Low-latency, hollow-core optical fiber with total internal reflection mode confinement

What is claimed is: 1. A method of manufacturing a low latency optical fiber waveguide structure, the method comprising: constructing an all-dielectric first optical fiber preform comprising a first dielectric bulk optical material having a first refractive index and a plurality of regions of a second dielectric material arranged in a lattice pattern and interspersed throughout the first dielectric bulk optical material, the second dielectric material having a second refractive index that is lower than the first refractive index, the plurality of regions of the second dielectric material being of subwavelength size and being cylindrical in shape with circular cross-section; drawing the all-dielectric first optical fiber preform through a fiber draw process to produce a first optical fiber; dividing the first optical fiber into a plurality of first optical fiber segments; constructing a second optical fiber preform from an arrangement of the plurality of first optical fiber segments about a hollow core region; drawing the second optical fiber preform through the fiber draw process to produce a hollow core optical fiber with an all-dielectric optical metamaterial cladding, the hollow core optical fiber being configured to guide optical energy within the hollow core region by total internal reflection at an interface between the hollow core region and the all-dielectric optical metamaterial cladding, the optical energy having a phase velocity that is greater than the speed of light in a vacuum, the all-dielectric optical metamaterial cladding being formed from the arrangement of the plurality of first optical fiber segments, the plurality of regions of the second dielectric material being arranged within the first dielectric bulk optical material such that the all-dielectric optical metamaterial exhibits resonance and has an effective refractive index that is greater than zero and less than unity at an operating wavelength of the optical fiber waveguide structure that is on a high-frequency side of the resonance of the all-dielectric optical metamaterial; and patterning an outer surface of the all-dielectric optical metamaterial cladding to form fine-patterned features configured to modify and localize electromagnetic properties of the all-dielectric optical metamaterial cladding. 2. The method of claim 1 wherein the first dielectric bulk optical material is a glass substrate and the plurality of regions of the second dielectric material is a plurality of glass rods, and wherein constructing the all-dielectric first optical fiber preform includes arranging the plurality of glass rods in the lattice pattern interspersed throughout the glass substrate. 3. The method of claim 2 wherein arranging the plurality of glass rods in the lattice pattern includes arranging the plurality of glass rods in a hexagonal array. 4. The method of claim 2 wherein arranging the plurality of glass rods in the lattice pattern includes arranging the plurality of glass rods in a rectangular array. 5. The method of claim 1 wherein drawing the all-dielectric first optical fiber preform through a fiber draw process includes drawing the all-dielectric first optical fiber preform within a zone-heated fiber draw tower. 6. The method of claim 1 wherein patterning the outer surface of the all-dielectric optical metamaterial cladding includes etching the outer surface of the all-dielectric optical metamaterial cladding. 7. The method of claim 1 wherein patterning the outer surface of the all-dielectric optical metamaterial cladding to form the fine-patterned features includes forming the fine-patterned features by lithography. 8. A method of manufacturing a low latency optical fiber waveguide structure, the method comprising: constructing an all-dielectric first optical fiber preform comprising a glass substrate having a first refractive index and a plurality of glass rods of sub-wavelength size arranged in a lattice pattern and interspersed throughout the glass substrate, the plurality of glass rods having a second refractive index that is lower than the first refractive index; drawing the all-dielectric first optical fiber preform through a fiber draw process to produce a first optical fiber; dividing the first optical fiber into a plurality of first optical fiber segments; constructing a second optical fiber preform from an arrangement of the plurality of first optical fiber segments about a hollow core region; drawing the second optical fiber preform through the fiber draw process to produce a hollow core optical fiber with an all-dielectric optical metamaterial cladding, the hollow core optical fiber being configured to guide optical energy within the hollow core region by total internal reflection at an interface between the hollow core region and the all-dielectric optical metamaterial cladding, the optical energy having a phase velocity that is greater than the speed of light in a vacuum, the all-dielectric optical metamaterial cladding being formed from the arrangement of the plurality of first optical fiber segments, the plurality of glass rods being arranged within the glass substrate such that the all-dielectric optical metamaterial exhibits resonance and has an effective refractive index that is greater than zero and less than unity at an operating wavelength of the optical fiber waveguide structure that is on a high-frequency side of the resonance of the all-dielectric optical metamaterial; and patterning an outer surface of the all-dielectric optical metamaterial cladding to form fine-patterned features configured to modify and localize electromagnetic properties of the all-dielectric optical metamaterial cladding. 9. The method of claim 8 wherein constructing the all-dielectric first optical fiber preform includes arranging the plurality of glass rods in a hexagonal lattice pattern. 10. The method of claim 8 wherein constructing the all-dielectric first optical fiber preform includes arranging the plurality of glass rods in a rectangular lattice pattern. 11. The method of claim 8 wherein patterning the outer surface of the all-dielectric optical metamaterial cladding includes etching the outer surface of the all-dielectric optical metamaterial cladding. 12. The method of claim 8 wherein patterning the outer surface of the all-dielectric optical metamaterial cladding to form the fine-patterned features includes forming the fine-patterned features by lithography.