Description
ITO CONDUCTIVE GLASS 7-10 OHM 1.1MM MAGNETRON SPUTTERED COATINGRESEARCH GRADE MATERIAL
|
|||||||||||||||||||||||||||||||
|
|||||||||||||||||||||||||||||||
|
TAILORED SOLUTIONS FOR RESEARCH
Contact our engineering team for technical support or official quotations.
EMAIL: inquiry@atomfair.com
|
|||||||||||||||||||||||||||||||
|
Manufacturer: Atomfair LLC
Brand: ATOMFAIR®
|
This document outlines mandatory handling and storage requirements for ITO conductive glass substrates to maintain surface integrity and electrical performance. Compliance with these constraints prevents contamination, mechanical damage, and degradation of the magnetron-sputtered coating.
- Storage Requirement: Store unused substrates in a dry, dust-free environment to prevent surface contamination.
- Handling Procedure: Handle substrates by edges only using cleanroom-compatible tweezers to avoid compromising the ITO coating.
- Pre-Use Cleaning: Clean the ITO surface before use to remove accumulated dust, grease, and organic contaminants from production and transport.
- Contamination Consequence: Surface contamination from improper handling can degrade electrical performance and optical transparency.
- Custom Processing Verification: For custom laser-cut or engraved pieces, verify dimensional tolerances and edge quality at the time of order.
This procedure ensures the ITO-coated surface remains free of contaminants and mechanically intact for optoelectronic applications. Follow these steps before and during substrate use to maintain specified sheet resistance and optical clarity.
Required Equipment: Cleanroom-compatible tweezers
- Inspect Substrate for Contaminants
Inspect the ITO-coated surface for visible dust, grease, or organic contaminants before initial use. - Handle by Edges
Handle the substrate by its edges using cleanroom-compatible tweezers to avoid surface contamination. - Store in Dry Environment
Store unused substrates in a dry, dust-free environment to maintain surface cleanliness.
How does the 7–10 Ω/sq sheet resistance of this ITO glass affect performance trade-offs between optical transmittance and conductivity for perovskite solar cell current collectors?
The 7–10 Ω/sq range provides a balanced trade-off for perovskite solar cells, offering stable electrical conductivity via magnetron sputtered ITO while maintaining high visible-light transmittance due to the wide bandgap. This specification is suitable for transparent electrode substrates where moderate sheet resistance supports efficient charge collection without excessive optical absorption. For applications requiring lower resistance (down to 1 Ω) or higher resistance (up to 10000 Ω), custom square resistance is available upon request.
Can this 1.1 mm ITO conductive glass be integrated with borosilicate substrates from Asahi, SCHOTT, or Corning for high-temperature thin-film deposition processes?
Yes, this product supports high-borosilicate substrates from Asahi, SCHOTT, and Corning, which are stocked regularly with both FTO and ITO conductive coatings available. The 1.1 mm thickness and borosilicate glass composition provide thermal stability suitable for high-temperature deposition processes. Custom substrate materials including quartz glass, K9 optical glass, and sapphire glass are also available upon request to match specific process compatibility requirements.
What mandatory cleaning and handling procedures are required before using this ITO glass to avoid surface contamination and ensure reliable device performance?
Cleaning is mandatory before use because ITO conductive glass surfaces may accumulate dust, grease, and organic contaminants during production, packaging, and transport. Handle substrates by the edges using cleanroom-compatible tweezers to avoid contaminating the ITO-coated side. Store unused substrates in a dry, dust-free environment to maintain surface cleanliness. For detailed cleaning protocols, consult the user guidelines provided with the shipment.
This ITO conductive glass substrate with 7–10 Ω/sq sheet resistance and 1.1 mm thickness, produced via magnetron sputtering, offers a versatile platform for optoelectronic device fabrication, with broad substrate material options and in-house precision processing services, though it requires mandatory pre-use cleaning and careful handling to maintain surface integrity.
Positive
- Broad substrate material selection: Available substrates include soda-lime float glass, ultra-white glass, borosilicate glass, quartz glass, K9 optical glass, and single-crystal sapphire, with high-borosilicate options from Asahi, SCHOTT, and Corning stocked regularly, enabling tailored optical and thermal matching for diverse research applications.
- Full-range resistance and thickness customization: Square resistance can be specified from 1 Ω to 10000 Ω and substrate thickness from 0.05 mm to 10 mm via magnetron sputtering, covering the complete specification range needed for varied research and industrial optoelectronic requirements.
Trade-offs
- Mandatory pre-use surface cleaning: ITO conductive glass surfaces may accumulate dust, grease, and organic contaminants during production, packaging, and transport; cleaning is mandatory before use to ensure reliable electrical and optical performance.
- Requires careful handling to avoid contamination: Substrates must be handled by the edges using cleanroom-compatible tweezers to prevent surface contamination of the ITO-coated side, and unused substrates must be stored in a dry, dust-free environment to maintain surface cleanliness.
Every advanced material, component, equipment, and instrument in our catalog is backed by rigorous testing. We maintain strict internal quality management frameworks and align with CE conformity metrics to deliver transparent, reproducible performance data via our public open-science repository.
To request raw batch performance data, submit formal vendor registration paperwork, or execute a fast-turnaround R&D manufacturing loop, contact us at inquiry@atomfair.com.
Item is dispatched under the Atomfair Shipping & Delivery Framework (Free worldwide shipping on orders over $59 USD). Return is governed by the Atomfair Return & Refund Policy (7-day technical return window).





