HOLLOW-CORE OPTICAL FIBERS

Organization Name

CORNING INCORPORATED

Inventor(s)

Paulo Clovis Dainese, Jr. of Painted Post NY (US)

Wei Jiang of Vestal NY (US)

Ming-Jun Li of Horseheads NY (US)

Xiaojun Liang of Chino Hills CA (US)

Dan Trung Nguyen of Painted Post NY (US)

Ilia Andreyevich Nikulin of Wilmington NC (US)

HOLLOW-CORE OPTICAL FIBERS - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240036252 titled 'HOLLOW-CORE OPTICAL FIBERS

Simplified Explanation

The abstract describes a hollow-core optical fiber that consists of a hollow core, a substrate with an inner surface surrounding the core, and multiple cladding elements positioned between the core and the substrate. Each cladding element includes a primary capillary that directly contacts the substrate's inner surface and has a cavity, as well as nested capillaries positioned within the cavity that also directly contact the inner surface of the primary capillary.

• The patent application describes a new type of hollow-core optical fiber.
• The fiber has a hollow core extending along its central longitudinal axis.
• It includes a substrate with a tubular shape and an inner surface surrounding the core.
• Multiple cladding elements are positioned between the core and the substrate.
• Each cladding element consists of a primary capillary that directly contacts the substrate's inner surface.
• The primary capillary has a cavity.
• Nested capillaries are positioned within the cavity of the primary capillary.
• The nested capillaries also directly contact the inner surface of the primary capillary.

Potential Applications

• High-speed data transmission: The hollow-core optical fiber can be used to transmit data at higher speeds compared to traditional solid-core fibers.
• Telecommunications: The fiber can be utilized in telecommunications networks to improve signal quality and reduce signal loss.
• Medical imaging: The fiber's unique properties can be beneficial in medical imaging applications, such as endoscopy or minimally invasive surgeries.
• Sensing and measurement: The fiber's hollow core can be used for sensing applications, such as detecting changes in temperature, pressure, or chemical composition.

Problems Solved

• Reduced signal loss: The hollow-core design minimizes signal loss, allowing for more efficient transmission of data.
• Improved signal quality: The nested capillaries within the cladding elements help maintain the integrity of the transmitted signal.
• Enhanced flexibility: The fiber's structure provides increased flexibility, making it easier to install and maneuver in various applications.
• Reduced dispersion: The design of the fiber helps minimize dispersion, ensuring that the transmitted signal remains intact and undistorted.

Benefits

• Higher data transmission speeds: The hollow-core fiber enables faster data transmission, improving overall network performance.
• Lower signal loss: The reduced signal loss results in improved signal quality and reliability.
• Increased flexibility: The fiber's flexibility allows for easier installation and integration into existing systems.
• Versatile applications: The fiber's unique properties make it suitable for a wide range of applications, including telecommunications, medical imaging, and sensing.
• Enhanced performance: The design of the fiber helps minimize dispersion and maintain signal integrity, leading to better overall performance.

Original Abstract Submitted

a hollow-core optical fiber may include a hollow core extending along a central longitudinal axis of the fiber; a substrate, the substrate having a tubular shape and an inner surface surrounding the central longitudinal axis of the fiber; and a plurality of cladding elements positioned between the hollow core and the substrate, each of the cladding elements extending in a direction parallel to the central longitudinal axis of the fiber. each of the cladding elements includes a primary capillary, the primary capillary directly contacting the inner surface of the substrate and having an inner surface defining a cavity, and a plurality of nested capillaries positioned within the cavity, each of the nested capillaries directly contacting the inner surface of the primary capillary.