms Manufactured
Table 14.13 Bruker: Annual Revenues, FY 2017-Q1 2022 (USD Billion)
Table 14.14 JEOL: Annual Revenues, FY 2017-Q1 2022 (USD Billion)
Table 14.15 PerkinElmer: Annual Revenues, FY 2017-Q1 2022 (USD Billion)
Table 14.16 Shimadzu: Annual Revenues, FY 2017-9M 2022 (JPY Billion)
Table 14.17 ThermoFisher Scientific: FY 2017-Q1 2022 (USD Billion)
Table 14.18 Waters: FY 2017-Q1 2022 (USD Billion)
Table 14.19 Publication Analysis: Cumulative Year-wise Trend, 2016-2022 (till May)
Table 14.20 Publication Analysis: Distribution by Type of Article
Table 14.21 Most Popular Journals: Distribution by Number of Publications
Table 14.22 Most Popular Publishers: Distribution by Number of Publications
Table 14.23 Most Popular Copyright Holders: Distribution by Number of Publications
Table 14.24 Global Events: Cumulative Year-Wise Trend, 2016-H1 2022
Table 14.25 Global Events: Distribution by Event Platform
Table 14.26 Global Events: Distribution by Type of Event
Table 14.27 Global Events: Distribution by Location of Event
Table 14.28 Most Active Event Organizers: Distribution by Number of Events
Table 14.29 Global Events: Distribution by Seniority Level of Event Speakers
Table 14.30 Global Events: Distribution by Affiliated Department of Event Speakers
Table 14.31 Patent Analysis: Distribution by Type of Patent
Table 14.32 Patent Analysis: Cumulative Distribution by Publication Year, 2018-2022 (till June)
Table 14.33 Patent Analysis: Distribution by Annual Number of Granted Patents and Patent Applications, 2016-2022 (till June)
Table 14.34 Patent Analysis: Distribution by Geographical Location
Table 14.35 Patent Analysis: Distribution by CPC Symbols
Table 14.36 Patent Analysis: Cumulative Year-wise Distribution by Type of Organization, 2016-2022 (till June)
Table 14.37 Leading Industry Players: Distribution by Number of Patents
Table 14.38 Leading Non-Industry Players: Distribution by Number of Patents
Table 14.39 Leading Individual Assignees: Distribution by Number of Patents
Table 14.40 Leading Players: Benchmarking by Patent Characteristics (CPC Symbols)
Table 14.41 Patent Analysis: Year-wise Distribution of Patents by Age, 2006-2021
Table 14.42 Novel Spectrometry Platforms: Patent Valuation Analysis
Table 14.43 Partnerships and Collaborations: Cumulative Year-wise Trend, Pre-2018-2022 (till June)
Table 14.44 Partnerships and Collaborations: Distribution by Type of Partnership
Table 14.45 Partnerships and Collaborations: Distribution by Year and Type of Partnership, Pre-2018-2022 (till June)
Table 14.46 Partnerships and Collaborations: Distribution by Type of Spectrometers
Table 14.47 Most Active Players: Distribution by Number of Partnerships
Table 14.48 Partnerships and Collaborations: Regional Distribution
Table 14.49 Partnerships and Collaborations: Intercontinental and Intracontinental Agreements
Table 14.50 Recent Initiatives: Analysis by Year of Initiatives
Table 14.51 Recent Initiatives: Analysis by Initiatives
Table 14.52 Recent Initiatives: Analysis by Type of Spectrometers
Table 14.53 Most Active Players: Distribution by Number of Initiatives
Table 14.54 Recent Initiatives: Distribution by Geography and Type of Initiative
Table 14.55 Global Demand for Novel Spectrometry Platforms, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.56 Global Novel Spectrometry Platforms Market, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.57 Novel Spectrometry Platforms Market, 2022-2035: Distribution by Type of Spectrometer, 2022 and 2035
Table 14.58 Novel Spectrometry Platforms Market for Atomic Absorption Spectrometers, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.59 Novel Spectrometry Platforms Market for Mass Spectrometers, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.60 Novel Spectrometry Platforms Market for Near Infrared Spectrometers, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.61 Novel Spectrometry Platforms Market for Nuclear Magnetic Resonance Spectrometers, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.62 Novel Spectrometry Platforms Market for, Raman Spectrometers, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.63 Novel Spectrometry Platforms Market for X-Ray Fluorescence Spectrometers, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.64 Novel Spectrometry Platforms Market, 2022-2035: Distribution by Company Size, 2022 and 2035
Table 14.65 Novel Spectrometry Platforms Market for Small Companies, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.66 Novel Spectrometry Platforms Market for Mid-Sized Companies, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.67 Novel Spectrometry Platforms Market for Large Companies, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.68 Novel Spectrometry Platforms Market, 2022-2035: Distribution by End User Industry, 2022 and 2035
Table 14.69 Novel Spectrometry Platforms Market for Agriculture / Pesticide Testing, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.70 Novel Spectrometry Platforms Market for Environmental Analysis, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.71 Novel Spectrometry Platforms Market for Food Biotechnology, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.72 Novel Spectrometry Platforms Market for Forensic Analysis, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.73 Novel Spectrometry Platforms Market for Pharmaceutical Analysis, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.74 Novel Spectrometry Platforms Market for Other End Users, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.75 Novel Spectrometry Platforms Market, 2022-2035: Distribution by Key Geographical Regions, 2022 and 2035
Table 14.76 Novel Spectrometry Platforms Market in North America, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.77 Novel Spectrometry Platforms Market in Europe, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.78 Novel Spectrometry Platforms Market in Asia-Pacific, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.79 Novel Spectrometry Platforms Market in Latin America, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)
Table 14.80 Novel Spectrometry Platforms Market in MENA, 2022-2035: Conservative, Base and Optimistic Scenarios (USD Million)

Companies Mentioned (Partial List)

A selection of companies mentioned in this report includes, but is not limited to:

  • Admesy
  • Advion Interchim Scientific
  • Agilent Technologies 
  • American Society for Biochemistry and Molecular Biology (ASBMB)
  • American Society for Mass Spectrometry (ASMS)
  • Avacta
  • Avantes
  • Bio-Rad 
  • Brigham Young University (BYU)
  • Bruker 
  • Charles River Laboratories
  • Coalesce Research Group
  • Cobalt Light Systems (Acquired by Agilent Technologies) 
  • Cork Chamber 
  • Dalian Institute of Chemical Physics (DICP)
  • Diagnostic anSERS
  • Earle A. Chiles Research Institute
  • Edinburgh Instruments
  • Emerald Scientific
  • Endress+Hauser
  • European Reference Network for Critical Infrastructure Protection (ERNCIP)
  • Evoke MicroMass
  • Excellims 
  • Extrel (Acquired by Process Insights)
  • Flash Photonics 
  • French Society of Mass Spectrometry (SFSM) 
  • Genedata
  • George Mason University 
  • German Society for Mass Spectrometry (DGMS)
  • HORIBA
  • Innovative Photonic Solutions (IPS)
  • Instrument Systems 
  • Intabio (Acquired by Sciex)
  • International Mass Spectrometry Foundation (IMSF)
  • International Scientific Advisory Committee (ISAC)
  • International Society for Ion Mobility Spectrometry (ISIMS)
  • IonSense (Acquired by Bruker)
  • IONTOF USA
  • Iowa State University
  • JEOL
  • Karlsruhe Institute of Technology (KIT)
  • Kore Technology
  • Kratos Analytical
  • Kyungpook National University (KNU)
  • Labroots
  • League of advanced European Neutron Sources (LENS)
  • LECO
  • Mass Spectrometry Core (Maintained by Office of Research and Innovation)
  • Massachusetts Institute of Technology (MIT)
  • Megadalton Solutions 
  • Mestrelab 
  • Metrohm 
  • Newomics
  • Nexus Conferences 
  • NJ Biopharmaceuticals 
  • Ocean Insight
  • PerkinElmer 
  • Photonics Spectra
  • Protein Metrics 
  • Providence Cancer Institute 
  • Purdue Research Foundation (PRF)
  • Quest Diagnostics
  • RESANET
  • Royal Society of Chemistry (RSC)
  • Scienta Omicron
  • SCIEX
  • Semiconductor Energy Laboratory (SEL)
  • SepSolve Analytical 
  • SGS AXYS
  • Shanghai Spectrum Instruments (SSI) (Acquired by PerkinElmer)
  • Shimadzu 
  • Skyray Instrument
  • SPECTRAL Industries 
  • Stanford University
  • TALS 
  • Teledyne FLIR
  • Teledyne Princeton Instruments
  • Thermo Finnigan
  • Thermo Fisher Scientific 
  • University of California
  • University of North Carolina
  • University of Queensland
  • University of Tartu 
  • University of Texas
  • Utrecht University
  • Waters
  • Wiley Analytical Science

Methodology

 

 

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