The present disclosure pertains to optical fibers. More particularly, the present disclosure relates to coupled-core multicore optical fibers having a plurality of cores that are doped with alkali metals and/or chlorine to achieve low attenuation and a large effective area.
The transmission capacity through single-mode optical fiber has theoretically reached its fundamental limit of around 100 Tb/s/fiber. Transmitting even 80 Tb/s in a single-mode optical fiber over transoceanic distance has proven challenging in the absence of an improved optical signal-to-noise ratio (OSNR). The actual capacity limit over about 10,000 km of a submarine single-mode optical fiber system used in a transoceanic transmission system is only about 50 Tb/s, even with advanced ultra-low-loss and low-nonlinearity optical fibers.
Spatial division multiplexing (SDM) technologies are being studied intensively to overcome this capacity limit. Transmission capacity may be increased by increasing the fiber pair count in the cable, increasing the capacity of each fiber, or increasing both. However, in submarine cables, higher fiber counts have limited practicality because a thicker and heavier cable significantly increases the cable installation cost due to the limited loading capacities of the ships that deploy the cables.
Multicore fiber (MCF) may exhibit less transmission loss when used in transoceanic applications. However, for practical use in ultra-long-haul submarine systems, the MCF should have ultra-low loss (i.e., low attenuation) to produce a high OSNR, have high spatial-mode density to increase the spatial channel count, and enable low differential group delay (DGD) between spatial modes to decrease the digital signal processing complexity. Also, the standard cladding diameter of 125 µm should be maintained so that no major modifications are needed for installation of the cable.
Thus, there is a need for new optical fibers that solve the problems described above while having satisfactory attenuation and an increased transmission capacity.
In a first aspect, either alone or in combination with any other aspect, a coupled-core multicore optical fiber includes an outer common cladding comprising a relative refractive index ΔOCC relative to pure silica; and a plurality of cores disposed in the outer common cladding, each of the plurality of cores comprising a relative refractive index ΔCi relative to pure silica and a maximum relative refractive index ACLi relative to pure silica. For the coupled-core multicore optical fiber ACLi > ΔCi > ΔOCC. Each of the plurality of cores has an effective area at 1550 nm of greater than or equal to 120 micrometers2 (µm2) and less than or equal to 160 µm2. A coupling coefficient K between adjacent cores of the plurality of cores is greater than or equal to 1 × 10-3 /m.
In a second aspect, either alone or in combination with any other aspect, a coupled-core multicore optical fiber includes an outer common cladding comprising a relative refractive index ΔOCC relative to pure silica; and a plurality of cores disposed in the outer common cladding, each of the plurality of cores comprising an inner core portion comprising a relative refractive index ΔCi relative to pure silica and a maximum relative refractive index ACLi relative to pure silica. For the coupled-core multicore optical fiber ACLi > ΔCi > ΔOCC. Each of the inner core portions comprises greater than or equal to 0.02 wt.% and less than or equal to 0.15 wt.% fluorine. A distance between centers of an adjacent two of the plurality of cores is greater than or equal to 20 micrometers (µm) and less than or equal to 40 µm. A coupling coefficient K between adjacent cores in the plurality of cores is greater than or equal to 1 × 10-3 /m.
In a third aspect, either alone or in combination with any other aspect, a distance between centers of an adjacent two of the plurality of cores is greater than or equal to 45 µm and less than or equal to 65 µm.
In a fourth aspect, either alone or in combination with the third aspect, a crosstalk between the plurality of cores is greater than or equal to -50 decibels (dB) per kilometer.
In a fifth aspect, either alone or in combination with any other aspect, the coupled-core multicore optical fiber includes greater than or equal to 2 and less than or equal to 6 of the cores.
In a sixth aspect, either alone or in combination with the fifth aspect, the coupled-core multicore optical fiber includes 3 sets of 3 of the cores.
In a seventh aspect, either alone or in combination with any other aspect, a cable cutoff wavelength of each of the plurality of cores of the optical fiber is greater than or equal to 1200 nanometers (nm) and less than or equal to 1520 nm.
In an eighth aspect, either alone or in combination with the seventh aspect, an average bend loss of the plurality of cores of the optical fiber at a wavelength of 1550 nm measured on a mandrel having a diameter of 20 millimeters (mm) is greater than or equal to 0.01 decibels per turn (dB/turn) and less than or equal to 1 dB/turn.
In a ninth aspect, either alone or in combination with any other aspect, an average bend loss of the plurality of cores of the optical fiber at a wavelength of 1550 nm measured on a mandrel having a diameter of 30 mm is greater than or equal to 0.001 decibels per turn (dB/turn) and less than or equal to 0.03 dB/turn.
In a tenth aspect, either alone or in combination with any other aspect, a minimum distance between a center of one of the plurality of cores to an adjacent edge of the optical fiber along a line formed by a centerpoint of the optical fiber, the center of the one of the plurality of cores, and the adjacent edge in a plane perpendicular to a long axis of the coupled-core multicore optical fiber is greater than or equal to 30 µm and less than or equal to 50 µm.
In an eleventh aspect, either alone or in combination with any other aspect, each of the plurality of cores comprises an inner core portion surrounded by an inner cladding portion.
In a twelfth aspect, either alone or in combination with any other aspect, each inner cladding portion comprises a relative refractive index ΔICi, the inner core portion comprises the ACLi, and ΔCLi > ACi > ΔICi > ΔOCC.
In a thirteenth aspect, either alone or in combination with any other aspect, each of the plurality of cores comprises an inner cladding portion and an inner core portion corresponding to the inner cladding portion, each inner cladding portion surrounding the corresponding inner core portion.
It is to be understood that both the foregoing general description and the following detailed description are merely exemplary and are intended to provide an overview or framework to understand the nature and character of the claims. Additional features and advantages will be set forth in the detailed description which follows, and in part will be readily apparent to those skilled in the art from the description or recognized by practicing the embodiments as described in the written description and claims hereof, as well as the appended drawings.
The accompanying drawings are included to provide a further understanding, and are incorporated in and constitute a part of this specification. The drawings are illustrative of selected aspects of the present disclosure, and together with the description serve to explain principles and operation of methods, products, and compositions embraced by the present disclosure, in which:
In this specification and in the claims which follow, reference will be made to a number of terms which shall be defined to have the following meanings:
As used herein, the term “about” means that amounts, sizes, formulations, parameters, and other quantities and characteristics are not and need not be exact, but may be approximate and/or larger or smaller, as desired, reflecting tolerances, conversion factors, rounding off, measurement error and the like, and other factors known to those of skill in the art. When the term “about” is used in describing a value or an end-point of a range, the disclosure should be understood to include the specific value or end-point referred to. Whether or not a numerical value or end-point of a range in the specification recites “about,” the numerical value or end-point of a range is intended to include two embodiments: one modified by “about,” and one not modified by “about.” It will be further understood that the end-points of each of the ranges are significant both in relation to the other end-point, and independently of the other end-point.
A multicore optical fiber, also referred to as a multicore fiber or “MCF”, is considered for the purposes of the present disclosure to include two or more core fibers disposed within a cladding matrix. Each core fiber can be considered as having a higher index core surrounded by a lower index cladding matrix defining a common cladding. Optionally, each core fiber can include a higher index core surrounded by one or more lower index inner claddings disposed between each core and the cladding matrix of the common cladding. As used herein, the term “inner core portion” refers to the higher index core. That is, a core fiber may include an inner core portion and optionally one or more lower index inner claddings.
“Radial position” and/or “radial distance,” when used in reference to the radial coordinate “r” refers to radial position relative to the centerline (r = 0) of each individual core in a multicore optical fiber. “Radial position” and/or “radial distance,” when used in reference to the radial coordinate “R” refers to radial position relative to the centerline (R = 0, central fiber axis) of the multicore optical fiber. The length dimension “micrometer” may be referred to herein as micron (or microns) or µm.
The “refractive index profile” is the relationship between refractive index or relative refractive index and radial distance r from the core’s centerline for each core fiber of the multicore optical fiber. For relative refractive index profiles depicted herein as having step boundaries between adjacent core and cladding regions, normal variations in processing conditions may result in step boundaries at the interface of adjacent regions that are not sharp. It is to be understood that although boundaries of refractive index profiles may be depicted herein as step changes in refractive index, the boundaries in practice may be rounded or otherwise deviate from perfect step function characteristics. It is further understood that the value of the relative refractive index may vary with radial position within the core region and/or any of the cladding regions. When relative refractive index varies with radial position in a particular region of the fiber (core region and/or any of the cladding regions), it may be expressed in terms of its actual or approximate functional dependence or in terms of an average value applicable to the region. Unless otherwise specified, if the relative refractive index of a region (core region and/or any of the inner and/or common cladding regions) is expressed as a single value, it is understood that the relative refractive index in the region is constant, or approximately constant, and corresponds to the single value or that the single value represents an average value of a non-constant relative refractive index dependence with radial position in the region. Whether by design or a consequence of normal manufacturing variability, the dependence of relative refractive index on radial position may be sloped, curved, or otherwise non-constant.
The “relative refractive index” or “relative refractive index percent” as used herein with respect to multicore optical fibers and fiber cores of multicore optical fibers is defined according to equation (1):
where n(r) is the refractive index at the radial distance r from the core’s centerline at a wavelength of 1550 nm, unless otherwise specified, and nc is 1.444, which is the refractive index of undoped silica glass at a wavelength of 1550 nm. As used herein, the relative refractive index is represented by Δ (or “delta”) or Δ% (or “delta %) and its values are given in units of “%” or “%Δ”, unless otherwise specified. Relative refractive index may also be expressed as Δ(r) or Δ(r)%. When the refractive index of a region is less than the reference index nc, the relative refractive index is negative and can be referred to as a trench. When the refractive index of a region is greater than the reference index nc, the relative refractive index is positive and the region can be said to be raised or to have a positive index.
The average relative refractive index of a region of the multicore optical fiber can be defined according to equation (2):
where rinner is the inner radius of the region, router is the outer radius of the region, and Δ(r) is the relative refractive index of the region.
The term “α-profile” (also referred to as an “alpha profile”) refers to a relative refractive index profile Δ(r) that has the following functional form (3):
where ro is the point at which Δ(r) is maximum, r1 is the point at which Δ(r) is zero, and r is in the range ri ≤ r ≤ rf, where ri is the initial point of the α-profile, rf is the final point of the α-profile, and α is a real number. In some embodiments, examples shown herein can have a core alpha of 1 ≤ α ≤ 100. In practice, an actual optical fiber, even when the target profile is an alpha profile, some level of deviation from the ideal configuration can occur. Therefore, the alpha parameter for an optical fiber may be obtained from a best fit of the measured index profile, as is known in the art.
The term “graded-index profile” refers to an α-profile, where α< 10. The term “step-index profile” refers to an α-profile, where α ≥ 10.
The “effective area” can be defined as (4):
where f(r) is the transverse component of the electric field of the guided optical signal and r is radial position in the fiber. “Effective area” or “Aeff” depends on the wavelength of the optical signal. Specific indication of the wavelength will be made when referring to “Effective area” or “Aeff” herein. Effective area is expressed herein in units of “µm2”, “square micrometers”, “square microns” or the like.
Unless otherwise noted herein, optical properties (such as dispersion, dispersion slope, etc.) are reported for the LP01 mode.
“Chromatic dispersion,” herein referred to as “dispersion” unless otherwise noted, of an optical fiber is the sum of the material dispersion, the waveguide dispersion, and the intermodal dispersion. “Material dispersion” refers to the manner in which the refractive index of the material used for the optical core affects the velocity at which different optical wavelengths propagate within the core. “Waveguide dispersion” refers to dispersion caused by the different refractive indices of the core and cladding of the optical fiber. In the case of single mode waveguide fibers, the inter-modal dispersion is zero. Dispersion values in a two-mode regime assume intermodal dispersion is zero. The zero-dispersion wavelength (λo) is the wavelength at which the dispersion has a value of zero. Dispersion slope is the rate of change of dispersion with respect to wavelength. Dispersion and dispersion slope are reported herein at a wavelength of 1310 nm or 1550 nm, as noted, and are expressed in units of ps/nm/km and ps/nm2/km, respectively. Chromatic dispersion is measured as specified by the IEC 60793-1-42:2013 standard, “Optical fibres - Part 1-42: Measurement methods and test procedures - Chromatic dispersion.”
The cutoff wavelength of an optical fiber is the minimum wavelength at which the optical fiber will support only one propagating mode. For wavelengths below the cutoff wavelength, multimode transmission may occur and an additional source of dispersion may arise to limit the fiber’s information carrying capacity. Cutoff wavelength will be reported herein as a cable cutoff wavelength. The cable cutoff wavelength is based on a 22-meter cabled fiber length as specified in TIA-455-80: FOTP-80 IEC-60793-1-44 Optical Fibres — Part 1-44: Measurement Methods and Test Procedures — Cut—off Wavelength (21 May 2003), by Telecommunications Industry Association (TIA).
The “theoretical cutoff wavelength”, or “theoretical fiber cutoff”, or “theoretical cutoff”, for a given higher-order mode, is the wavelength above which guided light cannot propagate in that higher-order mode. According to an aspect of the present disclosure, the cutoff wavelength refers to the cutoff wavelength of the LP11 mode. A mathematical definition can be found in Single Mode Fiber Optics, Jeunhomme, pp. 39-44, Marcel Dekker, New York, 1990, wherein the theoretical fiber cutoff is described as the wavelength at which the mode propagation constant becomes equal to the plane wave propagation constant in the common cladding. This theoretical wavelength is appropriate for an infinitely long, perfectly straight fiber that has no diameter variations.
The bend resistance of an optical fiber, expressed as “bend loss” herein, can be gauged by induced attenuation under prescribed test conditions as specified by the IEC-60793-1-47:2017 standard, “Optical fibres - Part 1-47: Measurement methods and test procedures -Macrobending loss.” For example, the test condition can entail deploying or wrapping the fiber one or more turns around a mandrel of a prescribed diameter, e.g., by wrapping 1 turn around either a 15 mm, 20 mm, or 30 mm or similar diameter mandrel (e.g. “1×15 mm diameter bend loss” or the “1×20 mm diameter bend loss” or the “1×30 mm diameter bend loss”) and measuring the increase in attenuation per turn.
The term “attenuation,” as used herein, is the loss of optical power as the signal travels along the optical fiber. Attenuation is measured as specified by the IEC 60793-1-40:2019 standard entitled “Optical fibres - Part 1-40: Attenuation measurement methods.”
As used herein, the multicore optical fiber can include a plurality of cores, wherein each core can be defined as an ith core (i.e., 1st, 2nd, 3rd, 4th, etc). Each ith core can have an outer radius rCi, an average relative refractive index ΔCi, and a maximum relative refractive index ACiMAX. Each ith core is disposed within a cladding matrix of the multicore optical fiber, which defines an outer common cladding of the multicore optical fiber. The outer common cladding includes a relative refractive index ΔOCC and an outer radius Rocc. Optionally, an inner common cladding may be disposed within the outer common cladding of the multicore optical fiber. The inner common cladding includes a relative refractive index ΔICC and an outer radius RICC. In embodiments in which the inner common cladding is not present, the refractive index of the outer common cladding is typically referred to as ΔCC and the outer radius of the common cladding is typically referred to as Rec.
Optionally, each ith core includes a corresponding ith centerline region that includes an outer radius rCLi and maximum relative refractive index ΔCLi. Thus, i=1 refers to a first core having an outer radius rC1 and relative refractive index ΔCl and a centerline region having an outer radius rCL1 and maximum relative refractive index ΔCL1. When i=2, the core is referred to as a second core having an outer radius rC2 and relative refractive index ΔC2. When the second core includes a corresponding ith centerline region, where i=2, it is referred to as the second centerline region and includes an outer radius rCL2 and maximum relative refractive index ΔCL2. Each additional ith core and optional ith inner cladding is referred to as a third core and optional centerline region (i=3), a fourth core and optional fourth centerline region (i=4), etc... The number assigned to each ith core is used to distinguish one core from another for the purposes of discussion and does not necessarily imply any particular ordering of the cores.
Optionally, each ith core is surrounded by a corresponding ith inner cladding having a width δrICi and a relative refractive index ΔICi. Thus, i=1 refers to a first core having an outer radius rC1 and relative refractive index ΔC1. When the first core is surrounded by a corresponding ith inner cladding, where i=1, it is referred to as the first inner cladding and has a width δrICl and a relative refractive index ΔIC1. When i=2, the core is referred to as a second core having an outer radius rC2 and relative refractive index ΔC2. When the second core is surrounded by a corresponding ith inner cladding, where i=2, it is referred to as the second inner cladding and includes a width δrIC2 and a relative refractive index ΔIC2. Each additional ith core and optional ith inner cladding is referred to as a third core and optional third inner cladding (i=3), a fourth core and optional fourth inner cladding (i=4), etc... The number assigned to each ith core is used to distinguish one core from another for the purposes of discussion and does not necessarily imply any particular ordering of the cores.
According to one aspect of the present disclosure, the core forms the central portion of each core fiber within the multicore optical fiber and is substantially cylindrical in shape. In addition, when present, the surrounding inner cladding region is substantially annular in shape. Annular regions may be characterized in terms of an inner radius and an outer radius. Radial positions r refer herein to the outermost radii of the region (e.g., the core, the centerline region, the inner cladding region, etc...). When two regions are directly adjacent to each other, the outer radius of the inner of the two regions coincides with the inner radius of the outer of the two regions. For example, in embodiments in which an inner cladding region surrounds and is directly adjacent to a core region, the outer radius of the core region coincides with the inner radius of the inner cladding region and the outer radius of the inner cladding region is separated from the inner radius of the inner cladding region by the width δrIC.
An “up-dopant” is herein considered to be a substance added to the glass of the component being studied that has a propensity to raise the refractive index relative to pure undoped silica. A “down-dopant” is herein considered to be a substance added to the glass of the component being studied that has a propensity to lower the refractive index relative to pure undoped silica. Examples of up-dopants include GeO2 (germania), Al2O3, P2O5, TiO2, Cl, Br, and alkali metal oxides, such as K2O, Na2O, Li2O, CS2O, Rb2O, and mixtures thereof. Examples of down-dopants include fluorine and boron.
The term “crosstalk” in a multi-core fiber is a measure of how much power leaks from one core to another, adjacent core. As used herein, the term “adjacent core” refers to the core that is nearest to the reference core. In embodiments, all cores may be equally spaced from one another, meaning that all cores are adjacent one another. In other embodiments, the cores may not be equally spaced from one another, meaning that some cores will be spaced further from the reference core than adjacent cores are spaced from the reference core. The crosstalk can be determined based on the coupling coefficient, which depends on the refractive index profile design of the core, the distance between the two adjacent cores, the structure of the cladding surrounding the two adjacent cores, and Δβ, which depends on a difference in propagation constant β values between the two adjacent cores. For two adjacent cores with power P1 launched into the first core, then the power P2 coupled from the first core to the second core can be determined from coupled mode theory using the following equation (5):
where < > denotes the average, L is fiber length, K is the coupling coefficient between the electric fields of the two cores, ΔL is the length of the fiber, Lc is the correlation length, and g is given by the following equation (6):
where Δβ is the mismatch in propagation constants between the LP01 modes in the two adjacent cores when they are isolated. The crosstalk (in dB) is then determined using the following equation (7):
The crosstalk between the two adjacent cores increases linearly with fiber length in the linear scale (equation (5)) but does not increase linearly with fiber length in the dB scale (equation (7)). As used herein, crosstalk performance is referenced to a 1 km length L of optical fiber. However, crosstalk performance can also be represented with respect to alternative optical fiber lengths, with appropriate scaling. For optical fiber lengths other than 1 km, the crosstalk between cores can be determined using the following equation (8):
For example, for a 10 km length of optical fiber, the crosstalk can be determined by adding “10 dB” to the crosstalk value for a 1 km length optical fiber. For a 100 km length of optical fiber, the crosstalk can be determined by adding “20 dB” to the crosstalk value for a 1 km length of optical fiber. For long-haul transmission in an uncoupled-core multicore fiber, the crosstalk should be less than or equal to -50 dB, less than or equal to -60 dB, or even less than or equal to -70 dB. For long-haul transmission in a coupled-core multicore fiber, the crosstalk is greater than or equal to -40 dB, greater than or equal to -30 dB, greater than or equal to -20 dB, or even greater than or equal to -10 dB. If the coupling coefficient is large enough, the power can couple back and forth periodically between two cores along the fiber. In this case, the crosstalk does not scale with the fiber length, but changes periodically. The crosstalk could even reach 100%, or zero dB.
Techniques for determining crosstalk between cores in a multicore optical fiber can be found in M. Li, et al., “Coupled Mode Analysis of Crosstalk in Multicore Fiber with Random Perturbations,” in Optical Fiber Communication Conference, OSA Technical Digest (online), Optical Society of America, 2015, paper W2A.35, and Shoichiro Matsuo, et al., “Crosstalk behavior of cores in multi-core fiber under bent condition,” IEICE Electronics Express, Vol. 8, No. 6, p. 385-390, published Mar. 25, 2011 and Lukasz Szostkiewicz, et al., “Cross talk analysis in multicore optical fibers by supermode theory,” Optics Letters, Vol. 41, No. 16, p. 3759-3762, published Aug. 15, 2016, the contents of which are all incorporated herein by reference in their entirety.
The phrase “coupling coefficient” K, as used herein, is related to the overlap of electric fields when the two cores are close to each other. The square of the coupling coefficient, K2, is related to the average power in core m as influenced by the power in other cores in the multicore optical fiber. The “coupling coefficient” can be estimated using the coupled power theory, with the methods disclosed in M. Koshiba, K. Saitoh, K. Takenaga, and S. Matsuo, “Analytical Expression of Average Power-Coupling Coefficients for Estimating Intercore Crosstalk in Multicore Fibers,” IEEE Photonics J., 4(5), 1987-95 (2012); and T. Hayashi, T. Sasaki, E. Sasaoka, K. Saitoh, and M. Koshiba, “Physical Interpretation of Intercore Crosstalk in Multicore Fiber: Effects of Macrobend, Structure Fluctuation, and Microbend,” Optics Express, 21(5), 5401-12 (2013), the contents of which are incorporated by reference herein in their entirety.
Directional terms as used herein - for example up, down, right, left, front, back, top, bottom - are made only with reference to the figures as drawn and are not intended to imply absolute orientation.
Unless otherwise expressly stated, it is in no way intended that any method set forth herein be construed as requiring that its steps be performed in a specific order, nor that with any apparatus specific orientations be required. Accordingly, where a method claim does not actually recite an order to be followed by its steps, or that any apparatus claim does not actually recite an order or orientation to individual components, or it is not otherwise specifically stated in the claims or description that the steps are to be limited to a specific order, or that a specific order or orientation to components of an apparatus is not recited, it is in no way intended that an order or orientation be inferred, in any respect. This holds for any possible non-express basis for interpretation, including: matters of logic with respect to arrangement of steps, operational flow, order of components, or orientation of components; plain meaning derived from grammatical organization or punctuation, and; the number or type of embodiments described in the specification.
As used herein, the singular forms “a,” “an” and “the” include plural referents unless the context clearly dictates otherwise. Thus, for example, reference to “a” component includes aspects having two or more such components, unless the context clearly indicates otherwise.
The present description provides a coupled-core multicore optical fiber having a plurality of cores that are doped with alkali metals or chlorine to achieve low attenuation and a large effective area. The cores may be embedded in an inner (or common inner) cladding region that may be fluorine doped, which may be surrounded by an outer (or common outer) cladding, which may also be fluorine doped, with a total diameter of 125 µm or greater, such as for example about 200 µm. For instance, the total diameter may be greater than or equal to 125 µm and less than or equal to 180 µm. In other embodiments, the cores may be doped with chlorine, either with the alkali metals described above or without the alkali metals.
Coupled-core multicore optical fiber is distinct from uncoupled-core multicore optical fiber. In the uncoupled variety, the cores are meant to be spatially isolated from one another to limit crosstalk between the cores. Coupled-core multicore optical fibers, however, take advantage of crosstalk between the cores. As a result, the distance between cores (i.e., the “core pitch”) can be much smaller in coupled-core multicore optical fibers than in uncoupled-core multicore optical fibers, allowing for more cores per unit area of the cross section of the multicore optical fiber.
Referring now to
In embodiments, the multicore optical fiber can have a circular cross-section shape with seven cores, wherein six of the cores are at the vertices of a hexagon and the seventh core is at the center of the circular cross-section. In some embodiments, the multicore optical fiber of the present disclosure can have a circular cross-section and the cores can be arranged in a 2 × 2 configuration. In still other embodiments, the multicore optical fiber of the present disclosure can have a circular cross-section and the number of cores can be between 10 and 20. The coupled-core multicore optical fiber 110 can have N number of total cores Ci, wherein i=1 ... N and N is at least 2. According to one aspect of the present disclosure, the total number N of cores Ci in the multicore optical fiber 10 is from 2 to 20, 2 to 18, 2 to 16, 2 to 12, 2 to 10, 2 to 8, 2 to 6, 2 to 4, 2 to 3, 4 to 20, 4 to 18, 4 to 16, 4 to 12, 4 to 10, 4 to 8, 4 to 6, 6 to 20, 6 to 18, 6 to 16, 6 to 12, 6 to 10, 6 to 8, 8 to 20, 8 to 18, 8 to 16, 8 to 12, 8 to 10, 10 to 20, 10 to 18, 10 to 16, 10 to 12, 12 to 20, 12 to 18, or 12 to 16. For example, the total number N of cores Ci in the multicore optical fiber 10 can be 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, or any total number N of cores Ci between any of these values. The total number N of cores Ci can be even or odd and can be arranged in any pattern within the cladding matrix 14, non-limiting examples of which include a 2 × 2 pattern (or multiples thereof; see, e.g.,
Referring now to
Referring now to
In embodiments, the radius RICC of the inner common cladding 20 may be greater than or equal to 20 µm and less than or equal to 45 µm or greater than or equal to 25 µm and less than or equal to 40 µm or greater than or equal to 20 µm and less than or equal to 30 µm or greater than or equal to 30 µm and less than or equal to 35 µm or even greater than or equal to 35 µm and less than or equal to 45 µm. It should be understood that the radius RICC may be within a range formed from any one of the lower bounds for the radius RICC and any one of the upper bounds of the radius RICC described herein.
In the same or alternative embodiments, the radius rCi of each core Cimay be greater than or equal to 3 µm and less than or equal to 10 µm or greater than or equal to 4 µm and less than or equal to 9 µm or greater than or equal to 4 µm and less than or equal to 8 µm or greater than or equal to 4 µm and less than or equal to 7 µm or greater than or equal to 4 µm and less than or equal to 6 µm or greater than or equal to 4 µm and less than or equal to 5 µm or greater than or equal to 5 µm and less than or equal to 7 µm or even greater than or equal to 6 µm and less than or equal to 7 µm. It should be understood that the radius rCi may be within a range formed from any one of the lower bounds for the radius rCi and any one of the upper bounds of the radius rCi described herein.
Still referring to
Referring now to
In the same or alternative embodiments, the radius rICi of each inner cladding ICi (depicted in
While
In embodiments, the core Ci may include alkali-doped silica glass, with the inner cladding ICi doped with fluorine to provide an index differential between the core and the common cladding layer. The alkali-doped silica glass of the core Ci may include for example, concentrations of alkali metal oxide from 20 ppm to 1000 ppm, from 50 ppm to 600 ppm, or even from 110 ppm to 200 ppm. The alkali may include, for example, oxides of sodium, potassium, rubidium, lithium, cesium, or a combination of two or more of these. In some embodiments, the core comprises more than one alkali doped in the core.
In embodiments, the silica-based glass of each of the plurality of cores Ci may comprise silica-based glass doped with one or more alkali metal oxides selected from K2O, Na2O, Li20, Cs2O, Rb2O, and mixtures thereof. Without intending to be bound by any particular theory, it is believed that including alkali metal oxides as dopants in each of the plurality of cores Ci may reduce the viscosity of the glass at elevated temperatures which, in turn, aids relaxation by mitigating the development of stress in the glass during drawing. The mitigation of stress in the glass decreases the attenuation of the glass. However, if the glass is doped with too much alkali, the concentration fluctuation contribution to Rayleigh scattering may be increased, leading to an increased observed attenuation. Further, in embodiments in which the silica-based glass is co-doped with both alkali metal oxides and germania, undesirable crystallization may occur.
In embodiments including the alkali metal oxide, the concentration of the alkali metal oxide in each of the plurality of cores Ci may be greater than or equal to 20 ppm and less than or equal to 1000 ppm by weight (0.1 wt.%) of each of the plurality of cores Ci. For example, the concentration of alkali metal oxide may be greater than or equal to 50 ppm (0.005 wt.%) and less than or equal to 950 ppm (0.095 wt.%) or greater than or equal to 100 ppm (0.01 wt.%) and less than or equal to 900 ppm (0.09 wt.%) or greater than or equal to 150 ppm (0.015 wt.%) and less than or equal to 850 ppm (0.085 wt.%) or greater than or equal to 200 ppm (0.02 wt.%) and less than or equal to 800 ppm (0.08 wt.%) or greater than or equal to 250 ppm (0.025 wt.%) and less than or equal to 750 ppm (0.075 wt.%) or greater than or equal to 300 ppm (0.03 wt.%) and less than or equal to 700 ppm (0.07 wt.%) or greater than or equal to 350 ppm (0.035 wt.%) and less than or equal to 650 ppm (0.065 wt.%) or greater than or equal to 400 ppm (0.04 wt.%) and less than or equal to 600 ppm (0.06 wt.%) or even greater than or equal to 450 ppm (0.045 wt.%) and less than or equal to 550 ppm (0.055 wt.%). It should be understood that the amount of alkali metal oxide in the silica-based glass may be within a range formed from any one of the lower bounds for alkali metal oxide and any one of the upper bounds of alkali metal oxide described herein.
In the same or different embodiments, the silica-based glass of each of the plurality of cores Ci may comprise silica-based glass doped with fluorine. Fluorine is a down-dopant that reduces the index of refraction of each of the plurality of cores Ci relative to undoped silica. In some embodiments, the concentration of fluorine in each of the plurality of cores Ci is greater than or equal to 0.02 wt.% and less than or equal to 0.15 wt.% by weight of the fully formed core Ci. For example, the concentration of fluorine in each of the plurality of cores Ci may be greater than or equal to 0.04 wt.% and less than or equal to 0.13 wt.%, greater than or equal to 0.06 wt.% and less than or equal to 0.11 wt.%, or even greater than or equal to 0.08 wt.% and less than or equal to 0.09 wt.%. It should be understood that the amount of fluorine in the compositions may be within a range formed from any one of the lower bounds for fluorine and any one of the upper bounds of fluorine described herein.
In embodiments, the silica-based glass of each of the plurality of cores Ci may comprise silica-based glass doped with chlorine. Chlorine is an up-dopant that increases the index of refraction of each of the plurality of cores Ci relative to undoped silica. In some embodiments, the concentration of the chlorine in each of the plurality of cores Ci is greater than or equal to 1 wt.% and less than or equal to 7 wt.% by weight of each of the plurality of cores Ci. For example, the concentration of chlorine may be greater than or equal to 1.5 wt.% and less than or equal to 7 wt.%, greater than or equal to 2 wt.% and less than or equal to 6.5 wt.%, greater than or equal to 2.5 wt.% and less than or equal to 6 wt.%, greater than or equal to 3 wt.% and less than or equal to 5.5 wt.%, greater than or equal to 3.5 wt.% and less than or equal to 5 wt.%, or even greater than or equal to 4 wt.% and less than or equal to 4.5 wt.%. It should be understood that the amount of chlorine in the compositions may be within a range formed from any one of the lower bounds for chlorine and any one of the upper bounds of chlorine described herein.
In embodiments, the silica-based glass of each of the plurality of cores Ci may comprise silica-based glass doped with phosphorus. Phosphorus is an up-dopant that increases the index of refraction of each of the plurality of cores Ci relative to undoped silica. In embodiments in which the phosphorus is present, the concentration of phosphorus in each of the plurality of cores Ci is greater than 0 wt.% and less than or equal to 2 wt.% or greater than or equal to 0.2 wt.% and less than or equal to 1.8 wt.% or greater than or equal to 0.4 wt.% and less than or equal to 1.6 wt.% or greater than or equal to 0.6 wt.% and less than or equal to 1.4 wt.% or greater than or equal to 0.8 wt.% and less than or equal to 1.2 wt.% or even greater than or equal to 1 wt.% and less than or equal to 1.1 wt.%. It should be understood that the amount of phosphorus in the compositions may be within a range formed from any one of the lower bounds for phosphorus and any one of the upper bounds of phosphorus described herein.
In embodiments, the silica-based glass of each of the plurality of cores Ci may comprise silica-based glass doped with phosphorus and one or more alkali metal oxides. In embodiments, the silica-based glass of each of the plurality of cores Ci may comprise silica-based glass doped with phosphorus and chlorine. In embodiments in which both phosphorus and chlorine are present, the concentration of chlorine may be greater than or equal to 1 wt.% to less than or equal to 6.5 wt.%, and the concentration of phosphorus may be greater than or equal to 0.5 wt.% and less than or equal to 2 wt.%. For example, the concentration of chlorine may be greater than or equal to 1.5 wt.% and less than or equal to 6 wt.% or greater than or equal to 2 wt.% and less than or equal to 5.5 wt.% or greater than or equal to 2.5 wt.% and less than or equal to 5 wt.% or greater than or equal to 3 wt.% and less than or equal to 4.5 wt.% or even greater than or equal to 3.5 wt.% and less than or equal to 4 wt.%. It should be understood that the amount of chlorine in the compositions may be within a range formed from any one of the lower bounds for chlorine and any one of the upper bounds of chlorine described herein. Further, the concentration of phosphorus may be greater than or equal to 0.6 wt.% and less than or equal to 1.9 wt.% or greater than or equal to 0.7 wt.% and less than or equal to 1.8 wt.% or greater than or equal to 0.8 wt.% and less than or equal to 1.7 wt.% or greater than or equal to 0.9 wt.% and less than or equal to 1.6 wt.% or greater than or equal to 1 wt.% and less than or equal to 1.5 wt.% or greater than or equal to 1.1 wt.% and less than or equal to 1.4 wt.% or even greater than or equal to 1.2 wt.% and less than or equal to 1.3 wt.%. It should be understood that the amount of phosphorus in the compositions may be within a range formed from any one of the lower bounds for phosphorus and any one of the upper bounds of phosphorus described herein.
When present, the inner common cladding 20 may comprise silica-based glass. In embodiments, the inner common cladding 20 may consist of, or consist essentially of, silica-based glass. In embodiments, the silica-based glass of the inner common cladding 20 may comprise a down-dopant such that the inner common cladding 20 has an index of refraction lower than that of each of the plurality of cores Ci. In embodiments, the down-dopant is fluorine.
In some embodiments, inner common cladding 20, when present, may include fluorine in a concentration greater than or equal to 0.5 wt.% and less than or equal to 1.8 wt.%. For example, the inner common cladding 20 may include fluorine in a concentration greater than or equal to 0.6 wt.% and less than or equal to 1.7 wt.% or greater than or equal to 0.7 wt.% and less than or equal to 1.6 wt.% or greater than or equal to 0.8 wt.% and less than or equal to 1.5 wt.% or greater than or equal to 0.9 wt.% and less than or equal to 1.4 wt.% or greater than or equal to 1 wt.% and less than or equal to 1.3 wt. % or even greater than or equal to 1.1 wt. % and less than or equal to 1.2 wt.% It should be understood that the amount of fluorine in the compositions may be within a range formed from any one of the lower bounds for fluorine and any one of the upper bounds of fluorine described herein.
The outer common cladding 21 may comprise silica-based glass. In embodiments, the outer common cladding 21 may consist of, or consist essentially of, silica-based glass. In embodiments, the silica-based glass of the outer common cladding 21 may comprise a down-dopant, such as fluorine, which reduces the index of refraction such that the outer common cladding 21 has an index of refraction lower than that of each of the plurality of cores C1 and higher than that of the inner common cladding 20. In other embodiments, each of the plurality of cores C1 may be undoped, the inner common cladding 20 may include a down-dopant, and the outer common cladding may include an up-dopant. Exemplary up-dopants include, but are not limited to, chlorine, germania, and titania.
In some embodiments, the concentration of fluorine in the silica-based glass of the outer common cladding 21 is greater than or equal to 0.3 wt.% and less than or equal to 1.6 wt.% of the fully formed outer common cladding 21. For example, the concentration of fluorine may be greater than or equal to 0.4 wt.% and less than or equal to 1.5 wt.% or greater than or equal to 0.7 wt.% and less than or equal to 1.4 wt.% or greater than or equal to 0.8 wt.% and less than or equal to 1.3 wt.% or greater than or equal to 0.9 wt.% and less than or equal to 1.2 wt.% or even greater than or equal to 1 wt.% and less than or equal to 1.1 wt.%. It should be understood that the amount of fluorine in the compositions may be within a range formed from any one of the lower bounds for fluorine and any one of the upper bounds of fluorine described herein.
Still referring to
To minimize radiation or tunneling loss, the minimum distance DCi-116 from the centers CLi of each of the plurality of cores Ci to the outer surface 116 of the coupled-core multicore optical fiber 110 may be greater than or equal to 30 µm in a plane perpendicular to the long axis of the coupled-core multicore optical fiber (i.e., the X-Y plane of the coordinate axes depicted in the figures), such as greater than or equal to 30 µm and less than or equal to 50 µm. For example, the distance DCi-116 may be greater than or equal to 32 µm and less than or equal to 48 µm, greater than or equal to 34 µm and less than or equal to 46 µm, greater than or equal to 34 µm and less than or equal to 44 µm, greater than or equal to 36 µm and less than or equal to 42 µm, greater than or equal to 30 µm and less than or equal to 40 µm, greater than or equal to 32 µm and less than or equal to 38 µm, greater than or equal to 34 µm and less than or equal to 36 µm, greater than or equal to 40 µm and less than or equal to 50 µm, greater than or equal to 42 µm and less than or equal to 48 µm, or even greater than or equal to 44 µm and less than or equal to 46 µm. It should be understood that the distance DCi-116 may be within a range formed from any one of the lower bounds for this distance DCi-116 and any one of the upper bounds of this distance DCi-116 described herein.
Referring to
In embodiments, ΔCLI is greater than or equal to -0.1 Δ% and less than or equal to 0.3 Δ%. For example, ΔCLI may be greater than or equal to -0.05 Δ% and less than or equal to 0.25 Δ% or greater than or equal to -0.03 Δ% and less than or equal to 0.2 Δ% or even greater than or equal to -0.03 Δ% and less than or equal to 0.15 Δ%. It should be understood ΔCLI may be within a range formed from any one of the lower bounds for ΔCL1 and any one of the upper bounds of ΔCL1 described herein.
In embodiments, ΔCl is greater than or equal to -0.1 Δ% and less than or equal to 0.2 Δ%. For example, ΔCl may be greater than or equal to -0.05 Δ% and less than or equal to 0.15 Δ% or even greater than or equal to 0 Δ% and less than or equal to 0.1 Δ%. It should be understood ΔCl may be within a range formed from any one of the lower bounds for ΔCl and any one of the upper bounds of ΔCl described herein.
In embodiments with an inner common cladding as depicted in
In embodiments in which each of the plurality of the cores is surrounded by an individual inner cladding as depicted in
In embodiments, ΔOCC is greater than or equal to -0.4 Δ% and less than or equal to -0.2 Δ%. For example, ΔOCC may be greater than or equal to -0.35 Δ% and less than or equal to -0.25 Δ%. It should be understood ΔOCC may be within a range formed from any one of the lower bounds for ΔOCC and any one of the upper bounds of ΔOCC described herein.
While not intending to be limited by theory, the electro-magnetic fields of the waves (e.g., light waves) propagating in the coupled-core multicore optical fiber 110 may be coupled, for example, selectively coupled, when certain conditions are met. For example, each of the plurality of cores Ci of the coupled-core multicore optical fiber 110 may be characterized by a plurality of coupling coefficients (i.e., various coupling coefficients for coupling from one individual core, such as the first core C1, to another individual core, such as the second core C2). Coupling coefficients measure the amount of overlay between the modal fields of two cores of the plurality of cores C1, such as the first core C1 and the second core C2. Modal fields of the cores depend on various parameters, such as the radius of the core rCi, the refractive index of the core, the material of the core, the material of the cladding, and the wavelength of operation (λ) (i.e., the wavelength of light propagating in the core).
The coupling coefficient κ between two adjacent cores C1, C2 depend upon the core pitch between adjacent cores, which may also be referred to as the core spacing. Larger coupling coefficients are expected as the distance between cores decreases. For instance, at very small core spacing, e.g. 15 µm, the coupling coefficient may be greater than or equal to 100 (linear units) per meter and less than or equal to 600 per meter, or greater than or equal to 150 per meter and less than or equal to 550 per meter, or even greater than or equal to 300 per meter and less than or equal to 400 per meter. However, at very large core spacing, e.g. 60 µm, the coupling coefficient may be greater than or equal to 8 × 10-6 per meter and less than or equal to 4 × 10-4 per meter.
In embodiments, the coupling coefficient may be greater than or equal to 1 × 10-3 /m. For instance, the power coupling coefficient may be greater than or equal to 1 × 10-3 /m and less than or equal to 5 × 10-3 /m or greater than or equal to 1.5 × 10-3 /m and less than or equal to 4.5 × 10-3 /m or greater than or equal to 2 × 10-3 /m and less than or equal to 4 × 10-3 /m or even greater than or equal to 2.5 × 10-3 /m and less than or equal to 3.5 × 10-3 /m.
Another parameter affecting the transmission of information using the fibers described herein is crosstalk. In various embodiments, the crosstalk between two adjacent cores 120a, 120b is greater than or equal to -30 dB for 1 km fiber length and less than or equal to 0 dB for 1 km fiber length. For example, the crosstalk may be greater than or equal to -25 dB for 1 km fiber length and less than or equal to -1 dB for 1 km fiber length, greater than or equal to -20 dB for 1 km fiber length and less than or equal to -2 dB for 1 km fiber length, greater than or equal to -15 dB for 1 km fiber length and less than or equal to -3 dB for 1 km fiber length, or even greater than or equal to -10 dB for 1 km fiber length and less than or equal to -4 dB for 1 km fiber length. It should be understood crosstalk may be within a range formed from any one of the lower bounds for crosstalk and any one of the upper bounds of crosstalk described herein.
In embodiments, each core of the coupled-core multicore optical fiber 110 may have an effective area Aeff of greater than 100 µm2 at a wavelength of 1550 nm. The effective area is determined individually for each core of the coupled-core multicore optical fiber without consideration of the effects of crosstalk between the cores of the coupled-core multicore optical fiber. For instance, the effective area or each core may be greater than or equal to 110 µm2 and less than or equal to 160 µm2, greater than or equal to 120 µm2 and less than or equal to 158 µm2, greater than or equal to 124 µm2 and less than or equal to 156 µm2, greater than or equal to 126 µm2 and less than or equal to 154 µm2, greater than or equal to 128 µm2 and less than or equal to 152 µm2, greater than or equal to 130 µm2 and less than or equal to 150 µm2, greater than or equal to 132 µm2 and less than or equal to 148 µm2, greater than or equal to 134 µm2 and less than or equal to 146 µm2, greater than or equal to 136 µm2 and less than or equal to 144 µm2, or even greater than or equal to 138 µm2 and less than or equal to 142 µm2. In other embodiments, each core of the coupled-core multicore optical fiber 110 may have an effective area of greater than or equal to 70 µm2 and less than or equal to 85 µm2 at a wavelength of 1550 nm. For instance, the effective area of each core may be greater than or equal to 71 µm2 and less than or equal to 84 µm2, greater than or equal to 72 µm2 and less than or equal to 83 µm2, greater than or equal to 73 µm2 and less than or equal to 82 µm2, greater than or equal to 74 µm2 and less than or equal to 81 µm2, greater than or equal to 75 µm2 and less than or equal to 80 µm2, greater than or equal to 76 µm2 and less than or equal to 79 µm2, or even greater than or equal to 77 µm2 and less than or equal to 78 µm2. It should be understood that the Aeff of each core of the coupled-core multicore optical fiber 110 may be within a range formed from any one of the lower bounds for Aeff and any one of the upper bounds of Aeff described herein.
The average attenuation of the coupled-core multicore optical fiber is determined by measuring the attenuation for each core of the coupled-core multicore optical fiber at a wavelength of 1510 nm and then calculating an average attenuation for the entire coupled-core multicore optical fiber based on the individual attenuation measurements of each core. In embodiments, the average attenuation of the coupled-core multicore optical fiber 110 is less than or equal to 0.18 dB/km, less than or equal to 0.175 dB/km, less than or equal to 0.17 dB/km, or even less than or equal to 0.165 dB/km. In embodiments, the attenuation of the optical fiber at a wavelength of 1550 nm may be greater than or equal to 0.16 dB/km and less than or equal to 0.18 dB/km, greater than or equal to 0.165 dB/km and less than or equal to 0.175 dB/km, greater than or equal to 0.16 dB/km and less than or equal to 0.175 dB/km, or even greater than or equal to 0.165 dB/km and less than or equal to 0.18 dB/km. It should be understood that the attenuation of the coupled-core multicore optical fiber 110 may be within a range formed from any one of the lower bounds for attenuation and any one of the upper bounds of attenuation described herein.
In various embodiments, the cable cutoff of each core of the coupled-core multicore optical fiber 110 is greater than or equal to 1200 nm and less than or equal to 1530 nm. For example, the cable cutoff of each core of each core of the coupled-core multicore optical fiber 110 may be greater than or equal to 1220 nm and less than or equal to 1530 nm, greater than or equal to 1240 nm and less than or equal to 1530 nm, greater than or equal to 1260 nm and less than or equal to 1530 nm, greater than or equal to 1280 nm and less than or equal to 1530 nm, greater than or equal to 1300 nm and less than or equal to 1500 nm, greater than or equal to 1320 nm and less than or equal to 1480 nm, greater than or equal to 1340 nm and less than or equal to 1460 nm, greater than or equal to 1360 nm and less than or equal to 1440 nm, greater than or equal to 1380 nm and less than or equal to 1420 nm, greater than or equal to 1390 nm and less than or equal to 1400 nm, greater than or equal to 1300 and less than or equal to 1500 nm, or even greater than or equal to 1320 and less than or equal to 1480 nm. It should be understood that the cable cutoff of each core of the coupled-core multicore optical fiber 110 may be within a range formed from any one of the lower bounds for cable cutoff and any one of the upper bounds of cable cutoff described herein.
The average 15 mm bend loss of the coupled-core multicore optical fiber is determined by measuring the 15 mm bend loss for each core of the coupled-core multicore optical fiber at a wavelength of 1510 nm and then calculating an average 15 mm bend loss for the entire coupled-core multicore optical fiber based on the individual 15 mm bend loss measurements of each core. In various embodiments, the average bend loss of the coupled-core multicore optical fiber 110 measured at a wavelength of 1550 nm using a mandrel with a 15 mm diameter (“1 × 15 mm diameter bend loss”) is greater than or equal to 0.1 dB/turn and less than or equal to 10 dB/turn. For example, the 1 × 15 mm diameter bend loss at 15 mm is less than or equal to 5 dB/turn, less than or equal to 4 dB/turn, less than or equal to 3 dB/turn, less than or equal to 2 dB/turn, or even less than or equal to 1 dB/turn.
The average 20 mm bend loss of the coupled-core multicore optical fiber is determined by measuring the 20 mm bend loss for each core of the coupled-core multicore optical fiber at a wavelength of 1510 nm and then calculating an average 20 mm bend loss for the entire coupled-core multicore optical fiber based on the individual 20 mm bend loss measurements of each core. In various embodiments, the average bend loss of the coupled-core multicore optical fiber 110 at a wavelength of 1550 nm using a mandrel with a 20 mm diameter (“1 × 20 bend loss”) is greater than or equal to 0.01 dB/turn and less than or equal to 1 dB/turn. For example, the 1 x 20 bend loss is less than or equal to 0.8 dB/turn, less than or equal to 0.6 dB/turn, less than or equal to 0.5 dB/turn, less than or equal to 0.4 dB/turn, less than or equal to 0.3 dB/turn, or even less than or equal to 0.2 dB/turn.
The average 30 mm bend loss of the coupled-core multicore optical fiber is determined by measuring the 30 mm bend loss for each core of the coupled-core multicore optical fiber at a wavelength of 1510 nm and then calculating an average 30 mm bend loss for the entire coupled-core multicore optical fiber based on the individual 30 mm bend loss measurements of each core. In various embodiments, the average bend loss at 1550 nm of the coupled-core multicore optical fiber 110 at a wavelength of 1550 nm using a mandrel with a 30 mm diameter (“1 × 30 bend loss”) is greater than or equal to 0.001 dB/turn and less than or equal to 0.03 dB/turn. For example, the 1 × 30 bend loss is greater than or equal to 0.001 dB/turn and less than or equal to 0.025 dB/turn or even greater than or equal to 0.001 dB/turn and less than or equal to 0.02 dB/turn. It should be understood that the 1 × 30 bend loss mm of the coupled-core multicore optical fiber 110 may be within a range formed from any one of the lower bounds for 1 × 30 bend loss and any one of the upper bounds of 1 × 30 bend loss described herein.
In various embodiments, the zero-dispersion wavelength of each core of the coupled-core multicore optical fiber 110 is greater than or equal to 1200 nm and less than or equal to 1350 nm. For example, the zero-dispersion wavelength of each core of the coupled-core multicore optical fiber 110 may be greater than or equal to 1225 nm and less than or equal to 1325 nm or even greater than or equal to 1250 nm and less than or equal to 1300 nm. It should be understood that the zero-dispersion wavelength of each core of the coupled-core multicore optical fiber 110 may be within a range formed from any one of the lower bounds for zero-dispersion wavelength and any one of the upper bounds of zero-dispersion wavelength described herein.
In various embodiments, dispersion at 1310 nm of each core of the coupled-core multicore optical fiber 110 is greater than or equal to 0.2 ps/nm/km and less than or equal to 3.5 ps/nm/km. For example, the dispersion at 1310 of each core of the coupled-core multicore optical fiber 110 may be greater than or equal to 0.5 ps/nm/km and less than or equal to 3 ps/nm/km, greater than or equal to 1 ps/nm/km and less than or equal to 2.5 ps/nm/km, or even greater than or equal to 1.5 ps/nm/km and less than or equal to 2 ps/nm/km. It should be understood that the dispersion at 1310 nm of each core of the coupled-core multicore optical fiber 110 may be within a range formed from any one of the lower bounds for dispersion at 1310 nm and any one of the upper bounds of dispersion at 1310 nm described herein.
In various embodiments, the dispersion slope at 1310 nm of each core of the coupled-core multicore optical fiber 110 is greater than or equal to 0.08 ps/nm2/km and less than or equal to 0.095 ps/nm2/km. For example, the dispersion slope at 1310 nm of each core of the coupled-core multicore optical fiber 110 may be greater than or equal to 0.081 ps/nm2/km and less than or equal to 0.094 ps/nm2/km, greater than or equal to 0.082 ps/nm2/km and less than or equal to 0.093 ps/nm2/km, greater than or equal to 0.083 ps/nm2/km and less than or equal to 0.092 ps/nm2/km, greater than or equal to 0.084 ps/nm2/km and less than or equal to 0.091 ps/nm2/km, greater than or equal to 0.085 ps/nm2/km and less than or equal to 0.09 ps/nm2/km, greater than or equal to 0.086 ps/nm2/km and less than or equal to 0.089 ps/nm2/km, or even greater than or equal to 0.087 ps/nm2/km and less than or equal to 0.088 ps/nm2/km. It should be understood that the dispersion slope at 1310 nm of each core of the coupled-core multicore optical fiber 110 may be within a range formed from any one of the lower bounds for dispersion slope at 1310 nm and any one of the upper bounds of dispersion slope at 1310 nm described herein.
In various embodiments, dispersion at 1550 nm of each core of the coupled-core multicore optical fiber 110 is greater than or equal to 15 ps/nm/km and less than or equal to 25 ps/nm/km. For example, dispersion at 1550 of each core of the coupled-core multicore optical fiber 110 may be greater than or equal to 16 ps/nm/km and less than or equal to 24 ps/nm/km, greater than or equal to 17 ps/nm/km and less than or equal to 23 ps/nm/km, greater than or equal to 18 ps/nm/km and less than or equal to 22 ps/nm/km, or even greater than or equal to 19 ps/nm/km and less than or equal to 21 ps/nm/km. It should be understood that the dispersion at 1550 nm of each core of the coupled-core multicore optical fiber 110 may be within a range formed from any one of the lower bounds for dispersion at 1550 nm and any one of the upper bounds of dispersion at 1550 nm described herein.
In various embodiments, the dispersion slope at 1550 nm of each core of the coupled-core multicore optical fiber 110 is greater than or equal to 0.05 ps/nm2/km and less than or equal to 0.065 ps/nm2/km. For example, the dispersion slope at 1550 nm of each core of the coupled-core multicore optical fiber 110 may be greater than or equal to 0.051 ps/nm2/km and less than or equal to 0.064 ps/nm2/km, greater than or equal to 0.052 ps/nm2/km and less than or equal to 0.063 ps/nm2/km, greater than or equal to 0.053 ps/nm2/km and less than or equal to 0.062 ps/nm2/km, greater than or equal to 0.054 ps/nm2/km and less than or equal to 0.061 ps/nm2/km, greater than or equal to 0.055 ps/nm2/km and less than or equal to 0.06 ps/nm2/km, greater than or equal to 0.056 ps/nm2/km and less than or equal to 0.059 ps/nm2/km, or even greater than or equal to 0.057 ps/nm2/km and less than or equal to 0.058 ps/nm2/km. It should be understood that the dispersion slope at 1550 nm of each core of the coupled-core multicore optical fiber 110 may be within a range formed from any one of the lower bounds for dispersion slope at 1550 nm and any one of the upper bounds of dispersion slope at 1550 nm described herein.
The coupled-core multicore optical fiber 110 of the present disclosure can be made using any suitable method for forming a multicore optical fiber. See, for example, U.S. Pat. No. 9,120,693 and U.S. Published Pat. Application No. 20150284286, the disclosures of which are incorporated herein by reference in their entirety. For example, the coupled-core multicore optical fiber 110 can be formed by drawing a multicore preform made using conventional optical-fiber techniques, such as glass drilling or stacking. The glass drilling method can be used to form a multicore preform by drilling holes in a silica glass cylinder (pure, undoped silica or doped silica). The locations and dimensions of the holes are based on the multicore optical fiber design. Core canes having the desired refractive index profile and a diameter that is slightly smaller than the pre-drilled holes are then inserted into the pre-drilled holes to form the multicore preform. The multicore preform is then heated to a temperature sufficient to melt the silica glass forming the pre-drilled holes such that the pre-drilled holes collapse around the core canes. The multicore preform is then drawn into a fiber. The core canes can be made using any suitable conventional preform manufacturing technique, such as outside vapor deposition (OVD), modified chemical vapor deposition (MCVD), or plasma activated chemical vapor deposition (PCVD).
Suitable precursors for silica include SiCl4 and organosilicon compounds. Organosilicon compounds are silicon compounds that include carbon, and optionally oxygen and/or hydrogen. Examples of suitable organosilicon compounds include octamethylcyclotetrasiloxane (OMCTS), silicon alkoxides (Si(OR)4), organosilanes (SiR4), and Si(OR)xR4-x, where R is a carbon-containing organic group or hydrogen and where R may be the same or different at each occurrence, and wherein at least one R is a carbon-containing organic group. Suitable precursors for chlorine doping include Cl2, SiCl4, Si2Cl6, Si2OCl6, SiCl3H, and CCl4. Suitable precursors for fluorine doping include F2, CF4, and SiF4. Regions of constant refractive index may be formed by not doping or by doping at a uniform concentration over the thickness of the region. Regions of variable refractive index are formed through non-uniform spatial distributions of dopants over the thickness of a region and/or through incorporation of different dopants in different regions. The OVD, MCVD, PCVD and other techniques for generating silica soot permit fine control of dopant concentration through layer-by-layer deposition with variable flow rate delivery of dopant precursors.
One exemplary method that can be used to form the multicore optical fibers of the present disclosure is a method that utilizes a cane-based optical fiber preform and then draws the optical fiber from the cane-based glass preform. An exemplary cane-based glass preform method is disclosed in Applicant’s co-pending U.S. Pat. Application Serial No. 62/811,842 (Attorney Docket No. SP19-067PZ), entitled “Vacuum-Based Methods of Forming a Cane-Based Optical Fiber Preform and Methods of Forming an Optical Fiber Using Same,” which was filed on Feb. 28, 2019, the contents of which are incorporated herein by reference in their entirety.
Briefly, a cane-based glass preform method for forming the multicore optical fibers 10 can include utilizing one or more glass cladding sections each having one or more precision axial holes formed therein and a top end with a recess defined by a perimeter lip. When using multiple glass cladding sections, the sections can be stacked so that the axial holes are aligned. A core cane can then be added to each axial hole to define a cane-cladding assembly. Top and bottom caps, respectively, can be added to the top and bottom of the cane-cladding assembly to define a preform assembly. The top cap closes off the recess at the top of the glass-cladding section. The bottom cap can have its own raised lip and recess that becomes closed off when the bottom cap is interfaced with the bottom end of the cane-cladding assembly. The closed-off recesses and gaps formed by the canes within the axial holes define a substantially sealed internal chamber. The preform assembly can then be dried and purified by drawing a select cleaning gas (e.g., chlorine) through a small passage in the bottom cap that leads to the internal chamber. A vacuum can be applied through the top cap to create a pressure differential between the internal chamber and the ambient environment. The pressure differential facilitates maintaining the components of the preform assembly together, and can be referred to as a vacuum-held preform assembly. The vacuum-held preform assembly can then be consolidated by heating in a furnace to just above the glass softening temperature so that the glass cladding section(s), the core canes, and the top and bottom caps, which are all made of glass, seal to one another. In addition, the glass flow can remove the internal chamber. The result is a solid glass preform that is ready to be drawn, especially if the furnace used for the consolidation is a draw furnace used for drawing optical fiber.
Additionally, if an outer common cladding is to be included, the material that will become the outer common cladding may be added to the outer surface of the preform containing the cores. For instance, soot may be applied to the preform via organic vapor deposition and then consolidated with the desired dopant. After the cores, inner common cladding material, and outer common cladding material are assembled as above, the coupled-core multicore optical fibers may then be drawn to the desired fiber diameter, as described above.
The coupled-core multicore optical fibers described herein will now be further described with reference to the following examples.
The coupled-core multicore optical fiber shown in
Six coupled-core multicore optical fibers were fabricated as detailed above in a 2 × 2 core (“four core”) arrangement as depicted in
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Examples 1, 3, 5, 6 were also examined to determine the coupling coefficient and the crosstalk between adjacent cores in dB with various core-to-core spacing. The coupling coefficients were determined by calculating the overlap integral between the electric fields of the LP01 modes in two neighboring cores. The crosstalk was calculated based on Equation (7). The results are summarized in Table 2 (coupling coefficients) and Table 3 (crosstalk). From the two tables, it is possible to choose the core spacing for a profile design to achieve a desired coupling coefficient and crosstalk. For coupled core multicore optical fibers, the core spacing can provide a coupling coefficient greater than or equal to 3.4 × 10-4 /m, greater than or equal to 1.1 × 10-3 /m, or even greater than or equal to 2.5 × 10-3 /m. The crosstalk is greater than or equal to -20 dB, greater than or equal to -10 dB, or even equal to 0 dB.
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As shown in Examples 2-6, the optical fibers described herein are capable of achieving an effective area Aeff for each core of greater than 100 µm2 at 1550 nm. And in some instances, the Aeff of each core may be much greater, such as with Example 3, which has an Aeff for each core of 150 µm2. However, the average attenuation remained relatively low in all the examples, i.e., 0.165 dB/km. The attenuation would be expected to be higher if there were significant levels of crosstalk present, but this undesirable phenomenon is suppressed through optimization of the refractive indices and dimensions of the cores and claddings and the spacing between the cores.
It will be apparent to those skilled in the art that various modifications and variations can be made to the embodiments described herein without departing from the spirit and scope of the claimed subject matter. Thus it is intended that the specification cover the modifications and variations of the various embodiments described herein provided such modification and variations come within the scope of the appended claims and their equivalents.
This Application is a divisional of U.S. Pat. Application Serial No. 17/387,113, filed on Jul. 28, 2021, which claims priority under 35 USC §119(e) from U.S. Provisional Pat. Application Serial Number 63/063,559 filed on Aug. 10, 2020, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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63063559 | Aug 2020 | US |
Number | Date | Country | |
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Parent | 17387113 | Jul 2021 | US |
Child | 18201368 | US |