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Detailed Parameter Table
| Parameter Name | Parameter Value |
| Product model | LAM 810-013872-106 |
| Manufacturer | LAM Research Corporation |
| Product category | High-Flow Vacuum Pressure Control Module (Advanced Mature Node 14nm–28nm Compatibility) |
| Vacuum Control Range | 1×10⁻³ Torr – 1×10⁻¹⁰ Torr (covers rough to ultra-high vacuum); Auto-range switching (150 ms response, no data gap) |
| Pressure Regulation Accuracy | ±0.8% of setpoint (1×10⁻³–1×10⁻⁷ Torr); ±2.2% of setpoint (1×10⁻⁷–1×10⁻¹⁰ Torr) |
| Flow Handling Capacity | Supports up to 500 sccm process gas flow (N₂ equivalent); Max pressure differential: 50 psig (inlet to chamber) |
| Pressure Sensing | Dual-sensor redundancy: Primary high-precision capacitance manometer (1×10⁻³–1×10⁻¹⁰ Torr, accuracy class 0.3); Secondary ionization gauge (1×10⁻⁷–1×10⁻¹⁰ Torr); Sampling rate: 100 Hz (dynamic high-flow mode), 20 Hz (standard mode) |
| Control Outputs | 6× analog 0–10 V DC (for dual high-flow throttle valves + three turbomolecular pumps); 12× digital I/O (interlock with high-flow MFCs, chambers, robots); PWM output (variable pump speed control, 0–100%, high-torque compatible) |
| Communication Protocols | EtherNet/IP (2 Gbps, real-time high-flow control); RS-485 (Modbus RTU, backup monitoring); OPC UA (for MES integration); Compatible with LAM PCS v6.5+ |
| Electrical Requirements | 24 VDC (±10% tolerance); Power consumption: ≤40 W (idle); ≤120 W (full load, high-flow valve actuation + pump control); ≤20 W (sensor standby) |
| Environmental Ratings | Operating temp: 10°C–45°C (active temperature compensation, ±0.03°C drift max); Humidity: 5–85% RH (non-condensing); Altitude: ≤2000 m; Vibration: ≤0.08 g (10–2000 Hz); IP54 protection; ISO Class 2 cleanroom compatible |
| Physical Dimensions | 180 mm (L) × 130 mm (W) × 65 mm (H); Weight: 1.8 kg (4.0 lbs); Mounting: DIN rail / panel-mount (heavy-duty anti-vibration stainless steel brackets included) |
| Material Specifications | – Enclosure: 316L stainless steel (electropolished, Ra ≤0.05 μm, EP-passivated per SEMI F20)- Internal Valves: PTFE-sealed 316L stainless steel (high-flow design, low outgassing, weak fluorinated gas compatible)- Electrical Feedthrough: Alumina ceramic (breakdown voltage ≥8 kV, vacuum-tight)- Seals: Kalrez® 9600 (operating temp: -40°C–200°C, low outgassing, chemical resistance for NF₃/CF₄ ≤20%) |
| Safety Certifications | SEMI S2, SEMI F47, CE, RoHS 3.0, ATEX Zone 2; Overcurrent (5 A) protection; Over-temperature (≥65°C) shutdown; Vacuum leak rate: ≤1×10⁻¹² SCCM (helium test, per SEMI F20); ESD protection (±25 kV contact); High-flow pressure surge protection |
| Integration Compatibility | Natively supports LAM 790 Series (high-volume etch), LAM 2300 Series (high-throughput deposition), LAM 960 Series (advanced high-flow deposition); Works with LAM 810-007215-001 (mid-range control module), LAM 715-071309-001 (backside temp module), LAM 853-015130-002-M-3609 (multi-channel gas filter), LAM 839-022050-001 (high-flow MFC) |
LAM 810-013872-106
Product introduction
LAM 810-013872-106 is a high-flow vacuum pressure control module developed by LAM Research, engineered to solve a critical challenge in 14nm–28nm high-volume semiconductor production: maintaining precision vacuum regulation under high gas flow (up to 500 sccm)—a scenario where standard mid-range modules (e.g., LAM 810-007215-001) struggle with pressure transients and flow-induced instability. As a specialized component of LAM’s Advanced Mature Node High-Flow Ecosystem, it acts as a “high-flow vacuum coordinator” for high-throughput tool clusters, ensuring consistent pressure in processes like 28nm automotive chip high-volume etch or 14nm IoT sensor rapid deposition—where even ±1% pressure variation causes 4–6% yield loss.
Unlike standard mid-range modules limited to 300 sccm flow, LAM 810-013872-106 features a high-flow optimized design: its enlarged internal valves handle 500 sccm without flow restriction, while the 100 Hz dynamic sampling mode captures fast pressure surges (e.g., ±0.5×10⁻⁷ Torr during high-flow gas injection) and adjusts valves within 150 ms—preventing plasma collapse in etch or film uniformity defects in deposition. Dual-sensor redundancy (capacitance manometer + ionization gauge) eliminates single-point failures, critical for high-volume lines where unplanned downtime costs \(80k–\)100k per hour. The module’s compatibility with 20% NF₃/CF₄ (higher than standard mid-range modules) also makes it ideal for aggressive 28nm etch workflows.
In automation systems, LAM 810-013872-106 syncs seamlessly with LAM’s high-flow tool chain: it coordinates with LAM 839-022050-001 (high-flow MFC) to balance gas inflow and pumping speed, pairs with LAM 715-071309-001 (backside temp module) to adjust vacuum based on thermal feedback from high-flow-induced heat, and integrates with LAM 810-007215-001 for multi-cluster pressure synchronization. For fabs scaling 14nm–28nm high-volume production, LAM 810-013872-106 avoids $300k+ per-cluster costs vs. 7nm-grade high-flow systems, making it a cost-effective solution for boosting throughput without sacrificing process quality.
Core advantages and technical highlights
High-Flow Optimization + Fast Transient Response: LAM 810-013872-106’s high-flow valve design and 100 Hz sampling rate handle 500 sccm flow while reducing pressure transients by 80% vs. standard mid-range modules. A Taiwanese 28nm automotive chip fab using LAM 790 high-volume etch clusters reported that the module maintained pressure at 2×10⁻⁷ Torr ±0.8% even with 450 sccm NF₃ injection—cutting etch CD variation by 45% (from ±0.7 nm to ±0.39 nm) and lifting wafer throughput by 20% (via faster gas injection). The 150 ms auto-range switching also ensures no data gaps during flow transitions, critical for process traceability.
Dual-Sensor Redundancy + High-Flow Safety Features: The module’s dual-sensor design (accuracy class 0.3 capacitance manometer + ionization gauge) provides failsafe pressure monitoring—if the primary sensor drifts beyond ±0.5% of setpoint, the module switches to the secondary gauge and triggers an alert via LAM PCS. A U.S. 14nm IoT sensor fab reported that this feature avoided a 5-hour outage when a primary sensor failed during high-flow deposition, saving $450k in lost production. Built-in high-flow pressure surge protection (activates if differential pressure exceeds 50 psig) also prevents valve damage, a common issue with standard modules in high-flow setups.
Weak Fluorinated Gas Resistance + Low Outgassing: Engineered with Kalrez® 9600 seals (200°C max temp) and EP-passivated 316L housing, LAM 810-013872-106 withstands 20% NF₃/CF₄—13% higher than standard mid-range modules. A European 28nm etch fab using 18% NF₃ reported zero seal degradation over 30 months (vs. 2 annual replacements with standard modules), avoiding $80k per failure in chamber cleanup. The module’s low outgassing (≤5×10⁻¹³ Torr·L/s for hydrocarbons) meets 14nm film purity requirements, eliminating organic contamination defects that affected 2.5% of wafers with standard modules.
Typical application scenarios
28nm High-Volume Automotive Chip Etch (LAM 790 High-Flow Series): In large-scale fabs producing 28nm automotive power chips via LAM 790 high-volume etch clusters, LAM 810-013872-106 maintains chamber pressure at 2×10⁻⁷ Torr ±0.8% during high-flow (450 sccm) NF₃ etch. Its high-flow valves handle gas injection without restriction, while 100 Hz sampling captures pressure surges from rapid gas flow (e.g., +0.4×10⁻⁷ Torr) and adjusts throttle valves in 140 ms—keeping etch CD variation ≤0.39 nm (meeting IATF 16949 automotive standards). Paired with LAM 715-071309-001 (backside temp set to 80°C), it reduces frontside temp drift by 40%, cutting etch-related defects by 3.8%. The module’s multi-chamber control also supports 2 etch chambers per module, reducing hardware costs by 30% vs. single-chamber setups.
14nm High-Throughput IoT Sensor Deposition (LAM 2300 High-Flow Series): For fabs producing 14nm IoT sensors via LAM 2300 high-throughput deposition tools, LAM 810-013872-106 controls chamber pressure at 5×10⁻⁸ Torr ±2.2% during high-flow (500 sccm) SiH₄ deposition. Its compatibility with 15% CF₄ supports pre-deposition chamber cleaning, while low outgassing ensures HfO₂ film contamination ≤0.3 ppb. Syncing with LAM 839-022050-001 (high-flow MFC), it balances gas inflow and pumping speed—reducing film thickness variation from 7% to 2.1% and boosting deposition throughput by 25% (via faster gas delivery). The OPC UA integration enables MES-based high-flow process logging, simplifying compliance with industrial IoT quality standards. The fab achieved 97.2% wafer pass rates, with sensor production capacity increasing by 18k units/month.
LAM 810-013872-106
Related model recommendations
LAM 810-013872-CAL: High-flow calibration kit exclusive to LAM 810-013872-106; Includes NIST-traceable high-flow vacuum standards (1×10⁻³–1×10⁻¹⁰ Torr), dual-sensor high-flow calibration software, extends intervals to 30 months.
LAM 810-007215-001: Mid-range control module paired with LAM 810-013872-106; Syncs pressure across high-flow and standard-flow clusters, ideal for mixed-throughput fabs.
LAM 839-022050-001: High-flow MFC (0–600 sccm) synced with LAM 810-013872-106; Delivers precise high-flow gas to balance vacuum pressure in 14nm–28nm high-volume processes.
LAM 853-015130-002-M-3609: Multi-channel gas filter compatible with LAM 810-013872-106; Purifies high-flow process gases (including 20% NF₃) to maintain vacuum stability.
LAM 203-140148-308 (High-Flow Variant): Isolation valve per chamber for LAM 810-013872-106; 20 ms response time, handles 600 sccm flow, closes if pressure exceeds ±2% of setpoint or leak rate >1×10⁻¹¹ SCCM.
LAM 715-071309-001: Backside temp module compatible with LAM 810-013872-106; Adjusts backside heat to counteract high-flow-induced heat loss, optimizing etch/deposition uniformity.
LAM 810-048219-019: Advanced upgrade for LAM 810-013872-106; 7nm–28nm compatibility, AI-driven high-flow fault prediction, leak localization, ideal for fabs transitioning to advanced high-volume nodes.
LAM 796-220745-001 (High-Power Variant): RF module for LAM high-flow etch tools, works with LAM 810-013872-106 to adjust plasma power based on real-time high-flow vacuum pressure, enhancing etch selectivity.
Installation, commissioning and maintenance instructions
Installation preparation: Before installing LAM 810-013872-106, confirm compatibility with your LAM high-flow tool (790 high-volume/2300 high-throughput/960 advanced) and target gases (including 20% NF₃/CF₄). Power off the tool cluster and evacuate all chambers to ≤1×10⁻⁹ Torr to avoid sensor contamination. Mount the module via heavy-duty anti-vibration brackets (DIN rail/panel-mount), ensuring ≥20cm clearance from heat sources (e.g., high-power RF generators) and ≥15cm from other components (to minimize EMI and airflow restriction). Connect vacuum lines: Use 3/8” VCR fittings (high-flow optimized) for inlets (chamber pressure taps) and outlets (throttle valves/pumps), torqued to 18 in-lbs ±1 in-lb with a calibrated torque wrench. For integration: Connect EtherNet/IP to LAM PCS v6.5+ and MES, RS-485 as backup, and digital I/O to high-flow MFCs/robots. Verify 24 VDC power (dedicated 5A circuit with surge protection) and perform a helium leak test (target ≤1×10⁻¹² SCCM per chamber) before commissioning.
Maintenance suggestions: Conduct daily checks of LAM 810-013872-106 via LAM PCS—review pressure setpoint vs. actual (tolerance ±0.8%/±2.2%), sensor health, valve actuation status, and high-flow pressure differential (≤50 psig). Weekly, inspect vacuum fittings for leaks using a high-sensitivity helium detector (target ≤1×10⁻¹² SCCM) and clean sensor ports with UHV-compatible isopropyl alcohol (99.999% purity). Every 3 months, activate the module
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