Market Insight-Global Semiconductor Tape Market Overview 2025
Global Semiconductor Tape Market Was Valued at USD 1.69 Billion in 2024 and is Expected to Reach USD 3.00 Billion by the End of 2033, Growing at a CAGR of 6.32% Between 2025 and 2033.– Bossonresearch.com
The semiconductor tapes market refers to the industry focused on the production and application of specialized adhesive tapes used in the semiconductor manufacturing process. These tapes are essential for various stages, including wafer dicing, backgrinding, and bonding, where they serve to securely hold delicate semiconductor wafers in place during precision activities such as cutting, grinding, and packaging. Made from high-performance materials, semiconductor tapes offer strong adhesive properties to ensure stability and alignment, minimizing the risk of misalignment or damage to the wafer.
Driven by the evolving demands across the semiconductor value chain, the semiconductor tape market is undergoing a significant transformation. A key trend is the integration of tape applications throughout the wafer’s lifecycle—tapes now play critical roles in edge protection, back grinding, dicing, and chip mounting. This has led manufacturers to develop comprehensive, automation-compatible solutions. The continued miniaturization and thinning of wafers is fueling demand for high-performance tapes with characteristics like precise adhesion, residue-free removal, antistatic properties, and thermal stability. Additionally, the rise of advanced packaging technologies such as 2.5D, 3D, and system-in-package (SiP) solutions is accelerating demand for specialized tapes that support high-density, high-performance chip designs. Innovations in materials—such as advanced polymers and precision coatings—are reshaping the market, as manufacturers prioritize clean release and eco-friendly compliance for cutting-edge semiconductor processes.
In 2024, the global semiconductor tape market reached approximately USD 1.69 billion, supported by strong growth in sectors like AI chips, 5G, and electric vehicles. From 2025 to 2033, the market is projected to grow at a CAGR of 6.32%, driven by increasing wafer process complexity and packaging sophistication, including chiplet architectures and 2.5D/3D stacking. Back grinding and dicing tapes are increasingly critical for defect-free wafer handling amid consumer electronics miniaturization and heterogeneous integration. Regional fab expansions, particularly in the U.S., Japan, and Europe, are boosting local demand, while rising adoption of compound semiconductors (e.g., GaN, SiC) further supports market growth.
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Figure 1. Figure Global Semiconductor Tape Market Size (M USD)
Source: Bossonresearch.com, 2025
Semiconductor Tape Industry Chain Analysis
Figure 2. Industry Chain Map of Semiconductor Tape
Source: Secondary Sources, 2025
Driving Factors
Integration of Tape Applications Across the Wafer Lifecycle
The role of semiconductor tapes has expanded across the entire wafer processing lifecycle, from edge protection during etching (e.g., acid-resistant films) to wafer thinning (BG tapes), cutting (dicing tapes), and bonding (die attach films). As fabs and outsourced semiconductor assembly and test (OSAT) facilities aim for process optimization and cost reduction, they increasingly seek tape solutions that are compatible with automated systems, reduce defects, and simplify handling. This integration trend is driving manufacturers to offer comprehensive tape portfolios and customized application support, moving beyond single-use cases to full-process solutions.
Miniaturization and Thinning
Currently, semiconductor products tend to be miniaturized and thinned, and the methods of reducing size are: 1) using extremely thin semiconductor wafers; 2) using back grinding to thin the thickness of semiconductor wafers. Therefore, usually after the integrated circuit manufacturing process on the wafer and before the wafer dicing process, the wafer back grinding process is also included to thin multiple wafers at one time. This process requires the use of back grinding tape, dicing tape, thermal separation tape for hard substrates, etc.
In order to adapt to the technical needs of chip miniaturization, thinning, or increased size, the balance of pick-up and adhesion, prevention of cutting debris, no residual adhesive, anti-warping, anti-static, heat resistance, and moisture resistance are all higher performance requirements for semiconductor chip dicing tapes.
Advanced Packaging Technology
The semiconductor process flow includes the front-end wafer manufacturing process and the back-end packaging and testing process. The front-end process is the wafer manufacturing process. In the front-end process, the wafer undergoes a series of steps such as oxidation, glue coating, photolithography, etching, ion implantation, physical/chemical vapor deposition, polishing, wafer inspection, cleaning, etc., and each step requires corresponding semiconductor manufacturing equipment. The back-end process is the packaging and testing process. In the back-end process, the uncut wafer enters the IC packaging and testing link, undergoing grinding/back thinning, cutting, patching, silver paste curing, lead welding, plastic sealing, rib cutting and forming, and FT testing. Each link also requires corresponding semiconductor packaging equipment and semiconductor testing equipment. Finally, the chip product is obtained.
Traditional packaging can no longer meet the new demands represented by artificial intelligence and high-performance computing. Advanced packaging technology has emerged to form a unique mid-end process. Advanced packaging is also called high-density packaging, which has the characteristics of a large number of pins, a small chip system and high integration. Advanced packaging belongs to the middle process, including cleaning, sputtering, gluing, exposure, development, electroplating, degumming, etching, coating flux, reflow soldering, cleaning, testing and other steps. Different from the traditional back-end packaging and testing process, the key process of advanced packaging needs to be completed on the front-end platform, which is an extension of the front-end process.
China's Semiconductor Material Import Substitution
Against the backdrop of the escalation of US export controls, China has stepped up its efforts to promote import substitution of semiconductor materials. Recent US sanctions, including the expansion of the "Entity List" and long-arm jurisdiction measures, have further restricted China's access to advanced semiconductor technology, especially in manufacturing equipment, memory chips, and cooperation with third-party countries. These geopolitical tensions have accelerated China's determination to achieve technological independence, especially in upstream materials and processes that are critical to chip manufacturing.
At present, semiconductor materials are one of the weak links in China's semiconductor industry chain. Many semiconductor materials, including adhesive films for semiconductor manufacturing, mainly rely on imports. Most of China's domestic products have a low self-sufficiency rate and are mainly concentrated in low-end packaging materials with low technical barriers. In order to achieve "independent control" of integrated circuit manufacturing, China supports domestic semiconductor material manufacturers in terms of policies and funds, and encourages the development of domestic semiconductor materials. In terms of policies, China has introduced a series of support policies for the semiconductor materials industry, cultivating and supporting the development of domestic semiconductor materials companies through tax cuts and subsidies. In terms of funds, the National Integrated Circuit Industry Investment Fund (also known as the "National Big Fund") was established to promote the development of China's chip industry by investing in early projects across the entire national chip industry chain.
Materials and Technology Innovations
To meet increasingly complex technology requirements, semiconductor tape manufacturers are increasing their focus on materials science and precision coating technologies. New-generation tapes use improved materials such as polyimide and other high-performance polymers, designed to withstand extreme temperatures, UV exposure, and mechanical stress. In addition, ultra-clean manufacturing processes and residue-free tape removal technologies are also receiving attention, which are critical to maintaining chip integrity. These innovations not only meet the specific needs of advanced semiconductor nodes, but also support broader industry trends to improve yield, achieve miniaturization, and meet environmental requirements.
Key Development Trends
Integration of Tape Applications Across the Wafer Lifecycle
The role of semiconductor tapes has expanded across the entire wafer processing lifecycle, from edge protection during etching (e.g., acid-resistant films) to wafer thinning (BG tapes), cutting (dicing tapes), and bonding (die attach films). As fabs and outsourced semiconductor assembly and test (OSAT) facilities aim for process optimization and cost reduction, they increasingly seek tape solutions that are compatible with automated systems, reduce defects, and simplify handling. This integration trend is driving manufacturers to offer comprehensive tape portfolios and customized application support, moving beyond single-use cases to full-process solutions.
Miniaturization and Thinning
Currently, semiconductor products tend to be miniaturized and thinned, and the methods of reducing size are: 1) using extremely thin semiconductor wafers; 2) using back grinding to thin the thickness of semiconductor wafers. Therefore, usually after the integrated circuit manufacturing process on the wafer and before the wafer dicing process, the wafer back grinding process is also included to thin multiple wafers at one time. This process requires the use of back grinding tape, dicing tape, thermal separation tape for hard substrates, etc.
In order to adapt to the technical needs of chip miniaturization, thinning, or increased size, the balance of pick-up and adhesion, prevention of cutting debris, no residual adhesive, anti-warping, anti-static, heat resistance, and moisture resistance are all higher performance requirements for semiconductor chip dicing tapes.
Advanced Packaging Technology
The semiconductor process flow includes the front-end wafer manufacturing process and the back-end packaging and testing process. The front-end process is the wafer manufacturing process. In the front-end process, the wafer undergoes a series of steps such as oxidation, glue coating, photolithography, etching, ion implantation, physical/chemical vapor deposition, polishing, wafer inspection, cleaning, etc., and each step requires corresponding semiconductor manufacturing equipment. The back-end process is the packaging and testing process. In the back-end process, the uncut wafer enters the IC packaging and testing link, undergoing grinding/back thinning, cutting, patching, silver paste curing, lead welding, plastic sealing, rib cutting and forming, and FT testing. Each link also requires corresponding semiconductor packaging equipment and semiconductor testing equipment. Finally, the chip product is obtained.
Traditional packaging can no longer meet the new demands represented by artificial intelligence and high-performance computing. Advanced packaging technology has emerged to form a unique mid-end process. Advanced packaging is also called high-density packaging, which has the characteristics of a large number of pins, a small chip system and high integration. Advanced packaging belongs to the middle process, including cleaning, sputtering, gluing, exposure, development, electroplating, degumming, etching, coating flux, reflow soldering, cleaning, testing and other steps. Different from the traditional back-end packaging and testing process, the key process of advanced packaging needs to be completed on the front-end platform, which is an extension of the front-end process.
China's Semiconductor Material Import Substitution
Against the backdrop of the escalation of US export controls, China has stepped up its efforts to promote import substitution of semiconductor materials. Recent US sanctions, including the expansion of the "Entity List" and long-arm jurisdiction measures, have further restricted China's access to advanced semiconductor technology, especially in manufacturing equipment, memory chips, and cooperation with third-party countries. These geopolitical tensions have accelerated China's determination to achieve technological independence, especially in upstream materials and processes that are critical to chip manufacturing.
At present, semiconductor materials are one of the weak links in China's semiconductor industry chain. Many semiconductor materials, including adhesive films for semiconductor manufacturing, mainly rely on imports. Most of China's domestic products have a low self-sufficiency rate and are mainly concentrated in low-end packaging materials with low technical barriers. In order to achieve "independent control" of integrated circuit manufacturing, China supports domestic semiconductor material manufacturers in terms of policies and funds, and encourages the development of domestic semiconductor materials. In terms of policies, China has introduced a series of support policies for the semiconductor materials industry, cultivating and supporting the development of domestic semiconductor materials companies through tax cuts and subsidies. In terms of funds, the National Integrated Circuit Industry Investment Fund (also known as the "National Big Fund") was established to promote the development of China's chip industry by investing in early projects across the entire national chip industry chain.
Materials and Technology Innovations
To meet increasingly complex technology requirements, semiconductor tape manufacturers are increasing their focus on materials science and precision coating technologies. New-generation tapes use improved materials such as polyimide and other high-performance polymers, designed to withstand extreme temperatures, UV exposure, and mechanical stress. In addition, ultra-clean manufacturing processes and residue-free tape removal technologies are also receiving attention, which are critical to maintaining chip integrity. These innovations not only meet the specific needs of advanced semiconductor nodes, but also support broader industry trends to improve yield, achieve miniaturization, and meet environmental requirements.
Global Semiconductor Tape Market: Competitive Landscape
Despite a relatively fragmented global landscape, the market’s top five players held a combined 46.14% market share (CR5) in 2024, and the Herfindahl-Hirschman Index (HHI) stood at 4.70%, suggesting a moderately concentrated but competitive environment. While incumbents like Denka and 3M have seen slight share declines, emerging regional players and cost-competitive newcomers are intensifying competition. The industry faces high entry barriers due to technological complexity, certification requirements, capital intensity, and raw material constraints. Simultaneously, pricing pressure—particularly in commoditized segments like dicing tape—is challenging profit margins. Key players in the market include Mitsui Chemicals ICT Materia, Inc., Furukawa Electric, Denka, Lintec, 3M, Sekisui, Nitto, Shin-Etsu, Maxell Holdings, Cybrid Technologies Inc., Eleven Electron, D&X Co., Ltd., Taicang Zhanxin Adhesive Material Co., Ltd., Shanghai Plusco Tech Co., Ltd., DaehyunST, Semiconductor Equipment, and AMC.
Figure 3. The Global 5 Largest Players: Market Share by Semiconductor Tape Revenue in 2024
Source: Above companies; Secondary Sources and Bosson Research, 2025
Key players in the Semiconductor Tape Market include:
Mitsui Chemicals ICT Materia, Inc.
Furukawa Electric
Denka
Lintec
3M
Sekisui
Nitto
Shin-Etsu
Maxell Holdings
Cybrid Technologies Inc
Eleven Electron
D&X Co., Ltd
Taicang Zhanxin Adhesive Material Co., Ltd.
Shanghai Plusco Tech Co ., Ltd.
DaehyunST
Semiconductor Equipment
AMC
Others
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