{"id":1937,"date":"2026-04-30T14:31:52","date_gmt":"2026-04-30T06:31:52","guid":{"rendered":"https:\/\/jeez-semicon.com\/?p=1937"},"modified":"2026-04-30T15:01:51","modified_gmt":"2026-04-30T07:01:51","slug":"cmp-materials-market-trends-outlook-2025-2030","status":"publish","type":"post","link":"https:\/\/jeez-semicon.com\/fr\/blog\/cmp-materials-market-trends-outlook-2025-2030\/","title":{"rendered":"March\u00e9 des mat\u00e9riaux CMP : Tendances et perspectives 2025-2030"},"content":{"rendered":"<!-- JEEZ | Cluster 7: CMP Materials Market: Trends & Outlook 2025\u20132030 -->\n<style>\n.jz*,.jz *::before,.jz *::after{box-sizing:border-box;margin:0;padding:0}\n.jz{font-family:'Segoe UI',Arial,sans-serif;font-size:16px;line-height:1.8;color:#1a1a2e;max-width:900px;margin:0 auto}\n.jz-hero{background:linear-gradient(135deg,#0f2544 0%,#1a4a8a 55%,#0e7c86 100%);border-radius:12px;padding:56px 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tr{background:linear-gradient(90deg,#0f2544,#1a4a8a);color:#fff}\n.jz-table th{padding:12px 14px;text-align:left;font-weight:600;white-space:nowrap}\n.jz-table td{padding:10px 14px;border-bottom:1px solid #e4edf8;color:#334;vertical-align:top}\n.jz-table tbody tr:nth-child(even){background:#f5f9ff}\n.jz-table tbody tr:hover{background:#ebf3ff}\n.jz-fact{border-left:4px solid #0e7c86;padding:14px 20px;background:#f0fffe;border-radius:0 8px 8px 0;margin:22px 0;font-size:1em;color:#0f3a3a;font-style:italic}\n.jz-fact strong{font-style:normal;color:#064444}\n.jz-trend-card{background:#fff;border-left:4px solid #1a4a8a;border-radius:0 10px 10px 0;padding:18px 22px;margin:16px 0;box-shadow:0 2px 8px rgba(26,74,138,.05)}\n.jz-trend-card h4{margin-top:0;color:#0f2544}\n.jz-trend-card p{margin-bottom:0;font-size:.93em}\n.jz-risk-card{background:#fff;border-left:4px solid #c04040;border-radius:0 10px 10px 0;padding:18px 22px;margin:16px 0;box-shadow:0 2px 8px rgba(180,40,40,.05)}\n.jz-risk-card h4{margin-top:0;color:#8a1010}\n.jz-risk-card p{margin-bottom:0;font-size:.93em}\n.jz-cta{background:linear-gradient(135deg,#0f2544 0%,#1a4a8a 60%,#0e7c86 100%);border-radius:12px;padding:44px 36px;text-align:center;margin:56px 0 36px;position:relative;overflow:hidden}\n.jz-cta h2{font-size:1.6em;color:#fff;border:none;margin:0 0 12px;position:relative;z-index:1}\n.jz-cta p{color:#c8dff0;margin-bottom:24px;position:relative;z-index:1}\n.jz-btn{display:inline-block;background:#fff;color:#0f2544;font-weight:700;font-size:.93em;padding:12px 30px;border-radius:50px;text-decoration:none;transition:all .25s;position:relative;z-index:1;box-shadow:0 4px 14px rgba(0,0,0,.18)}\n.jz-btn:hover{background:#a8d8ea;color:#0f2544;transform:translateY(-1px)}\n.jz-btn-sec{display:inline-block;background:rgba(255,255,255,.12);color:#e8f4ff;font-weight:600;font-size:.88em;padding:10px 24px;border-radius:50px;text-decoration:none;transition:all .25s;position:relative;z-index:1;border:1px solid rgba(255,255,255,.3);margin-left:12px}\n.jz-btn-sec:hover{background:rgba(255,255,255,.22);color:#fff}\n.jz-tags{display:flex;flex-wrap:wrap;gap:7px;margin:20px 0}\n.jz-tag{background:#e8f2ff;color:#1a4a8a;font-size:.77em;font-weight:600;padding:4px 11px;border-radius:20px;border:1px solid #c0d8f5}\n.jz-divider{border:none;border-top:1px solid #e0ebff;margin:38px 0}\n.jz-pillar-link{display:inline-flex;align-items:center;gap:8px;background:#e8f2ff;border:1px solid #b8d5f5;border-radius:8px;padding:10px 18px;text-decoration:none;color:#1a4a8a;font-size:.9em;font-weight:600;margin:10px 0 24px;transition:all .2s}\n.jz-pillar-link:hover{background:#d0e8ff;border-color:#1a4a8a}\n<\/style>\n\n<div class=\"jz\">\n<div class=\"jz-hero\">\n  <div class=\"jz-hero-label\">JEEZ Market Intelligence \u00b7 CMP Industry<\/div>\n  <p>A comprehensive market analysis covering global CMP consumables demand drivers, segment growth forecasts, supply chain transformation, geopolitical risks, and the technology shifts that will define the industry through 2030.<\/p>\n  <div class=\"jz-hero-meta\">\n    <span>\ud83d\udcc5 Mise \u00e0 jour avril 2026<\/span>\n    <span>Temps de lecture : ~20 min<\/span>\n    <span>\u270d\ufe0f \u00c9quipe de r\u00e9daction technique de JEEZ<\/span>\n  <\/div>\n<\/div>\n\n<a class=\"jz-pillar-link\" href=\"https:\/\/jeez-semicon.com\/fr\/blog\/What-Are-CMP-Materials-Complete-Guide\/\" target=\"_blank\" rel=\"noopener noreferrer\">\u2190 Retour \u00e0 Mat\u00e9riaux CMP : Le guide complet<\/a>\n\n<nav class=\"jz-toc\" aria-label=\"Table des mati\u00e8res\">\n  <div class=\"jz-toc-title\">\ud83d\udccb Table des mati\u00e8res<\/div>\n  <ol>\n    <li><a href=\"#mkt-size\">Market Size and Historical Growth<\/a><\/li>\n    <li><a href=\"#drivers\">Key Demand Drivers 2025\u20132030<\/a><\/li>\n    <li><a href=\"#segments\">Segment-by-Segment Growth Analysis<\/a><\/li>\n    <li><a href=\"#ai-hbm\">AI Accelerators and HBM: The Dominant Near-Term Growth Engine<\/a><\/li>\n    <li><a href=\"#advanced-logic\">Advanced Logic Node Ramp<\/a><\/li>\n    <li><a href=\"#memory\">Memory Segment: DRAM and NAND Trends<\/a><\/li>\n    <li><a href=\"#power\">Power, RF, and Automotive Semiconductors<\/a><\/li>\n    <li><a href=\"#supply-chain\">Supply Chain Transformation and Geopolitics<\/a><\/li>\n    <li><a href=\"#ceria-risk\">Ceria Supply Risk: A Special Case<\/a><\/li>\n    <li><a href=\"#innovation\">Technology Innovation Driving New Consumable Categories<\/a><\/li>\n    <li><a href=\"#forecast\">Market Forecast Summary 2026\u20132030<\/a><\/li>\n    <li><a href=\"#faq\">FAQ<\/a><\/li>\n  <\/ol>\n<\/nav>\n\n<section id=\"mkt-size\">\n  <h2>1. Market Size and Historical Growth<\/h2>\n  <p>The global CMP consumables market \u2014 encompassing CMP slurries, polishing pads, and pad conditioners \u2014 has grown from approximately $4.2 billion in 2018 to an estimated $9.2 billion in 2026, representing a compound annual growth rate of approximately 10% over this period. This growth has significantly outpaced overall semiconductor capital equipment spending over the same interval, reflecting the increasing CMP intensity of advanced-node process flows as device architectures shift from planar to 3D.<\/p>\n\n  <div class=\"jz-stats\">\n    <div class=\"jz-stat\"><div class=\"n\">$9.2B<\/div><div class=\"l\">Estimated global CMP consumables market size, 2026<\/div><\/div>\n    <div class=\"jz-stat\"><div class=\"n\">~$14B<\/div><div class=\"l\">Forecast market size by 2030 (JEEZ estimate, ~8% CAGR)<\/div><\/div>\n    <div class=\"jz-stat\"><div class=\"n\">~60%<\/div><div class=\"l\">Slurry share of total CMP consumables market<\/div><\/div>\n    <div class=\"jz-stat\"><div class=\"n\">~30%<\/div><div class=\"l\">Polishing pad share of total market<\/div><\/div>\n  <\/div>\n\n  <p>The market experienced a cyclical correction in 2023 as the semiconductor industry entered a broad inventory correction cycle, with fab utilization rates declining at memory fabs in particular. The recovery from 2024 onward has been sharp, driven by AI infrastructure spending that has kept leading-edge logic fabs operating at near-full utilization even while mature-node and memory markets normalized.<\/p>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"drivers\">\n  <h2>2. Key Demand Drivers 2025\u20132030<\/h2>\n\n  <div class=\"jz-trend-card\">\n    <h4>\ud83e\udd16 AI and Data Center Infrastructure<\/h4>\n    <p>Training and inference demand for large language models, multimodal AI systems, and AI-accelerated cloud services is driving unprecedented investment in leading-edge GPU and custom ASIC fabrication. Each H100\/B200-class GPU die requires advanced packaging with extensive CMP steps for redistribution layer (RDL) formation and TSV planarization. AI is the single largest incremental demand driver for CMP consumables in the 2025\u20132028 period.<\/p>\n  <\/div>\n\n  <div class=\"jz-trend-card\">\n    <h4>\ud83d\udce6 Advanced Packaging and 3D-IC<\/h4>\n    <p>CoWoS, SoIC, Foveros, and equivalent advanced packaging technologies integrate multiple dies through silicon interposers and wafer-bonding, each requiring multiple CMP steps. As AI chips continue to scale through packaging rather than (or in addition to) lithographic scaling, the CMP content per end-product chip increases rapidly. Hybrid bonding CMP alone is projected to be a $400\u2013600 million sub-market by 2029.<\/p>\n  <\/div>\n\n  <div class=\"jz-trend-card\">\n    <h4>\ud83d\udcbe HBM Memory Expansion<\/h4>\n    <p>High-Bandwidth Memory (HBM3E, HBM4) production requires wafer-level stacking with extensive CMP for each memory die tier. The HBM market is growing at approximately 40\u201350% annually through 2027 according to multiple analyst estimates, driven entirely by AI accelerator demand. SK hynix, Samsung, and Micron are all aggressively expanding HBM capacity, with direct implications for CMP slurry and pad consumption at their memory fabs.<\/p>\n  <\/div>\n\n  <div class=\"jz-trend-card\">\n    <h4>\u26a1 Power Semiconductors and EV<\/h4>\n    <p>Electric vehicle adoption is driving strong demand for silicon carbide (SiC) power devices, which require specialized CMP slurries for substrate and epi-layer planarization. The global SiC power device market is forecast to grow from approximately $3 billion in 2024 to over $10 billion by 2030, with CMP consumable demand scaling proportionally. This segment primarily uses alumina and colloidal silica abrasives and benefits from investment in 200 mm SiC wafer platforms.<\/p>\n  <\/div>\n\n  <div class=\"jz-trend-card\">\n    <h4>\ud83c\udf10 Geographic Fab Expansion<\/h4>\n    <p>The CHIPS Act (USA), the European Chips Act, and equivalent national semiconductor investment programs are funding major new fab construction in the United States (TSMC Arizona, Samsung Texas, Intel Ohio), Europe (TSMC Dresden, Intel Magdeburg), and Japan (Rapidus Hokkaido, TSMC Kumamoto). Each new 300 mm fab represents an incremental CMP consumable demand of $50\u2013150 million annually at full utilization, creating meaningful new market volume outside the traditional Taiwan\/Korea\/Japan fab heartland.<\/p>\n  <\/div>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"segments\">\n  <h2>3. Segment-by-Segment Growth Analysis<\/h2>\n  <div class=\"jz-table-wrap\">\n    <table class=\"jz-table\">\n      <thead>\n        <tr><th>Segment<\/th><th>2024 Market Size (est.)<\/th><th>2030 Forecast (est.)<\/th><th>CAGR<\/th><th>Primary Growth Driver<\/th><\/tr>\n      <\/thead>\n      <tbody>\n        <tr><td><strong>CMP Slurry \u2014 Oxide\/STI<\/strong><\/td><td>$1.8B<\/td><td>$2.6B<\/td><td>~6%<\/td><td>Advanced node step count increase; GAA STI complexity<\/td><\/tr>\n        <tr><td><strong>CMP Slurry \u2014 Copper\/Barrier<\/strong><\/td><td>$1.6B<\/td><td>$2.8B<\/td><td>~10%<\/td><td>Advanced packaging BEOL expansion; HBM Cu CMP<\/td><\/tr>\n        <tr><td><strong>CMP Slurry \u2014 Tungsten<\/strong><\/td><td>$0.7B<\/td><td>$0.8B<\/td><td>~3%<\/td><td>Mature node (modest growth); W being displaced by Co\/Ru at leading edge<\/td><\/tr>\n        <tr><td><strong>CMP Slurry \u2014 Cobalt\/Ru\/Mo (new metals)<\/strong><\/td><td>$0.2B<\/td><td>$1.0B<\/td><td>~30%<\/td><td>Fastest growing segment; driven by advanced logic metal transitions<\/td><\/tr>\n        <tr><td><strong>CMP Polishing Pads<\/strong><\/td><td>$2.2B<\/td><td>$3.4B<\/td><td>~7%<\/td><td>Step count growth; advanced packaging pad demand<\/td><\/tr>\n        <tr><td><strong>Pad Conditioners<\/strong><\/td><td>$0.8B<\/td><td>$1.1B<\/td><td>~5%<\/td><td>Proportional to pad market; CVD diamond disc premium growth<\/td><\/tr>\n        <tr><td><strong>SiC \/ Compound Semiconductor<\/strong><\/td><td>$0.3B<\/td><td>$0.9B<\/td><td>~20%<\/td><td>EV power device expansion; SiC 200mm transition<\/td><\/tr>\n      <\/tbody>\n    <\/table>\n  <\/div>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"ai-hbm\">\n  <h2>4. AI Accelerators and HBM: The Dominant Near-Term Growth Engine<\/h2>\n  <p>The AI infrastructure investment cycle that began in earnest in 2023 \u2014 driven by the rapid scaling of large language model training and deployment \u2014 has had a disproportionate impact on the CMP consumables market relative to its share of total wafer starts. This disproportionality arises because AI chips and the HBM memory they require are among the most CMP-intensive products manufactured at any fab.<\/p>\n\n  <h3>Why AI Chips Are CMP-Intensive<\/h3>\n  <ul>\n    <li>Training-class GPUs (NVIDIA H100, H200, B200; AMD MI300X) are fabricated at TSMC&#8217;s N4 and N3 nodes, each requiring 50+ CMP steps per wafer<\/li>\n    <li>Each GPU is packaged on a CoWoS silicon interposer requiring 5\u201310 additional CMP steps for RDL and bump planarization<\/li>\n    <li>HBM3E stacks paired with each GPU die require wafer thinning CMP and hybrid bonding surface preparation CMP for each of the 8\u201312 memory die tiers<\/li>\n    <li>Custom AI ASICs (Google TPU, Amazon Trainium, Microsoft Maia) follow similar process flows at comparable leading-edge nodes<\/li>\n  <\/ul>\n\n  <div class=\"jz-fact\">\n    <strong>Market impact calculation:<\/strong> A single NVIDIA B200 system module (containing multiple GPU dies and HBM stacks) may require 300\u2013400 total CMP wafer passes across all the semiconductor dies it contains, compared to fewer than 50 passes for a mainstream consumer CPU. The $40B+ annual GPU semiconductor revenue being generated by AI demand therefore creates CMP consumable demand that is 5\u20138\u00d7 more intensive per dollar of end-product revenue than the broader chip market average.\n  <\/div>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"advanced-logic\">\n  <h2>5. Advanced Logic Node Ramp<\/h2>\n  <p>The ramp of TSMC N3 and N2 (GAA), Samsung 3GAE and SF2, and Intel 18A and 14A creates sustained demand for advanced-node CMP consumables with performance specifications that the majority of the current supply base cannot meet. This performance gap creates a qualification bottleneck: only a small number of slurry and pad products have been \u2014 or are being \u2014 qualified for each new node, limiting the competitive dynamics and maintaining pricing power for technically capable suppliers.<\/p>\n  <p>The transition to GAA architecture is particularly significant for CMP consumables because it introduces entirely new CMP steps (nanosheet reveal, inner spacer CMP) that do not exist in FinFET flows, and requires new metal chemistries (Ru, Mo) that are not yet commercially mature. This creates a multi-year R&amp;D and qualification cycle for consumable suppliers seeking to participate in the leading-edge market.<\/p>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"memory\">\n  <h2>6. Memory Segment: DRAM and NAND Trends<\/h2>\n  <p>The memory segment \u2014 DRAM and 3D NAND \u2014 accounts for approximately 35% of total CMP consumable consumption by volume. The segment&#8217;s growth profile differs from logic: memory CMP has somewhat lower per-wafer step count than advanced logic, but the sheer volume of memory wafer starts (driven by AI-related demand growth across the data storage hierarchy) creates very large absolute demand.<\/p>\n  <p>3D NAND layer counts continue to increase (280+ layers in 2026, with 400+ targeted by 2028), creating incremental CMP demand for wordline planarization steps at each tier increment. Each additional 32-layer increment adds approximately 2\u20133 CMP steps to the process flow, meaning a transition from 200 to 300 layers adds 6\u20139 CMP steps per wafer \u2014 a meaningful consumption increase at the fab&#8217;s scale.<\/p>\n  <p>DRAM continues its EUV-enabled scaling at Samsung, SK hynix, and Micron, with each new generation introducing tighter CMP requirements for buried wordline, capacitor, and BEOL metal planarization. The transition to GAA-like buried gate structures in DRAM also introduces cobalt and alternative metal CMP requirements similar to those in logic.<\/p>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"power\">\n  <h2>7. Power, RF, and Automotive Semiconductors<\/h2>\n  <p>Outside the leading-edge logic and memory segments, the power semiconductor market is the fastest-growing application area for CMP materials. Driven by EV adoption, industrial motor control, and grid-scale power conversion, silicon carbide (SiC) MOSFET demand is growing at approximately 25\u201330% annually, significantly outpacing the broader semiconductor market.<\/p>\n  <p>SiC device manufacturing requires CMP for substrate planarization (using specialized high-pH colloidal silica or alumina slurries), epi-layer smoothing, and active region planarization. The transition from 150 mm to 200 mm SiC wafers, now underway at major SiC device manufacturers, will increase per-fab CMP consumable volume significantly. JEEZ&#8217;s alumina and specialty colloidal silica product lines address this market segment directly.<\/p>\n  <p>For CMP materials and advanced node details, see our in-depth article on <a href=\"https:\/\/jeez-semicon.com\/fr\/blog\/CMP-Materials-for-Advanced-Nodes-(Below-14nm)\/\" target=\"_blank\" rel=\"noopener noreferrer\">CMP Materials for Advanced Nodes<\/a>.<\/p>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"supply-chain\">\n  <h2>8. Supply Chain Transformation and Geopolitics<\/h2>\n  <p>The CMP consumables supply chain is being reshaped by a convergence of geopolitical forces that have no precedent in the industry&#8217;s history. The following dynamics are actively transforming supplier-fab relationships as of April 2026:<\/p>\n\n  <div class=\"jz-risk-card\">\n    <h4>US Export Controls on Semiconductor Materials<\/h4>\n    <p>The US Department of Commerce&#8217;s Bureau of Industry and Security (BIS) has progressively tightened export controls on semiconductor manufacturing equipment and materials since 2022. While CMP slurries and pads are not currently subject to direct export licensing requirements in most cases, restrictions on the broader semiconductor manufacturing ecosystem affect which fabs in which countries can access leading-edge consumable products and services.<\/p>\n  <\/div>\n\n  <div class=\"jz-risk-card\">\n    <h4>China Domestic Semiconductor Investment<\/h4>\n    <p>China&#8217;s government-backed semiconductor investment programs have funded aggressive expansion of domestic CMP consumable production capacity. Domestic Chinese slurry and pad suppliers are rapidly gaining qualification at Chinese fabs, reducing the addressable market for international suppliers at these customers while simultaneously creating a more competitive environment in the global market as Chinese suppliers seek international sales to justify their investment.<\/p>\n  <\/div>\n\n  <div class=\"jz-trend-card\">\n    <h4>CHIPS Act and Regional Fab Construction<\/h4>\n    <p>New fab construction in the USA, Europe, and Japan under national semiconductor incentive programs creates CMP consumable demand in regions that have historically been undersupplied relative to the Taiwan\/Korea\/Japan fab heartland. Suppliers with manufacturing or distribution capabilities in these regions \u2014 or who are willing to establish them \u2014 will benefit from first-mover qualification advantages at these new fabs.<\/p>\n  <\/div>\n\n  <div class=\"jz-trend-card\">\n    <h4>Dual-Sourcing and Supply Chain Diversification<\/h4>\n    <p>Major fabs are systematically expanding their qualified supplier lists for CMP consumables, reducing single-source dependence that COVID-era disruptions revealed as a structural vulnerability. This is creating qualification opportunities for alternative suppliers \u2014 including JEEZ \u2014 at fabs that would previously have defaulted exclusively to tier-one incumbents.<\/p>\n  <\/div>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"ceria-risk\">\n  <h2>9. Ceria Supply Risk: A Special Case<\/h2>\n  <p>Cerium oxide (ceria), the critical abrasive for STI and oxide CMP, deserves special attention in any market risk analysis. China accounts for approximately 85\u201390% of global cerium oxide production, derived from rare earth ore processing at facilities concentrated in Inner Mongolia. This geographic concentration creates a structural supply risk that is distinct from other CMP raw materials and is receiving increasing strategic attention from both fabs and consumable formulators.<\/p>\n  <p>Mitigations being developed or deployed include:<\/p>\n  <ul>\n    <li><strong>Synthetic ceria production:<\/strong> High-purity ceria synthesized from non-Chinese precursors (cerium chloride from Australian, Brazilian, or US rare earth sources) is being developed by several slurry companies. Unit cost is higher than Chinese-derived ceria but the supply chain independence is valued by fabs facing geopolitical exposure.<\/li>\n    <li><strong>Ceria-free STI slurry development:<\/strong> Several major slurry suppliers are investing in high-selectivity silica-based formulations that could replace ceria for some STI applications. Performance parity with ceria has not been fully demonstrated for sub-5 nm STI as of 2026, but progress is being made.<\/li>\n    <li><strong>Strategic inventory buildup:<\/strong> Some fabs and slurry suppliers are maintaining 6\u201312 month ceria raw material inventories as a near-term risk hedge, accepting higher working capital costs as insurance against supply disruption.<\/li>\n  <\/ul>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"innovation\">\n  <h2>10. Technology Innovation Driving New Consumable Categories<\/h2>\n  <p>Beyond the well-established CMP slurry and polishing pad markets, a new generation of CMP materials and process technologies is emerging in response to the challenges of post-14 nm process nodes. These emerging categories represent both near-term R&amp;D investment opportunities and longer-term market growth vectors for the consumables industry.<\/p>\n\n  <div class=\"jz-grid2\">\n    <div class=\"jz-card\">\n      <h4>Ruthenium and Molybdenum Slurries<\/h4>\n      <ul>\n        <li>Currently a ~$200M market, projected to reach $1B+ by 2030<\/li>\n        <li>Fastest CAGR in CMP slurry (~30% annually)<\/li>\n        <li>Driven by GAA gate metal transitions at TSMC, Samsung, Intel<\/li>\n        <li>Only a small number of qualified products exist; premium pricing<\/li>\n      <\/ul>\n    <\/div>\n    <div class=\"jz-card\">\n      <h4>Hybrid Bonding CMP Consumables<\/h4>\n      <ul>\n        <li>Sub-market growing at ~25% CAGR through 2030<\/li>\n        <li>Ultra-pure nano-silica slurries at extreme purity specifications<\/li>\n        <li>Soft pad systems for sub-0.3 nm Ra preparation<\/li>\n        <li>Driven by HBM, 3D-IC logic stacking, and CMOS image sensors<\/li>\n      <\/ul>\n    <\/div>\n    <div class=\"jz-card\">\n      <h4>SiC Substrate CMP<\/h4>\n      <ul>\n        <li>~$300M in 2024, forecast $900M by 2030<\/li>\n        <li>200mm SiC transition doubles per-wafer consumable volume<\/li>\n        <li>Specialized high-pH silica and colloidal alumina slurries<\/li>\n        <li>EV demand is the primary growth driver<\/li>\n      <\/ul>\n    <\/div>\n    <div class=\"jz-card\">\n      <h4>Electrochemical CMP (ECMP)<\/h4>\n      <ul>\n        <li>Still primarily in research and early qualification phase<\/li>\n        <li>Combines electrochemical dissolution with minimal mechanical abrasion<\/li>\n        <li>Potential applications: ultra-low-k, 2D materials, sub-1 nm removal control<\/li>\n        <li>Tool platform and consumable co-development required for commercialization<\/li>\n      <\/ul>\n    <\/div>\n  <\/div>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"forecast\">\n  <h2>11. Market Forecast Summary 2026\u20132030<\/h2>\n  <div class=\"jz-table-wrap\">\n    <table class=\"jz-table\">\n      <thead>\n        <tr><th>Year<\/th><th>Total CMP Market (est.)<\/th><th>Boues<\/th><th>Pads<\/th><th>Conditioners<\/th><th>Key Market Event<\/th><\/tr>\n      <\/thead>\n      <tbody>\n        <tr><td><strong>2026<\/strong><\/td><td>$9.2B<\/td><td>$5.5B<\/td><td>$2.7B<\/td><td>$1.0B<\/td><td>AI GPU demand at peak; HBM3E capacity ramp; GAA N3 volume production<\/td><\/tr>\n        <tr><td><strong>2027<\/strong><\/td><td>$10.1B<\/td><td>$6.0B<\/td><td>$3.0B<\/td><td>$1.1B<\/td><td>N2\/18A ramp; HBM4 qualification; new US\/Europe fabs initial production<\/td><\/tr>\n        <tr><td><strong>2028<\/strong><\/td><td>$11.2B<\/td><td>$6.7B<\/td><td>$3.3B<\/td><td>$1.2B<\/td><td>300+ layer 3D NAND; Ru\/Mo slurry commercialization; SiC 200mm volume<\/td><\/tr>\n        <tr><td><strong>2029<\/strong><\/td><td>$12.4B<\/td><td>$7.5B<\/td><td>$3.6B<\/td><td>$1.3B<\/td><td>1.4nm node early production; backside power delivery CMP; hybrid bonding at scale<\/td><\/tr>\n        <tr><td><strong>2030<\/strong><\/td><td>$13.8B<\/td><td>$8.3B<\/td><td>$4.1B<\/td><td>$1.4B<\/td><td>Next-gen AI accelerator platforms; broad GAA maturity; 2D material research pilots<\/td><\/tr>\n      <\/tbody>\n    <\/table>\n  <\/div>\n  <p style=\"font-size:.85em;color:#778;\">Forecasts are JEEZ estimates based on publicly available industry reports, analyst consensus, and internal market analysis as of April 2026. Actual results may differ materially from forecasts due to macro, technology, and geopolitical factors.<\/p>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<section id=\"faq\">\n  <h2>12. FAQ<\/h2>\n\n  <h3>What is the total size of the CMP slurry market in 2026?<\/h3>\n  <p>The global CMP slurry market is estimated at approximately $5.5 billion in 2026, representing roughly 60% of the total CMP consumables market. This includes oxide\/STI slurries, copper and barrier slurries, tungsten slurries, and the rapidly growing advanced metal (Co, Ru, Mo) segment. The slurry market is growing faster than the pad market, driven by the disproportionate increase in slurry consumption per wafer at advanced nodes.<\/p>\n\n  <h3>How is AI demand affecting the CMP consumables market?<\/h3>\n  <p>AI is the single largest incremental demand driver for CMP consumables in the 2025\u20132028 window. AI training chips and the HBM memory they require are among the most CMP-intensive products in semiconductor manufacturing \u2014 each GPU\/accelerator ecosystem involves 300\u2013400+ cumulative CMP wafer passes across all its constituent dies. The concentration of AI chip production at a small number of leading-edge fabs (primarily TSMC and Samsung) means this demand is immediately visible in consumable consumption at those facilities.<\/p>\n\n  <h3>Which regions will see the fastest CMP consumables market growth?<\/h3>\n  <p>The fastest absolute market growth will remain concentrated in East Asia (Taiwan, South Korea, Japan) where the highest-density advanced-node manufacturing is concentrated. However, the fastest growth rate on a percentage basis through 2030 will likely be in the USA and Europe, where new fab investments under the CHIPS Act and European Chips Act are bringing significant new wafer capacity to regions that have historically been lightly represented in semiconductor manufacturing. These new fabs will need to build local CMP consumable supply chains, creating first-mover qualification opportunities for suppliers willing to invest in regional presence.<\/p>\n<\/section>\n\n<hr class=\"jz-divider\"\/>\n\n<div class=\"jz-tags\">\n  <span class=\"jz-tag\">CMP Market 2026<\/span><span class=\"jz-tag\">CMP Industry Trends<\/span><span class=\"jz-tag\">AI Semiconductor<\/span>\n  <span class=\"jz-tag\">HBM CMP<\/span><span class=\"jz-tag\">3D-IC Market<\/span><span class=\"jz-tag\">SiC Market<\/span>\n  <span class=\"jz-tag\">CMP Supply Chain<\/span><span class=\"jz-tag\">JEEZ<\/span>\n<\/div>\n\n<div class=\"jz-cta\">\n  <h2>Stay Ahead of CMP Market Developments<\/h2>\n  <p>JEEZ publishes regular technical and market updates on CMP materials. Contact us to discuss how emerging market trends affect your consumable strategy \u2014 and how JEEZ&#8217;s product roadmap aligns with your fab&#8217;s technology trajectory.<\/p>\n  <a href=\"https:\/\/jeez-semicon.com\/fr\/contact\/\" target=\"_blank\" rel=\"noopener noreferrer\" class=\"jz-btn\">Discuss Your CMP Strategy<\/a>\n  <a href=\"https:\/\/jeez-semicon.com\/fr\/blog\/What-Are-CMP-Materials-Complete-Guide\/\" target=\"_blank\" rel=\"noopener noreferrer\" class=\"jz-btn-sec\">\u2190 CMP Materials Complete Guide<\/a>\n<\/div>\n<\/div>","protected":false},"excerpt":{"rendered":"<p>JEEZ Market Intelligence \u00b7 CMP Industry A comprehensive market analysis covering global CMP consumables demand drivers, segment growth forecasts, supply chain transformation, geopolitical risks, and the technology shifts that will  &#8230;<\/p>","protected":false},"author":1,"featured_media":1956,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"_acf_changed":false,"footnotes":""},"categories":[9,59],"tags":[],"class_list":["post-1937","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-blog","category-industry"],"acf":[],"_links":{"self":[{"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/posts\/1937","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/comments?post=1937"}],"version-history":[{"count":2,"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/posts\/1937\/revisions"}],"predecessor-version":[{"id":1939,"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/posts\/1937\/revisions\/1939"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/media\/1956"}],"wp:attachment":[{"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/media?parent=1937"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/categories?post=1937"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/jeez-semicon.com\/fr\/wp-json\/wp\/v2\/tags?post=1937"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}