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Product Information Sheets

Product Information Sheets

Alumina Ribbon Ceramic

Alumina Ribbon Ceramic is a thin, flexible substrate that has a smoother native surface with fewer defects than commercially available thin ceramic sheets.  Alumina Ribbon Ceramic conducts heat efficiently and is an excellent electrical insulator even at high temperatures.

 

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Zirconia Ribbon Ceramic

In addition to being thin and flexible with a smooth, low-defect surface, Zirconia Ribbon Ceramic is also mechanically durable and ionically conductive at high temperatures.

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Additional Reading

Additional Reading

Ribbon Ceramics Technology positioned to impact next-gen batteries

Early-stage developments put Corning in a promising position to create a new generation of energy storage technology.

 

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Alumina Ribbon Ceramic and its application in 5G mmWave filter

Presented at the 32nd Electronics Packaging Symposium - a demonstration of small system integration of ultra-miniaturized, high-performance 5G mmWave filters (<1.3dB) for 28 and 39GHz on Alumina Ribbon Ceramic through collaboration with the Georgia Institute of Technology 3D Systems Packaging Research Center.

 

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Copper Nanoplates for Printing Flexible High-Temperature Conductors

In this paper, we report a thermally stable (upwards of 1300C), antioxidation and anticorrosion-printed Cu-graphene conductor on Alumina Ribbon Ceramic. High temperature stability from in-situ graphene conversion for copper and graphene interfaces and preferential stacking of copper nanoplates, distinctly suited for emerging high-temperature flexible electronics. This is a collaboration work with University at Buffalo, the State University of New York.

Aaron Sheng et. al. “Copper Nanoplates for Printing Flexible High-Temperature Conductors”, ACS Appl. Nano Mater. 2022, 5, 4028-4037

 

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Transmission Lines on Alumina Ribbon Ceramic Substrate Material for 30 to 170 GHz Wireless Applications

In this paper, electrical properties of the newly developed 40 mm thick Alumina Ribbon Ceramic substrate were characterized in the frequency band of 30-170 GHz using the microstrip ring resonator (MRR) method as well as insertion loss on both microstrip and CPW transmission lines structured for potential applications in 5G and 6G frequencies. This is a collaboration work with the Georgia Institute of Technology 3D Systems Packaging Research Center

N. Aslani-Amoli et al., "Transmission Lines on Alumina Ribbon Ceramic Substrate Material for 30 to 170 GHz Wireless Applications," 2021 IEEE 71st Electronic Components and Technology Conference (ECTC), 2021, pp. 2272-2278, doi: 10.1109/ECTC32696.2021.00356.

 

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Flexibility matters: High purity, thin, flexible alumina ribbon ceramic

In this paper, we introduce a high-performance Alumina Ribbon Ceramic and outline the ceramic's key properties. We also discuss process capabilities demonstrated on this new form factor.

Zhuang et al. (2020). “Flexibility matters: High purity, thin, flexible alumina ribbon ceramic,” Ceramic & Glass Manufacturing 1(4). Published within ACerS Bulletin 99(7): 54–58.

 

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Videos

Videos

Introduction to Corning Ribbon Ceramics

Introducing ceramics as you’ve never seen them before – thin, flexible, durable, and available in large area, continuous format.

 

 

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Alumina Ribbon Ceramic: Narrow Ribbon Demonstration

Introducing ceramics in an entirely new form factor – thin, narrow, flexible strands of high purity Alumina Ribbon Ceramic.

 

 

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Alumina Ribbon Ceramic: Thermal Tolerance Demonstration

Watch this real-time demonstration using an infrared camera to witness the high heat dissipation and high thermal shock tolerance of Corning’s Alumina Ribbon Ceramic material. The thinness and flexibility of Alumina Ribbon Ceramic enable it to bend, but not break when exposed to high temperature gradients. Therefore, the material can undergo rapid thermal shock and be run through high temperature processes at fast speeds without mechanical failure.

 

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