Global Atomic Force Microscopy Market Size, Share, Trends, Industry Growth by Type (Research Grade, Industrial Grade), by Application (Life Sciences and Biology, Semiconductors and Electronics, Nanomaterial science, Others), by Region, and Forecast to 2030

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The global atomic force microscopy market size was valued at around USD 510 million in 2022 and anticipated to register a significant CAGR of over 5% during the forecast period from 2023 to 2030. The adoption of Atomic Force Microscopy (AFM) is fueled by diverse factors. AFM’s role in nanotechnology research, revealing nanoscale intricacies, drives its growth. Material analysis across industries benefits from AFM’s high-resolution imaging. In life sciences, AFM enables biomolecule and cell exploration. The semiconductor sector relies on AFM for precise analysis. Emerging economies investing in research boost AFM’s demand. AFM fuels materials innovation and aids academia. Research investments, technological advancements, and its use in healthcare contribute to its expansion. AFM’s adaptable nature supports quality control and environmental monitoring, shaping its significance in multidisciplinary applications.

Market Snapshot:

Benchmark Year 2022
Market Size ~ USD 510 Million in 2022
Market Growth (CAGR) > 5% (2023-2030)
Largest Market Share North America
Analysis Period 2020-2030
Market Players Bruker Corporation, Keysight Technologies, Inc., Oxford Instruments plc, Park Systems Corp., Nanosurf AG, and NT-MDT Spectrum Instruments

Market Drivers:

  • Advancements in Nanotechnology: AFM serves as a cornerstone in nanotechnology research, enabling scientists and researchers to delve into the intricate world of nanoscale materials, structures, and interactions. The continuous evolution of nanotechnology fuels a persistent demand for advanced imaging and manipulation tools, propelling AFM’s significance.
  • Critical Material Characterization: In fields like materials science, AFM offers a window into the micro and nanoscale characteristics of diverse materials. The ability to visualize surface features, defects, and properties contributes significantly to optimizing material design and performance.
  • Exploring Life at the Nanoscale: The life sciences benefit immensely from AFM’s capabilities, allowing researchers to peer into the nanoscale intricacies of biological structures. The study of biomolecules, cells, DNA, and proteins opens doors to breakthroughs in medicine, pharmaceuticals, and biotechnology.
  • Semiconductor Precision: The semiconductor industry, with its ever-shrinking components, relies heavily on AFM for characterizing nanoelectronics and thin films. Ensuring quality control and optimizing semiconductor devices are critical drivers for AFM adoption.
  • Growing Markets: Emerging economies, recognizing the potential of nanotechnology in driving innovation, are investing in advanced research instrumentation. This dynamic boosts the AFM market as a fundamental tool for expanding research capabilities.
  • Enabling Materials Innovation: Industries centered around materials, such as polymers and coatings, harness AFM to unravel surface properties and develop novel materials with enhanced features. AFM’s ability to unveil nanoscale details fuels innovation in materials science.
  • Catalyzing Research and Academia: Academic institutions and research centers stand as pillars for AFM’s growth. Beyond serving as a research tool, AFM finds its place in educational curricula, molding the next generation of scientists and engineers.
  • Research Investment: The infusion of both public and private funds into research and development, particularly in nanotechnology and materials science, amplifies AFM’s importance as a versatile research instrument.

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Market Insights:

Market Analysis by Type:

The global atomic force microscopy market is bifurcated into type, application, and geography. on the basis of type, the industrial grade segment exhibiting the fastest compound annual growth rate (CAGR) within the market underscores its pivotal role in addressing real-world industrial needs. This growth projection is rooted in the escalating integration of AFM technology into various industrial processes across sectors like semiconductors, electronics, manufacturing, and materials. Industrial Grade AFMs are poised to become indispensable tools for quality control, process optimization, and product development. Their emphasis on automation, user-friendliness, and robustness resonates with the demand for efficient, high-throughput testing and analysis in industrial environments. By aiding in defect identification, surface characterization, and material property enhancement, Industrial Grade AFMs enhance product quality and innovation. As industries undergo digital transformation with Industry 4.0 and IoT adoption, the adaptability of these AFMs to smart manufacturing aligns perfectly with evolving industrial trends.

Research Grade AFM: Research Grade AFMs are designed primarily for scientific exploration and academic research. They emphasize high-resolution imaging, advanced spectroscopy, and compatibility with a wide range of experimental techniques. These systems cater to researchers in fields such as materials science, life sciences, nanotechnology, and fundamental physics. Research Grade AFMs often feature innovative technologies, customizable configurations, and capabilities for probing nanoscale properties with precision. Their versatility suits the evolving needs of academia and advanced research settings, supporting groundbreaking discoveries, fundamental understanding, and exploratory studies.

Industrial Grade AFM: Industrial Grade AFMs are engineered with a focus on reliability, automation, and robustness to meet the demands of industrial applications. These systems find application in quality control, process optimization, and product development across sectors such as semiconductors, electronics, manufacturing, and materials industries. Industrial AFMs emphasize user-friendly interfaces, automated operation, and repeatable measurements, aligning with the efficiency and consistency requirements of industrial environments. They enable in-line inspection, defect analysis, and production monitoring, contributing to improved product quality and operational efficiency.

Market Analysis by Application:

On the basis of application, the global atomic force microscopy market is further segmented into life sciences and biology, semiconductors and electronics, nanomaterial science, and others. The semiconductors and electronics segment emerges as a dominant application within the realm of atomic force microscopy (AFM) owing to its strategic significance in ensuring the precision and quality of nanoscale devices. In an era marked by relentless miniaturization of semiconductor components, AFM’s capability to provide intricate imaging, meticulous surface analysis, and adept defect detection positions it at the forefront of semiconductor manufacturing and electronics industries. The imperatives of identifying defects that could compromise device performance, characterizing thin films, and assessing surface roughness underscore AFM’s pivotal role. Its role expands beyond mere observation, delving into failure analysis, process optimization, and the pursuit of innovative nanoelectronic materials. The Semiconductors and Electronics sector’s adherence to rigorous standards and the growing demand for high-resolution insights dovetail seamlessly with AFM’s precision.

Life Sciences and Biology: AFM plays a crucial role in life sciences and biology by enabling high-resolution imaging and analysis of biological samples at the nanoscale. Researchers use AFM to study cellular structures, biomolecules, DNA, proteins, and interactions. It aids in understanding cellular mechanics, disease mechanisms, drug delivery, and other biological phenomena. AFM’s ability to operate in various environments, including liquid, makes it invaluable for biological research.

Semiconductors and Electronics: In the semiconductor and electronics industries, AFM serves as a powerful tool for characterizing thin films, measuring surface roughness, and inspecting semiconductor devices at the nanoscale. AFM helps ensure product quality, assess material properties, and identify defects that could impact device performance. Its role in quality control, process optimization, and failure analysis is crucial for maintaining the reliability of electronic components.

Nanomaterial Science: AFM is fundamental to nanomaterial science, enabling researchers to visualize and manipulate nanoscale materials, such as nanoparticles, nanotubes, and nanocomposites. AFM’s capacity to study material properties, including mechanical, electrical, and chemical characteristics, aids in developing innovative materials with enhanced properties for various applications, from energy storage to advanced coatings.

Other Applications: This category encompasses a wide range of additional applications, including physics, chemistry, materials science, and more. AFM’s versatility allows researchers to explore various phenomena at the nanoscale, from surface interactions to mechanical properties of materials.

The atomic force microscopy market research report presents the analysis of each segment from 2020 to 2030 considering 2022 as the base year for the research. The compounded annual growth rate (CAGR) for each respective segment is calculated for the forecast period from 2023 to 2030.

Historical & Forecast Period

  • 2020-21 – Historical Year
  • 2022 – Base Year
  • 2023-2030 – Forecast Period

Market Segmentation:

By Type:

  • Research Grade
  • Industrial Grade

By Application:

  • Life Sciences and Biology
  • Semiconductors and Electronics
  • Nanomaterial science
  • Others

By Region:

  • North America
  • Europe
  • Asia Pacific
  • Latin America
  • Middle East & Africa

Regional Analysis:

Geographically, North America emerges as the dominant region in the realm of Atomic Force Microscopy (AFM), primarily due to a confluence of factors that have established it as a prominent hub for AFM research, development, and application. Renowned for its research excellence, the region hosts a plethora of distinguished universities, research institutions, and technology centers that drive groundbreaking research and innovation across a diverse spectrum of AFM applications. This innovation is facilitated by a robust technological infrastructure and a culture of pushing boundaries.

The strong presence of key players in the AFM industry further reinforces North America’s leadership, fostering collaboration, knowledge exchange, and market growth. Significantly, the region enjoys ample funding and investments in nanotechnology and related fields, ensuring that researchers have the resources to explore AFM’s versatile potential. Interdisciplinary research flourishes within this ecosystem, aligning well with the multidisciplinary nature of AFM applications. Industries such as semiconductors, electronics, and life sciences, which contribute significantly to the regional economy, find AFM invaluable for material characterization, quality assurance, and advancing scientific understanding.

Competitive Assessment:

Some of the prominent market players operating in the global atomic force microscopy market are Bruker Corporation, Keysight Technologies, Inc., Oxford Instruments plc, Park Systems Corp., Nanosurf AG, and NT-MDT Spectrum Instruments. Companies are exploring markets through expansion, new investment, the introduction of new services, and collaboration as their preferred strategies. Players are exploring new geography through expansion and acquisition to gain a competitive advantage through joint synergy.

Recent Developments:

  • In April 2021, Asylum Research, a subsidiary of Oxford Instruments based in the UK, unveiled its latest innovation – the Cypher VRS1250 video-rate atomic force microscope (AFM). This new iteration offers double the speed of its predecessor, the first-generation Cypher VRS. Equipped with the ability to achieve scan rates of up to 1250 lines per second and frame rates of up to 45 frames per second, this advanced AFM enables researchers to capture intricate nanoscale details of dynamic events that were previously beyond reach. This heightened speed opens up avenues for studying fast-evolving phenomena with unprecedented precision.
  • In July 2020, Bruker, a US-based company, introduced the NanoRacer high-speed AFM system, marking a significant milestone in AFM technology. Distinguished by its remarkable imaging speed of 50 frames per second, this system sets a new benchmark in high-speed scanning capabilities. Notably, this breakthrough empowers real-time visualization of dynamic biological processes using atomic force microscopy. By allowing researchers to observe rapid biological interactions and movements at an unmatched pace, the NanoRacer system paves the way for deeper insights into the dynamics of biological systems on the nanoscale.

Key Companies:

  • Bruker Corporation
  • Keysight Technologies, Inc.
  • Oxford Instruments plc
  • Park Systems Corp.
  • Nanosurf AG
  • NT-MDT Spectrum Instruments
  • JEOL Ltd.
  • WITec GmbH
  • Nanonics Imaging Ltd.
  • Asylum Research (now part of Oxford Instruments)
  • Nanoscale Corporation
  • Nanotec Electronica S.L.

Key Questions Answered by Atomic Force Microscopy Market Report

  • Global atomic force microscopy market forecasts from 2023-2030
  • Regional market forecasts from 2023-2030 covering Asia-Pacific, North America, Europe, Middle East & Africa, and Latin America
  • Country-level forecasts from 2023-2030 covering 15 major countries from the regions as mentioned above
  • Atomic force microscopy submarket forecasts from 2023-2030 covering the market by type, application, and geography
  • Various industry models such as SWOT analysis, Value Chain Analysis about the market
  • Analysis of the key factors driving and restraining the growth of the global, regional, and country-level atomic force microscopy markets from 2023-2030
  • Competitive Landscape and market positioning of top 10 players operating in the market
Atomic Force Microscopy Market
Table of Content:

1. Preface


1.1. Report Description
1.1.1. Purpose of the Report
1.1.2. Target Audience
1.1.3. USP and Key Offerings
1.2. Research Scope
1.3. Research Methodology
1.3.1. Phase I – Secondary Research
1.3.2. Phase II – Primary Research
1.3.3. Phase III – Expert Panel Review
1.4. Assumptions

 

2. Executive Summary


2.1. Global Atomic Force Microscopy Market Portraiture
2.2. Global Atomic Force Microscopy Market, by Type, 2022 (USD Mn)
2.3. Global Atomic Force Microscopy Market, by Application, 2022 (USD Mn)
2.4. Global Atomic Force Microscopy Market, by Geography, 2022 (USD Mn)

 

3. Global Atomic Force Microscopy Market Analysis


3.1. Atomic Force Microscopy Market Overview
3.2. Market Inclination Insights
3.3. Market Dynamics
3.3.1. Drivers
3.3.2. Challenges
3.3.3. Opportunities
3.4. Attractive Investment Proposition
3.5. Competitive Analysis
3.6. Porter’s Five Force Analysis
3.6.1. Bargaining Power of Suppliers
3.6.2. Bargaining Power of Buyers
3.6.3. Threat of New Entrants
3.6.4. Threat of Substitutes
3.6.5. Degree of Competition
3.7. PESTLE Analysis
3.8. COVID-19 Impact Analysis

 

4. Global Atomic Force Microscopy Market By Type, 2020 – 2030 (USD Mn)


4.1. Overview
4.2. Research Grade
4.3. Industrial Grade

 

5. Global Atomic Force Microscopy Market By Application, 2020 – 2030 (USD Mn)


5.1. Overview
5.2. Life Sciences and Biology
5.3. Semiconductors and Electronics
5.4. Nanomaterial science
5.5. Others

 

6. North America Atomic Force Microscopy Market Analysis and Forecast, 2020 – 2030 (USD Mn)


6.1. Overview
6.2. North America Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
6.3. North America Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
6.4. North America Atomic Force Microscopy Market by Country, (2020-2030 USD Mn)
6.4.1. U.S.
6.4.1.1. U.S. Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
6.4.1.2. U.S. Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
6.4.2. Canada
6.4.2.1. Canada Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
6.4.2.2. Canada Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
6.4.3. Mexico
6.4.3.1. Mexico Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
6.4.3.2. Mexico Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)

 

7. Europe Atomic Force Microscopy Market Analysis and Forecast, 2020 - 2030 (USD Mn)


7.1. Overview
7.2. Europe Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
7.3. Europe Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
7.4. Europe Atomic Force Microscopy Market by Country, (2020-2030 USD Mn)
7.4.1. Germany
7.4.1.1. Germany Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
7.4.1.2. Germany Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
7.4.2. U.K.
7.4.2.1. U.K. Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
7.4.2.2. U.K. Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
7.4.3. France
7.4.3.1. France Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
7.4.3.2. France Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
7.4.4. Spain
7.4.4.1. Spain Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
7.4.4.2. Spain Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
7.4.5. Italy
7.4.5.1. Italy Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
7.4.5.2. Italy Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
7.4.6. Rest of Europe
7.4.6.1. Rest of Europe Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
7.4.6.2. Rest of Europe Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)

 

8. Asia Pacific Atomic Force Microscopy Market Analysis and Forecast, 2020 - 2030 (USD Mn)


8.1. Overview
8.2. Asia Pacific Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
8.3. Asia Pacific Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
8.4. Asia Pacific Atomic Force Microscopy Market by Country, (2020-2030 USD Mn)
8.4.1. China
8.4.1.1. China Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
8.4.1.2. China Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
8.4.2. Japan
8.4.2.1. Japan Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
8.4.2.2. Japan Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
8.4.3. India
8.4.3.1. India Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
8.4.3.2. India Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
8.4.4. South Korea
8.4.4.1. South Korea Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
8.4.4.2. South Korea Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
8.4.5. Rest of Asia Pacific
8.4.5.1. Rest of Asia Pacific Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
8.4.5.2. Rest of Asia Pacific Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)

 

9. Latin America (LATAM) Atomic Force Microscopy Market Analysis and Forecast, 2020 - 2030 (USD Mn)


9.1. Overview
9.2. Latin America Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
9.3. Latin America Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
9.4. Latin America Atomic Force Microscopy Market by Country, (2020-2030 USD Mn)
9.4.1. Brazil
9.4.1.1. Brazil Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
9.4.1.2. Brazil Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
9.4.2. Argentina
9.4.2.1. Argentina Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
9.4.2.2. Argentina Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
9.4.3. Rest of Latin America
9.4.3.1. Rest of Latin America Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
9.4.3.2. Rest of Latin America Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)

 

10. Middle East and Africa Atomic Force Microscopy Market Analysis and Forecast, 2020 - 2030 (USD Mn)


10.1. Overview
10.2. MEA Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
10.3. MEA Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
10.4. Middle East and Africa Atomic Force Microscopy Market, by Country, (2020-2030 USD Mn)
10.4.1. GCC
10.4.1.1. GCC Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
10.4.1.2. GCC Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
10.4.2. South Africa
10.4.2.1. South Africa Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
10.4.2.2. South Africa Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)
10.4.3. Rest of MEA
10.4.3.1. Rest of MEA Atomic Force Microscopy Market by Type, (2020-2030 USD Mn)
10.4.3.2. Rest of MEA Atomic Force Microscopy Market by Application, (2020-2030 USD Mn)

 

11. Competitive Landscape


11.1. Company Market Share Analysis, 2022
11.2. Competitive Dashboard
11.3. Competitive Benchmarking, By Type
11.4. Competitive Benchmarking, By Application
11.5. Geographic Presence Heatmap Analysis
11.6. Company Evolution Matrix
11.6.1. Star
11.6.2. Pervasive
11.6.3. Emerging Leader
11.6.4. Participant
11.7. Strategic Analysis Heatmap Analysis
11.8. Key Developments and Growth Strategies
11.8.1. Mergers and Acquisitions
11.8.2. New Product Launch
11.8.3. Joint Ventures
11.8.4. Others

 

12. Company Profiles


12.1. Bruker Corporation
12.1.1. Business Description
12.1.2. Financial Health and Budget Allocation
12.1.3. Product Positions/Portfolio
12.1.4. Recent Development
12.1.5. SWOT Analysis
12.2. Keysight Technologies, Inc.
12.3. Oxford Instruments plc
12.4. Park Systems Corp.
12.5. Nanosurf AG
12.6. NT-MDT Spectrum Instruments
12.7. JEOL Ltd.
12.8. WITec GmbH
12.9. Nanonics Imaging Ltd.
12.10. Asylum Research (now part of Oxford Instruments)
12.11. Nanoscale Corporation
12.12. Nanotec Electronica S.L.
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