{"id":2476,"date":"2026-07-16T13:18:05","date_gmt":"2026-07-16T05:18:05","guid":{"rendered":"https:\/\/jeez-semicon.com\/?p=2476"},"modified":"2026-07-16T13:18:05","modified_gmt":"2026-07-16T05:18:05","slug":"oxide-cmp-slurry-market-size-growth-regional-trends-2025-2030","status":"publish","type":"post","link":"https:\/\/jeez-semicon.com\/ja\/blog\/oxide-cmp-slurry-market-size-growth-regional-trends-2025-2030\/","title":{"rendered":"Oxide CMP Slurry Market: Size, Growth &amp; Regional Trends 2025\u20132030"},"content":{"rendered":"<link rel=\"preconnect\" href=\"https:\/\/fonts.googleapis.com\">\n<link rel=\"preconnect\" href=\"https:\/\/fonts.gstatic.com\" crossorigin>\n<link href=\"https:\/\/fonts.googleapis.com\/css2?family=Syne:wght@400;600;700;800&#038;family=Inter:ital,wght@0,300;0,400;0,500;0,600;1,400&#038;display=swap\" rel=\"stylesheet\">\n<style>\n\/* JEEZ Oxide CMP Cluster Article | Jizhi Electronic Technology Co., Ltd. | jeez-semicon.com *\/\n#jeez-ocmp *, #jeez-ocmp *::before, #jeez-ocmp *::after { box-sizing: border-box; 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border-radius: 10px; margin-bottom: 0.75rem; overflow: hidden; }\n.ocmp-faq-q { font-family: 'Syne', sans-serif; font-weight: 700; font-size: 0.9375rem; color: #0B2444; padding: 1.125rem 1.25rem; background: #F5F8FF; display: block; margin: 0; border-bottom: 1px solid #E2EAF4; line-height: 1.45; }\n.ocmp-faq-a { padding: 1rem 1.25rem; font-size: 0.9rem; color: #334155; margin: 0; line-height: 1.72; }\n.ocmp-hr { border: none; border-top: 1px solid #E2EAF4; margin: 2.5rem 0; }\n@media (max-width: 640px) {\n  .ocmp-compare { grid-template-columns: 1fr; }\n  .ocmp-toc ol { grid-template-columns: 1fr; }\n  #jeez-ocmp h2 { margin-top: 2.25rem; }\n}\n<\/style>\n<article id=\"jeez-ocmp\" itemscope itemtype=\"https:\/\/schema.org\/Article\">\n\n<div class=\"ocmp-meta\">\n  <span>\ud83d\udcc5 July 2026<\/span><span>\u00b7<\/span><span>\u23f1 16 min read<\/span><span>\u00b7<\/span><span>\u270d\ufe0f JEEZ Technical Team<\/span>\n<\/div>\n\n<p class=\"ocmp-lead\">The global oxide CMP slurry market is among the fastest-growing segments of the semiconductor materials industry, driven by relentless expansion in advanced-node logic, 3D NAND scaling, and new oxide polishing applications in advanced packaging. This article provides a comprehensive analysis of the market in 2026 \u2014 sizing, segmentation, demand drivers, competitive landscape, regional dynamics, and forecast to 2030. For technical context on what oxide CMP slurry is and how it is used, see our <a href=\"https:\/\/jeez-semicon.com\/ja\/blog\/oxide-cmp-slurry\/\" target=\"_blank\" rel=\"noopener noreferrer\">Oxide CMP Slurry: Complete Technical Guide<\/a>.<\/p>\n\n<nav class=\"ocmp-toc\" aria-label=\"\u76ee\u6b21\">\n  <p class=\"ocmp-toc-title\">\u76ee\u6b21<\/p>\n  <ol>\n    <li><a href=\"#mkt-overview\">Market Overview &amp; Size (2026)<\/a><\/li>\n    <li><a href=\"#mkt-drivers\">Key Demand Drivers<\/a><\/li>\n    <li><a href=\"#mkt-segment\">Market Segmentation<\/a><\/li>\n    <li><a href=\"#mkt-players\">Competitive Landscape<\/a><\/li>\n    <li><a href=\"#mkt-regional\">Regional Market Dynamics<\/a><\/li>\n    <li><a href=\"#mkt-forecast\">Forecast to 2030<\/a><\/li>\n    <li><a href=\"#mkt-faq\">\u3088\u304f\u3042\u308b\u8cea\u554f<\/a><\/li>\n  <\/ol>\n<\/nav>\n\n<h2 id=\"mkt-overview\">Market Overview &amp; Size (2026)<\/h2>\n<p>The global oxide CMP slurry market is estimated at approximately <strong>$2.5 billion<\/strong> in 2026, representing the largest application segment within the broader CMP slurry market by consumed value. CMP slurry overall (all metal, barrier, oxide, and specialty types) totals approximately $4.5 billion globally in 2026; oxide slurry accounts for over 55% of this total due to its dominant wafer-area consumption across all semiconductor device types.<\/p>\n<p>The oxide CMP slurry market has grown consistently at approximately 8\u201310% compound annual growth rate (CAGR) over the past five years, outpacing the overall semiconductor materials market (which grew at approximately 6% CAGR over the same period). This outperformance reflects the increasing number of oxide CMP steps per wafer as advanced node counts increase, and the entry of oxide CMP into new application spaces (advanced packaging) with historically small or zero CMP consumable content.<\/p>\n<div class=\"ocmp-box key\">\n  <span class=\"ocmp-box-label\">Market Snapshot \u2014 July 2026<\/span>\n  <p><strong>Market size:<\/strong> ~$2.5 billion &nbsp;|&nbsp; <strong>CAGR (2021\u20132026):<\/strong> ~8\u201310% &nbsp;|&nbsp; <strong>Forecast CAGR (2026\u20132030):<\/strong> ~8% &nbsp;|&nbsp; <strong>Largest region:<\/strong> Asia-Pacific (~68% share) &nbsp;|&nbsp; <strong>Top applications:<\/strong> ILD oxide (~60%), STI (~30%), other (~10%)<\/p>\n<\/div>\n\n<h2 id=\"mkt-drivers\">Key Demand Drivers<\/h2>\n<h3>AI Accelerator Fab Capacity Expansion<\/h3>\n<p>The single largest near-term demand driver for oxide CMP slurry in 2026 is the rapid expansion of advanced-node logic capacity to serve artificial intelligence chip demand. TSMC, Samsung Foundry, and Intel Foundry have all announced or begun construction of major 2 nm and 3 nm capacity additions in 2025\u20132026. Advanced logic at these nodes requires 25\u201335% more CMP steps per wafer than 5 nm predecessor processes, and the slurry consumed per step is increasingly specialized (and therefore higher-value). A single TSMC N2 fab capable of 50,000 wafer starts per month consumes tens of millions of dollars of oxide CMP slurry annually.<\/p>\n<h3>3D NAND Layer Count Scaling<\/h3>\n<p>Major NAND flash producers (Samsung, Micron, SK Hynix, Kioxia\/WD, YMTC) are qualifying and ramping 256-layer to 300-layer-plus 3D NAND products in 2025\u20132026. Each additional 32-layer step-height block in the ONO stack adds one to two additional oxide CMP steps per die. The global 3D NAND market at 300+ layers represents an incrementally larger oxide CMP slurry market than 128-layer NAND \u2014 both in terms of step count and in terms of the selectivity requirements that favor higher-value ceria formulations.<\/p>\n<h3>Advanced Packaging Growth<\/h3>\n<p>Advanced packaging \u2014 TSMC CoWoS, SoIC, Intel EMIB, and direct Cu\u2013Cu hybrid bonding \u2014 is the fastest-growing new application for oxide CMP slurry. HBM4 memory stacks require oxide CMP on bonding surfaces; hybrid bonding is rolling out across a widening range of AI and imaging chip products. Each advanced package that incorporates an oxide-polished bonding surface creates new ongoing demand for specialty oxide slurry formulations with no historical equivalent in standard chip packaging.<\/p>\n<h3>Mature-Node Capacity Investment<\/h3>\n<p>Significant government-incentivized semiconductor capacity investment in the US (CHIPS Act), Europe (European Chips Act), Japan, and India is expanding the global mature-node (28 nm to 180 nm) wafer start base. Mature-node fabs are large consumers of ILD oxide CMP slurry per wafer \u2014 the high film thicknesses and multiple ILD levels at these nodes offset the lower wafer volume per tool compared to leading-edge fabs. This investment cycle is creating sustained, geographically diversified demand for oxide CMP slurry at volumes that will support market growth independent of leading-edge technology fluctuations.<\/p>\n\n<h2 id=\"mkt-segment\">Market Segmentation<\/h2>\n<div class=\"ocmp-table-wrap\">\n<table>\n<thead><tr><th>\u30bb\u30b0\u30e1\u30f3\u30c8<\/th><th>2026 Share (Est.)<\/th><th>Key Characteristics<\/th><\/tr><\/thead>\n<tbody>\n<tr><td class=\"ocmp-td-label\">ILD Oxide CMP (Colloidal Silica)<\/td><td>~60%<\/td><td>Highest volume by wafer area; mature formulations; price-competitive; driven by BEOL step count growth<\/td><\/tr>\n<tr><td class=\"ocmp-td-label\">STI CMP (Ceria-Based)<\/td><td>~28%<\/td><td>Higher ASP than ILD; technology-driven growth at advanced nodes; ceria rare earth supply risk<\/td><\/tr>\n<tr><td class=\"ocmp-td-label\">Advanced Packaging \/ Other<\/td><td>~7%<\/td><td>Fastest-growing; hybrid bonding buff slurry; CoWoS; specialty formulations at premium pricing<\/td><\/tr>\n<tr><td class=\"ocmp-td-label\">Mature-Node (All Types)<\/td><td>~5%<\/td><td>Supported by government-incentivized fab buildout; stable pricing; multi-supplier environment<\/td><\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n\n<h2 id=\"mkt-players\">Competitive Landscape<\/h2>\n<p>The oxide CMP slurry market is served by a tiered supplier structure, with significant concentration at the advanced-node tier:<\/p>\n<h3>Tier 1 \u2014 Global Leaders<\/h3>\n<p><strong>Fujifilm Holdings<\/strong> (incorporating Hitachi Chemical \/ Showa Denko Materials CMP assets, rebranded under Fujifilm Electronic Materials) is the market share leader in advanced-node oxide slurry globally. Strong customer relationships at TSMC, Samsung, and Intel provide production qualification breadth unmatched by any competitor.<\/p>\n<p><strong>Entegris<\/strong> (including CMC Materials, acquired in 2022) holds major market positions in both colloidal silica ILD and ceria STI segments. The combined Entegris\/CMC portfolio covers essentially all oxide CMP applications and all major tool platforms.<\/p>\n<p><strong>Merck KGaA<\/strong> (through Versum Materials, acquired in 2019) is the third major Tier-1 competitor, with strong positions in ceria STI slurry at TSMC and Samsung. Merck&#8217;s semiconductor solutions division has been expanding slurry production capacity in Taiwan and Korea in 2025\u20132026 to address supply constraints.<\/p>\n<p><strong>\u682a\u5f0f\u4f1a\u793e\u30d5\u30b8\u30df<\/strong> (Japan) holds significant market share in ILD colloidal silica slurry, particularly at Japanese semiconductor manufacturers and increasingly at Korean and Taiwanese fabs. Fujimi&#8217;s PLANERLITE series is well-qualified at multiple foundry customers.<\/p>\n<h3>Tier 2 \u2014 Specialty &amp; Regional Suppliers<\/h3>\n<p>AGC (Japan), Resonac (formerly Showa Denko), and BASF Electronic Materials serve both advanced and mature-node markets with competitive ILD and STI formulations. Chinese domestic suppliers \u2014 including Jizhi Electronic Technology Co., Ltd. (JEEZ), Anji Microelectronics, and KMKL CMP Materials \u2014 hold growing market share in mature-node ILD and STI applications at domestic Chinese fabs and are progressively pursuing advanced-node qualifications. The domestic Chinese market for oxide CMP slurry is estimated at $350\u2013400 million in 2026, with domestic producers&#8217; share growing from approximately 15% in 2022 to approximately 25% in 2026, driven by supply chain localization incentives.<\/p>\n\n<h2 id=\"mkt-regional\">Regional Market Dynamics<\/h2>\n<p>Asia-Pacific dominates global oxide CMP slurry consumption with approximately 68% of total market value, reflecting the concentration of semiconductor manufacturing capacity in Taiwan (TSMC), South Korea (Samsung, SK Hynix), Japan (Kioxia, Sony, Renesas), and China (YMTC, CXMT, SMIC, Hua Hong). Within Asia-Pacific:<\/p>\n<ul>\n  <li><strong>Taiwan:<\/strong> Largest single-country consumer, driven by TSMC&#8217;s advanced-node capacity. N2 and N3 production ramp in 2025\u20132026 is creating significant incremental oxide slurry demand.<\/li>\n  <li><strong>South Korea:<\/strong> Second-largest consumer, with Samsung Electronics and SK Hynix collectively consuming significant oxide slurry for both advanced logic (Samsung Foundry) and memory (3D NAND, HBM DRAM) applications.<\/li>\n  <li><strong>China:<\/strong> Fastest-growing regional market. YMTC&#8217;s 3D NAND expansion, CXMT&#8217;s DRAM production ramp, and continued mature-node capacity additions are all driving strong oxide slurry demand. Government policy supporting domestic slurry supplier qualification is creating market share transition opportunities.<\/li>\n<\/ul>\n<p>North America accounts for approximately 14% of global consumption, Europe for approximately 8%, and Japan (outside of Asia-Pacific aggregate) for the remaining portion. New fab investments in the US (TSMC Arizona, Samsung Texas, Intel Ohio) and Europe (TSMC Dresden, Intel Germany) will shift regional shares modestly toward these regions through 2028\u20132030.<\/p>\n\n<h2 id=\"mkt-forecast\">Market Forecast to 2030<\/h2>\n<p>The oxide CMP slurry market is projected to reach approximately <strong>$3.4\u20133.8 billion<\/strong> by 2030, growing at a sustained CAGR of approximately 8%. Key upside and downside risks to this forecast:<\/p>\n<p><strong>Upside factors:<\/strong> Faster-than-expected AI chip demand growth (driving advanced-node logic capacity expansion beyond current announcements); accelerated hybrid bonding adoption across consumer electronics (expanding specialty oxide slurry market); successful qualification of domestic Chinese suppliers at advanced nodes (expanding the addressable market for second-source slurry).<\/p>\n<p><strong>Downside risks:<\/strong> Extended semiconductor capex cycle downturn reducing new fab starts; geopolitical disruptions to ceria rare earth supply from China; potential technological disruption from new dielectric deposition methods that reduce oxide CMP step count in future process generations.<\/p>\n<p>For technical context on how oxide CMP slurry is used in the end applications driving this market growth, see our articles on <a href=\"https:\/\/jeez-semicon.com\/ja\/blog\/Oxide-CMP-Slurry-Advanced-Nodes-FinFET-3D-NAND-GAA-Integration\/\" target=\"_blank\" rel=\"noopener noreferrer\">Oxide CMP Slurry for Advanced Nodes<\/a> \u305d\u3057\u3066 <a href=\"https:\/\/jeez-semicon.com\/ja\/blog\/ILD-Oxide-CMP-Slurry-TEOS-Planarization-Process-Slurry-Selection-Guide\/\" target=\"_blank\" rel=\"noopener noreferrer\">ILD Oxide CMP Slurry Process Guide<\/a>.<\/p>\n\n<div class=\"ocmp-back\">\n  \u2190 Part of the JEEZ Oxide CMP Slurry series. Return to the <a href=\"https:\/\/jeez-semicon.com\/ja\/blog\/oxide-cmp-slurry\/\" target=\"_blank\" rel=\"noopener noreferrer\">Oxide CMP Slurry: Complete Technical &amp; Procurement Guide<\/a>\n<\/div>\n<hr class=\"ocmp-hr\">\n<h2 id=\"mkt-faq\">Frequently Asked Questions: Oxide CMP Slurry Market<\/h2>\n<div class=\"ocmp-faq\">\n<div class=\"ocmp-faq-item\">\n  <p class=\"ocmp-faq-q\">What is the size of the global oxide CMP slurry market in 2026?<\/p>\n  <p class=\"ocmp-faq-a\">The global oxide CMP slurry market is estimated at approximately $2.5 billion in 2026, representing over 55% of the total CMP slurry market by value. The market has grown at approximately 8\u201310% CAGR over 2021\u20132026, driven by advanced-node capacity expansion, 3D NAND layer scaling, and new advanced packaging applications. ILD colloidal silica slurry accounts for approximately 60% of the market, with ceria STI slurry at ~28% and specialty\/packaging applications at ~12%.<\/p>\n<\/div>\n<div class=\"ocmp-faq-item\">\n  <p class=\"ocmp-faq-q\">Who are the major oxide CMP slurry suppliers?<\/p>\n  <p class=\"ocmp-faq-a\">The Tier-1 global leaders are Fujifilm (Fujifilm Electronic Materials), Entegris (incorporating CMC Materials), Merck KGaA (Versum Materials), and Fujimi. These four collectively hold the majority of revenue at advanced-node applications. Tier-2 suppliers include AGC, Resonac, BASF Electronic Materials, and domestic Chinese producers including JEEZ (Jizhi Electronic Technology Co., Ltd.), Anji Microelectronics, and KMKL CMP Materials \u2014 the last group holding growing market share in mature-node domestic Chinese applications.<\/p>\n<\/div>\n<div class=\"ocmp-faq-item\">\n  <p class=\"ocmp-faq-q\">Which semiconductor application drives the most oxide CMP slurry consumption?<\/p>\n  <p class=\"ocmp-faq-a\">Advanced logic (foundry) manufacturing drives the highest value oxide CMP slurry consumption due to the high step count per wafer and the premium pricing of advanced-node-qualified formulations. By volume, 3D NAND flash manufacturing consumes the largest absolute volume of oxide CMP slurry globally due to the 10\u201315 oxide CMP steps required per die and the massive production scale of the NAND industry.<\/p>\n<\/div>\n<div class=\"ocmp-faq-item\">\n  <p class=\"ocmp-faq-q\">What is the growth outlook for the oxide CMP slurry market through 2030?<\/p>\n  <p class=\"ocmp-faq-a\">The oxide CMP slurry market is projected to reach $3.4\u20133.8 billion by 2030 at approximately 8% CAGR. Key growth drivers through 2030 include continued advanced-node capacity expansion for AI chips, 3D NAND layer count increases, growing advanced packaging adoption (hybrid bonding, CoWoS), and mature-node fab buildout in the US, Europe, Japan, and India under government semiconductor investment programs.<\/p>\n<\/div>\n<\/div>\n\n<\/article>\n<script type=\"application\/ld+json\">\n{\"@context\":\"https:\/\/schema.org\",\"@type\":\"FAQPage\",\"mainEntity\":[\n{\"@type\":\"Question\",\"name\":\"What is the size of the global oxide CMP slurry market in 2026?\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"The global oxide CMP slurry market is estimated at approximately $2.5 billion in 2026, over 55% of the total CMP slurry market. It has grown at 8-10% CAGR over 2021-2026, with ILD colloidal silica at ~60%, ceria STI at ~28%, and specialty\/packaging at ~12%.\"}},\n{\"@type\":\"Question\",\"name\":\"Who are the major oxide CMP slurry suppliers?\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"Tier-1 global leaders are Fujifilm Electronic Materials, Entegris\/CMC Materials, Merck\/Versum Materials, and Fujimi. Tier-2 includes AGC, Resonac, BASF, and domestic Chinese producers including JEEZ (Jizhi Electronic Technology Co., Ltd.), Anji Microelectronics, and KMKL.\"}},\n{\"@type\":\"Question\",\"name\":\"Which semiconductor application drives the most oxide CMP slurry consumption?\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"Advanced logic manufacturing drives the highest value consumption due to high step count per wafer and premium pricing. By volume, 3D NAND flash consumes the most absolute slurry globally due to 10-15 oxide CMP steps per die and massive production scale.\"}},\n{\"@type\":\"Question\",\"name\":\"What is the growth outlook for the oxide CMP slurry market through 2030?\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"The market is projected to reach $3.4-3.8 billion by 2030 at ~8% CAGR, driven by advanced-node capacity for AI chips, 3D NAND layer scaling, advanced packaging adoption, and government-incentivized mature-node fab buildout globally.\"}}\n]}<\/script>","protected":false},"excerpt":{"rendered":"<p>\ud83d\udcc5 July 2026\u00b7\u23f1 16 min read\u00b7\u270d\ufe0f JEEZ Technical Team The global oxide CMP slurry market is among the fastest-growing segments of the semiconductor materials industry, driven by relentless expansion in  &#8230;<\/p>","protected":false},"author":1,"featured_media":2478,"comment_status":"closed","ping_status":"closed","sticky":false,"template":"","format":"standard","meta":{"_acf_changed":false,"footnotes":""},"categories":[9,59],"tags":[],"class_list":["post-2476","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-blog","category-industry"],"acf":[],"_links":{"self":[{"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/posts\/2476","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/comments?post=2476"}],"version-history":[{"count":2,"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/posts\/2476\/revisions"}],"predecessor-version":[{"id":2479,"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/posts\/2476\/revisions\/2479"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/media\/2478"}],"wp:attachment":[{"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/media?parent=2476"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/categories?post=2476"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/jeez-semicon.com\/ja\/wp-json\/wp\/v2\/tags?post=2476"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}