半导体划片刀片市场报告：2031 年趋势、预测与竞争分析

全球半导体切割刀片市场前景光明，300毫米和200毫米晶圆市场蕴藏着巨大机会。预计2025年至2031年期间，全球半导体切割刀片市场的复合年增长率将达到3.6%。该市场的主要驱动力是对先进半导体封装日益增长的需求，以及5G、人工智慧和物联网技术的日益普及。

Lucintel 预计，基于类型的无毂切割刀片在预测期内将实现高速成长。

从应用来看，300mm晶圆预计将出现强劲成长。

按地区划分，预计预测期内将出现最高成长。

半导体切割刀片市场趋势

半导体切割刀片市场是晶圆加工阶段的关键部件，用于将单个晶粒从晶圆上分离出来。精准高效的切割对于最大限度地提高产量比率并最大程度地减少对精密半导体装置的损伤至关重要。晶片设计日益复杂、新型晶圆材料的使用以及对产量不断提升的追求推动着半导体切割刀片市场的发展。製造商正致力于开发切割性能更佳、使用寿命更长、切口宽度更小的切割刀片。了解这些新兴趋势对于充分利用这个专业市场至关重要。以下是塑造半导体切割刀片市场的五大关键趋势：

• 先进刀片材料：製造商正在开发具有更高硬度、耐磨性和断裂韧性的先进刀片材料，以提高切割性能并延长刀片寿命。这包括探索新的钻石砂粒类型、黏合材料和刀片基板材料。先进材料对于切割日益复杂的晶圆材料并最大限度地减少削片和开裂的发生至关重要。
• 减小切口宽度：最小化切口宽度（即切割刀片切割的宽度）对于最大化每片晶圆的晶粒数量并减少材料浪费至关重要。开发人员正在优化刀片设计以减小切口宽度，并致力于开发更薄的刀片。减小切口宽度可以提高运转率利用率并降低成本。
• 雷射切割：雷射切割作为一种实现超精细切割并最大程度减少对精密半导体元件损伤的方法，正日益受到关注。雷射切割利用聚焦的雷射光束烧蚀晶圆材料，从而实现小切口宽度和高精度切割。该技术尤其适用于先进的封装技术和易碎晶圆材料。
• 切割刀片整合到自动化晶圆处理和切割系统中，以提高效率和产量。自动化系统能够精确对准晶圆、定位刀片并回收晶粒，从而最大限度地减少人为错误并提高整体生产率。与自动化系统的整合对于大批量半导体製造至关重要。
• 注重永续性：永续性在半导体製造中日益重要。製造商正在寻求减少切割刀片生产和使用对环境影响的方法。这包括使用再生材料、优化刀片寿命以减少废弃物，以及开发更环保的切割流程。永续实践对于最大限度地减少半导体製造的环境足迹至关重要。

这些趋势正在透过推动创新、提升性能和促进永续性来重塑半导体切割刀片市场。这些趋势正在推动更先进、更专业、更环保的切割刀片技术的发展，这对于满足半导体产业不断发展的需求至关重要。切割刀片市场的未来在于持续的技术创新和对精密工程的坚定承诺。

目录

第一章执行摘要

第二章全球半导体划片刀片市场：市场动态

• 简介、背景和分类
• 供应链
• 产业驱动力与挑战

第三章 2019-2031 年市场趋势与预测分析

• 宏观经济趋势（2019-2024）及预测（2025-2031）
• 全球半导体划片刀片市场趋势（2019-2024）及预测（2025-2031）
• 全球半导体划片刀片市场类型
  • 无轮毂切割刀片
  • 轮毂切割刀片
• 全球半导体切割刀片市场（按应用）
  • 300毫米晶圆
  • 200毫米晶圆

第四章 2019 - 2031 年各地区市场趋势及预测分析

• 全球半导体切割刀片市场（按地区）
• 北美半导体切割刀片市场
• 欧洲半导体切割刀片市场
• 亚太半导体切割刀片市场
• 其他地区的半导体切割刀片市场

第五章 竞争分析

• 产品系列分析
• 营运整合
• 波特五力分析

第六章 成长机会与策略分析

• 成长机会分析
  • 全球半导体划片刀片市场成长机会（按类型）
  • 全球半导体划片刀片市场的成长机会（按应用）
  • 全球半导体划片刀片市场各区域成长机会
• 全球半导体划片刀片市场的新趋势
• 战略分析
  • 新产品开发
  • 全球半导体切割刀片市场产能扩张
  • 全球半导体切割刀片市场的合併、收购和合资企业
  • 认证和许可

第七章主要企业简介

• Advent Tools & Technologies
• Advanced Dicing Technologies（ADT）
• Technocut
• MDL
• Saint-Gobain
• NAKANISHI
• TYROLIT

The future of the global semiconductor dicing blade market looks promising with opportunities in the 300mm wafer and 200mm wafer markets. The global semiconductor dicing blade market is expected to grow with a CAGR of 3.6% from 2025 to 2031. The major drivers for this market are the increasing demand for advanced semiconductor packaging and the rising adoption of 5G, AI, & IoT technologies.

Lucintel forecasts that, within the type category, hubless dicing blade is expected to witness higher growth over the forecast period.

Within the application category, 300mm wafer is expected to witness higher growth.

In terms of region, APAC is expected to witness the highest growth over the forecast period.

Gain valuable insights for your business decisions with our comprehensive 150+ page report. Sample figures with some insights are shown below.

Emerging Trends in the Semiconductor Dicing Blade Market

The semiconductor dicing blade market is a critical component of the wafer processing stage, responsible for separating individual dies from a wafer. Precise and efficient dicing is essential for maximizing yield and minimizing damage to delicate semiconductor devices. The market is driven by the increasing complexity of chip design, the use of new wafer materials, and the constant push for higher throughput. Manufacturers are focused on developing dicing blades with improved cutting performance, longer lifespan, and reduced kerf width. Understanding these emerging trends is crucial for navigating this specialized market. Here are five key trends shaping the semiconductor dicing blade market:

• Advanced Blade Materials: Manufacturers are developing advanced blade materials with improved hardness, wear resistance, and fracture toughness to enhance cutting performance and extend blade lifespan. This includes exploring new diamond grit types, bonding materials, and blade substrate materials. Advanced materials are crucial for dicing increasingly complex wafer materials and minimizing chipping and cracking.
• Reduced Kerf Width: Minimizing kerf width, the width of the cut made by the dicing blade, is essential for maximizing the number of dies per wafer and reducing material waste. Manufacturers are focusing on developing thinner blades with optimized cutting edge designs to achieve narrower kerf widths. Reduced kerf width leads to higher wafer utilization and cost savings.
• Laser Dicing: Laser dicing is gaining traction as a method for achieving ultra-fine cuts and minimizing damage to delicate semiconductor devices. Laser dicing uses a focused laser beam to ablate the wafer material, offering high precision and reduced kerf width. This technique is particularly suitable for advanced packaging technologies and fragile wafer materials.
• Integration with Automated Systems: Dicing blades are being integrated with automated wafer handling and dicing systems to increase efficiency and throughput. Automated systems enable precise wafer alignment, blade positioning, and die collection, minimizing human error and improving overall productivity. Integration with automation is crucial for high-volume semiconductor manufacturing.
• Focus on Sustainability: Sustainability is becoming increasingly important in semiconductor manufacturing. Manufacturers are exploring ways to reduce the environmental impact of dicing blade production and use. This includes using recycled materials, optimizing blade lifespan to reduce waste, and developing more environmentally friendly dicing processes. Sustainable practices are crucial for minimizing the environmental footprint of semiconductor manufacturing.

These trends are collectively reshaping the semiconductor dicing blade market by driving innovation, improving performance, and promoting sustainability. They are leading to the development of more advanced, specialized, and environmentally conscious dicing blade technologies, which are essential for meeting the evolving needs of the semiconductor industry. The future of the dicing blade market lies in continuous innovation and a strong focus on precision engineering.

Strategic Growth Opportunities in the Semiconductor Dicing Blade Market

The semiconductor dicing blade market is a critical part of the wafer processing stage, directly influencing yield and device performance. As semiconductor technology advances, the demands on dicing blades increase, creating strategic growth opportunities. Manufacturers are focused on developing innovative solutions to meet the evolving needs of the industry. Capitalizing on these opportunities requires a deep understanding of market trends, technological advancements, and customer requirements. Here are five key growth opportunities in the semiconductor dicing blade market:

• Advanced Node Manufacturing: The fabrication of advanced semiconductor nodes (e.g., 5nm and below) requires extremely precise and damage-free dicing. This presents a significant growth opportunity for dicing blade manufacturers to develop specialized blades that can handle these delicate and complex structures. Advanced node manufacturing demands innovative blade materials and designs to minimize chipping and cracking, driving demand for high-performance dicing solutions.
• 3D NAND Flash Memory Fabrication: The increasing demand for 3D NAND flash memory is driving the need for advanced dicing solutions for the complex vertical structures involved. Developing specialized dicing blades optimized for 3D NAND processing offers a substantial growth opportunity. Precise and efficient dicing is crucial during the various steps of 3D NAND fabrication, making specialized blades essential for achieving high yields.
• Silicon Carbide (SiC) and Gallium Nitride (GaN) Wafers: The growing adoption of SiC and GaN wafers in power electronics and other high-performance applications is creating a demand for specialized dicing solutions. These materials have unique properties and require blades that can withstand their hardness and specific processing conditions. Developing dicing blades tailored for SiC and GaN wafer processing presents a lucrative growth opportunity.
• Advanced Packaging Technologies: Advanced packaging technologies, such as fan-out wafer-level packaging (FOWLP) and 2.5D/3D integration, require precise and damage-free dicing of thin and fragile dies. Developing specialized dicing blades for these advanced packaging applications offers a significant growth opportunity. Precise die separation is crucial for maximizing yield and ensuring reliable device performance in advanced packages.
• Wafer Level Testing and Singulation: As wafer-level testing becomes more prevalent, the need for efficient and precise singulation of known good dies increases. Developing dicing blades optimized for singulating tested dies offers a growth opportunity. This capability can streamline the packaging process and improve manufacturing efficiency by focusing on known good dies.

These growth opportunities are collectively shaping the semiconductor dicing blade market by driving innovation, increasing specialization, and expanding the market reach. They are leading to the development of more advanced and specialized dicing blade technologies, which are essential for enabling the production of next-generation semiconductor devices. The future of the dicing blade market lies in continuous innovation and a strong focus on meeting the evolving needs of the semiconductor industry.

Semiconductor Dicing Blade Market Driver and Challenges

The semiconductor dicing blade market is a critical component of the wafer processing stage, directly impacting yield and device performance. Precise and efficient dicing is essential for maximizing usable dies and minimizing damage. The market is driven by increasing chip complexity, new wafer materials, and the demand for higher throughput. Manufacturers are focused on improving cutting performance, extending blade lifespan, and reducing kerf width. However, the market also faces challenges related to cost, material compatibility, and meeting the stringent requirements of advanced semiconductor nodes. Understanding these drivers and challenges is crucial for navigating this specialized market.

The factors responsible for driving the semiconductor dicing blade market include:

1. Increasing Complexity of Chip Design: Modern chips are becoming increasingly complex, with smaller feature sizes and new materials being used. This complexity necessitates more precise and efficient dicing processes, driving the demand for advanced dicing blade technologies. Complex chip designs require blades that can cut accurately and cleanly without damaging delicate structures.

2. Demand for Higher Throughput: Semiconductor manufacturers are constantly seeking to increase production throughput to meet the growing demand for chips. This drives the need for dicing blades that can cut faster and more efficiently, reducing processing time and increasing overall productivity. Higher throughput translates to increased revenue and faster time-to-market.

3. Use of New Wafer Materials: The semiconductor industry is increasingly using new wafer materials, such as silicon carbide (SiC) and gallium nitride (GaN), which are harder and more challenging to dice than traditional silicon wafers. This drives the development of specialized dicing blades that can handle these materials without chipping or cracking. New materials necessitate specialized blade compositions and designs.

4. Advancements in Dicing Technology: Continuous advancements in dicing technology, including new blade materials, cutting edge designs, and laser dicing techniques, are improving the performance and efficiency of dicing blades. These advancements enable more precise cuts, reduced kerf width, and extended blade lifespan, leading to improved yield and cost savings.

5. Focus on Cost Reduction: Semiconductor manufacturers are constantly seeking ways to reduce production costs. Dicing blades are a significant consumable in the wafer processing stage, making cost-effectiveness a key consideration. This drives the demand for dicing blades that offer a balance of performance, lifespan, and price. Cost reduction initiatives push manufacturers to optimize blade design and manufacturing processes.

Challenges in the semiconductor dicing blade market are:

1. High Development and Manufacturing Costs: Developing and manufacturing advanced dicing blades with specialized properties can be expensive, requiring significant investment in research and development, specialized equipment, and high-quality materials. These high costs can be a barrier to entry for smaller companies and can pose a challenge for manufacturers seeking to upgrade their product lines.

2. Material Compatibility and Blade Wear: Dicing blades must be compatible with the various wafer materials and chemicals used in semiconductor manufacturing. Blade wear is also a significant concern, as it can affect cutting accuracy and lead to defects. Finding materials that are both compatible and durable is a key challenge.

3. Meeting the Requirements of Advanced Nodes: As semiconductor technology advances and feature sizes shrink, the requirements for dicing blades become increasingly stringent. Meeting the demands of advanced nodes, such as 5nm and below, requires continuous innovation and significant investment in research and development to overcome the technological challenges associated with dicing these extremely delicate structures.

The interplay of these drivers and challenges is shaping the semiconductor dicing blade market. While the increasing complexity of chip design, demand for higher throughput, and advancements in dicing technology are fueling growth, high development costs, material compatibility issues, and the challenges of meeting the requirements of advanced nodes require careful consideration. Successfully navigating this dynamic landscape requires a strategic approach that balances innovation with cost-effectiveness, performance, and reliability.

List of Semiconductor Dicing Blade Companies

Companies in the market compete on the basis of product quality offered. Major players in this market focus on expanding their manufacturing facilities, R&D investments, infrastructural development, and leverage integration opportunities across the value chain. With these strategies semiconductor dicing blade companies cater increasing demand, ensure competitive effectiveness, develop innovative products & technologies, reduce production costs, and expand their customer base. Some of the semiconductor dicing blade companies profiled in this report include-

• Advent Tools & Technologies
• Advanced Dicing Technologies (ADT)
• Technocut
• MDL
• Saint-Gobain
• NAKANISHI
• TYROLIT

Semiconductor Dicing Blade Market by Segment

The study includes a forecast for the global semiconductor dicing blade market by type, application, and region.

Semiconductor Dicing Blade Market by Type [Value from 2019 to 2031]:

• Hubless Dicing Blades
• Hub Dicing Blades

Semiconductor Dicing Blade Market by Application [Value from 2019 to 2031]:

• 300mm Wafer
• 200mm Wafer

Semiconductor Dicing Blade Market by Region [Value from 2019 to 2031]:

• North America
• Europe
• Asia Pacific
• The Rest of the World

Country Wise Outlook for the Semiconductor Dicing Blade Market

The semiconductor dicing blade market is a crucial segment of the semiconductor manufacturing process, responsible for separating individual dies from a wafer. Precise and efficient dicing is essential for maximizing yield and minimizing damage to delicate semiconductor devices. The market is driven by the increasing complexity of chip design, the use of new wafer materials, and the constant push for higher throughput. Manufacturers are focused on developing dicing blades with improved cutting performance, longer lifespan, and reduced kerf width to meet the stringent requirements of advanced semiconductor manufacturing. Here's a look at recent developments in key markets:

• United States: The US market is characterized by a strong presence of established material science companies and specialized cutting tool manufacturers. Key trends include the development of advanced blade materials with improved hardness, wear resistance, and fracture toughness, the use of laser dicing techniques for ultra-fine cuts, and the integration of dicing blades with automated wafer handling systems for increased efficiency.
• China: China is rapidly expanding its semiconductor manufacturing capacity, leading to a surge in demand for dicing blades. Chinese manufacturers are focusing on developing cost-effective dicing blade solutions to compete with international players. The market is also witnessing a growing emphasis on localization and domestic production of dicing blades to support China's semiconductor industry growth.
• Germany: Germany has a strong tradition in precision engineering and manufacturing, which is reflected in its advanced dicing blade technologies. German companies are focusing on developing high-precision dicing blades with improved cutting accuracy and surface finish. The market is also seeing a growing emphasis on material characterization and quality control in dicing blade manufacturing.
• India: The Indian semiconductor industry is at a nascent stage but is expected to grow rapidly in the coming years. The Indian government is promoting initiatives to attract semiconductor manufacturing investments, which will drive the demand for dicing blades. Indian manufacturers are focusing on developing cost-effective and reliable dicing blade solutions to cater to the growing domestic market.
• Japan: Japan is a leading player in the semiconductor materials and equipment market, with a strong focus on innovation and quality. Japanese companies are developing cutting-edge dicing blade technologies with advanced cutting-edge designs and high precision. The market is also seeing a growing emphasis on minimizing kerf width and reducing chipping in dicing blade systems to meet the stringent requirements of advanced semiconductor processes.

Features of the Global Semiconductor Dicing Blade Market

Market Size Estimates: Semiconductor dicing blade market size estimation in terms of value ($B).

Trend and Forecast Analysis: Market trends (2019 to 2024) and forecast (2025 to 2031) by various segments and regions.

Segmentation Analysis: Semiconductor dicing blade market size by type, application, and region in terms of value ($B).

Regional Analysis: Semiconductor dicing blade market breakdown by North America, Europe, Asia Pacific, and Rest of the World.

Growth Opportunities: Analysis of growth opportunities in different types, applications, and regions for the semiconductor dicing blade market.

Strategic Analysis: This includes M&A, new product development, and competitive landscape of the semiconductor dicing blade market.

Analysis of competitive intensity of the industry based on Porter's Five Forces model.

This report answers following 11 key questions:

• Q.1. What are some of the most promising, high-growth opportunities for the semiconductor dicing blade market by type (hubless dicing blades and hub dicing blades), application (300mm wafer and 200mm wafer), and region (North America, Europe, Asia Pacific, and the Rest of the World)?
• Q.2. Which segments will grow at a faster pace and why?
• Q.3. Which region will grow at a faster pace and why?
• Q.4. What are the key factors affecting market dynamics? What are the key challenges and business risks in this market?
• Q.5. What are the business risks and competitive threats in this market?
• Q.6. What are the emerging trends in this market and the reasons behind them?
• Q.7. What are some of the changing demands of customers in the market?
• Q.8. What are the new developments in the market? Which companies are leading these developments?
• Q.9. Who are the major players in this market? What strategic initiatives are key players pursuing for business growth?
• Q.10. What are some of the competing products in this market and how big of a threat do they pose for loss of market share by material or product substitution?
• Q.11. What M&A activity has occurred in the last 5 years and what has its impact been on the industry?

Table of Contents

1. Executive Summary

2. Global Semiconductor Dicing Blade Market : Market Dynamics

• 2.1: Introduction, Background, and Classifications
• 2.2: Supply Chain
• 2.3: Industry Drivers and Challenges

3. Market Trends and Forecast Analysis from 2019 to 2031

• 3.1. Macroeconomic Trends (2019-2024) and Forecast (2025-2031)
• 3.2. Global Semiconductor Dicing Blade Market Trends (2019-2024) and Forecast (2025-2031)
• 3.3: Global Semiconductor Dicing Blade Market by Type
  • 3.3.1: Hubless Dicing Blades
  • 3.3.2: Hub Dicing Blades
• 3.4: Global Semiconductor Dicing Blade Market by Application
  • 3.4.1: 300mm Wafer
  • 3.4.2: 200mm Wafer

4. Market Trends and Forecast Analysis by Region from 2019 to 2031

• 4.1: Global Semiconductor Dicing Blade Market by Region
• 4.2: North American Semiconductor Dicing Blade Market
  • 4.2.1: North American Market by Type: Hubless Dicing Blades and Hub Dicing Blades
  • 4.2.2: North American Market by Application: 300mm Wafer and 200mm Wafer
• 4.3: European Semiconductor Dicing Blade Market
  • 4.3.1: European Market by Type: Hubless Dicing Blades and Hub Dicing Blades
  • 4.3.2: European Market by Application: 300mm Wafer and 200mm Wafer
• 4.4: APAC Semiconductor Dicing Blade Market
  • 4.4.1: APAC Market by Type: Hubless Dicing Blades and Hub Dicing Blades
  • 4.4.2: APAC Market by Application: 300mm Wafer and 200mm Wafer
• 4.5: ROW Semiconductor Dicing Blade Market
  • 4.5.1: ROW Market by Type: Hubless Dicing Blades and Hub Dicing Blades
  • 4.5.2: ROW Market by Application: 300mm Wafer and 200mm Wafer

5. Competitor Analysis

• 5.1: Product Portfolio Analysis
• 5.2: Operational Integration
• 5.3: Porter's Five Forces Analysis

6. Growth Opportunities and Strategic Analysis

• 6.1: Growth Opportunity Analysis
  • 6.1.1: Growth Opportunities for the Global Semiconductor Dicing Blade Market by Type
  • 6.1.2: Growth Opportunities for the Global Semiconductor Dicing Blade Market by Application
  • 6.1.3: Growth Opportunities for the Global Semiconductor Dicing Blade Market by Region
• 6.2: Emerging Trends in the Global Semiconductor Dicing Blade Market
• 6.3: Strategic Analysis
  • 6.3.1: New Product Development
  • 6.3.2: Capacity Expansion of the Global Semiconductor Dicing Blade Market
  • 6.3.3: Mergers, Acquisitions, and Joint Ventures in the Global Semiconductor Dicing Blade Market
  • 6.3.4: Certification and Licensing

7. Company Profiles of Leading Players

• 7.1: Advent Tools & Technologies
• 7.2: Advanced Dicing Technologies (ADT)
• 7.3: Technocut
• 7.4: MDL
• 7.5: Saint-Gobain
• 7.6: NAKANISHI
• 7.7: TYROLIT