Description
ITO CONDUCTIVE GLASS 7-10 OHM 1.5MM 100 PCS MAGNETRON SPUTTEREDRESEARCH GRADE MATERIAL
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TAILORED SOLUTIONS FOR RESEARCH
Contact our engineering team for technical support or official quotations.
EMAIL: inquiry@atomfair.com
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Manufacturer: Atomfair LLC
Brand: ATOMFAIR®
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This substrate requires cleaning before use to remove surface contaminants acquired during production and transport. Unused substrates must be stored in a dry, dust-free environment to preserve surface cleanliness.
- Cleaning Requirement: Cleaning is mandatory before use as the ITO surface may accumulate dust, grease, and organic contaminants during production, packaging, and transport.
- Handling Protocol: Substrates must be handled by the edges using cleanroom-compatible tweezers to avoid contaminating the ITO-coated side.
- Storage Condition: Unused substrates should be stored in a dry, dust-free environment to maintain surface cleanliness and prevent mechanical damage.
This procedure outlines the mandatory cleaning, handling, and storage steps for ITO conductive glass substrates. Proper execution ensures surface cleanliness and optimal performance in optoelectronic applications.
Required Equipment: Cleanroom-compatible tweezers
- Clean Substrate
Clean the ITO glass substrate using the recommended protocol to remove organic residues and particulate contamination. - Handle by Edges
Handle the substrate only by the edges using cleanroom-compatible tweezers to prevent surface contamination. - Store Appropriately
Store unused substrates in a dry, dust-free environment inside a rigid protective container.
What sheet resistance and substrate thickness options are available for this ITO conductive glass, and how do these parameters influence its use in thin-film solar cells versus OLED devices?
This ITO conductive glass is offered with a standard sheet resistance of 7–10 Ω/sq at 1.5 mm thickness, but custom square resistance from 1 Ω/sq to 10000 Ω/sq and substrate thickness from 0.05 mm to 10 mm are available via magnetron sputtering. Lower sheet resistance (e.g., 7–10 Ω/sq) provides higher conductivity suitable for current collection in thin-film solar cells, while higher resistance values may be selected for capacitive or low-current applications such as OLED electrodes. Thinner substrates enable flexibility but require careful handling; thicker substrates provide mechanical rigidity for large-area devices.
Which substrate materials are available for this ITO glass, and what are the key considerations when selecting between soda-lime glass and borosilicate glass for optoelectronic applications?
Available substrate materials include soda-lime float glass, ultra-white glass, borosilicate glass (with stock high-borosilicate from Asahi, SCHOTT, and Corning), quartz glass, K9 optical glass, and sapphire glass. Soda-lime glass is cost-effective and suitable for standard applications, while borosilicate glass offers enhanced thermal stability and chemical durability for processes involving high-temperature deposition or aggressive cleaning steps. The choice depends on the specific thermal budget, optical clarity requirements, and mechanical constraints of the target device.
What are the mandatory cleaning and handling procedures for ITO conductive glass to ensure optimal surface conductivity and prevent damage?
ITO conductive glass surfaces may accumulate dust, grease, and organic contaminants during production and transport; cleaning is mandatory before use. Substrates must be handled by the edges using cleanroom-compatible tweezers to avoid contaminating the ITO-coated side. Unused substrates should be stored in a dry, dust-free environment to maintain surface cleanliness. For custom laser-cut or engraved pieces, verify dimensional tolerances and edge quality at the time of order.
This ITO conductive glass product offers broad customizability in resistance, thickness, and substrate material, making it suitable for diverse optoelectronic applications. However, mandatory cleaning before use and careful handling due to surface sensitivity and glass fragility are required.
Positive
- Extensive customization options: Square resistance from 1 to 10000 Ω, substrate thickness from 0.05 to 10 mm, and multiple substrate materials (soda-lime, borosilicate, quartz, sapphire) are available, with in-house precision laser cutting and processing services to meet exact research requirements.
- High optical transparency and conductivity: Magnetron-sputtered ITO coating provides wide bandgap optical transmission and stable low-resistivity (7-10 Ω/sq) electrical performance, essential for flat panel displays, solar cells, and optoelectronic components.
Trade-offs
- Surface contamination sensitivity: ITO surfaces may accumulate dust, grease, and organic contaminants during production and transport; mandatory cleaning is required before use to ensure performance, adding a preparatory step.
- Fragile glass substrate handling: The 1.5 mm thick glass substrates require edge handling with cleanroom tweezers and storage in dry, dust-free environments to avoid breakage and surface contamination, imposing careful handling protocols.
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).





