Loss in hollow-core optical fibers: mechanisms, scaling rules, and limits

Fokoua, Eric Numkam; Mousavi, Seyed Mohammad Abokhamis; Jasion, Gregory T.; Richardson, David J.; Poletti, Francesco

doi:10.1364/aop.470592

Cited by 59 publications

(32 citation statements)

References 254 publications

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“…The seven-element cladding design offers an excellent compromise between confinement loss, higher-order mode suppression, and bend-loss sensitivity, allowing efficient single-mode delivery in practical fiber deployments. [19,46] The fiber was drawn to a total length of ≈500 m, but >1 km lengths are possible with our current preform design. The inner micro-structure was consistent over the fiber length, as confirmed by imaging both ends of the entire fiber (not shown).…”

Section: Hc-arf Power Delivery Results and Discussionmentioning

confidence: 99%

“…The development of HCFs for this wavelength range represents a higher fabrication challenge due to the smaller structural features. [17][18][19] Furthermore, nonlinearity in HCFs in the visible relative to the infrared region is significantly higher, which is due not only to the smaller fiber core size but also to the shorter operation wavelength. In particular, Raman scattering strength, which is the primary nonlinearity in this context, scales inversely with approximately the fourth power of the laser wavelength.…”

Section: Introductionmentioning

confidence: 99%

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Hollow‐Core Fiber: Breaking the Nonlinearity Limits of Silica Fiber in Long‐Distance Green Laser Pulse Delivery

Fu,

Davidson,

Mousavi

et al. 2024

Laser & Photonics Reviews

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Hollow‐core fiber (HCF), in which >99.99% of the light is guided in a central air (or vacuum) filled core, is a radically new fiber technology offering the potential to overcome the nonlinear limits associated with the delivery of high‐brightness laser pulses over long distances in conventional solid‐core fiber. Overcoming these limits is particularly challenging at visible wavelengths where the core sizes of single‐mode fibers (SMFs) are reduced. In this work, the delivery of near‐diffraction‐limited, kilowatt‐peak‐power, sub‐nanosecond laser pulses in the green wavelength range over hundred‐meter scale lengths of a hollow‐core anti‐resonant fiber (HC‐ARF) which offers broadband low‐loss guidance in the visible is experimentally demonstrated. Substantially reduced nonlinearity‐induced spectral broadening is observed relative to silica‐core SMF. The simulation further confirms that the broadening observed (in the HC‐ARF) is entirely due to the interaction of the light with the air in the core and thus can effectively be eliminated by evacuating the fiber. Moreover, access to lower‐loss is noted, and visible guiding HC‐ARFs (that are now becoming available) will improve the throughput efficiency and extend power delivery to kilometer distance scales. The results demonstrated here pave the way for future long‐distance HCF pulse delivery applications, such as remote industrial e‐mobility manufacturing.

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Section: Hc-arf Power Delivery Results and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Hollow‐Core Fiber: Breaking the Nonlinearity Limits of Silica Fiber in Long‐Distance Green Laser Pulse Delivery

Fu,

Davidson,

Mousavi

et al. 2024

Laser & Photonics Reviews

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“…A numerical simulation employing nite element analysis was used to extrapolate the loss of the HCF in additional spectral bands 43 . In the MIR spectral band, especially above 3.7 μm, the signi cant mechanisms that cause attenuation are leakage loss and material absorption of silica 34,37 . Hence, the simulation solely took into account these two variables.…”

Section: B Broadband Low-loss Hcfmentioning

confidence: 99%

“…However, the CO-lled bre laser has not yet been reported, primarily due to the overly extended wavelength band. While it is true that advanced HCFs have the capability to minimize the overlap between material and mode domains to approximately 10 − 5 , the transmission loss of HCFs is still affected by the signi cant loss of silica materials in the MIR band 34 . According to the curve presented in Fig.…”

Section: Introductionmentioning

confidence: 99%

4.8-μm CO-filled hollow-core silica fibre laser

wang,

Li,

Yang

et al. 2024

Preprint

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Mid-infrared (MIR) fibre lasers are important for a wide range of applications in sensing, spectroscopy, imaging, defense, and security. Some progress has been made in the research of MIR fibre lasers based on soft glass fibres, however, the emission range of rare-earth ions and the robustness of the host materials are still a major challenge for MIR fibre lasers. The large number of gases provide a variety of optical transitions in the MIR band. When combined with recent advances in low-loss hollow-core fibre (HCF), there is a great opportunity for gas-filled fibre lasers to further extend the radiation to the MIR region. Here, a 4.8-µm CO-filled silica-based HCF laser is reported for the first time. This is enabled by a homemade broadband low-loss HCF with a measured loss of 1.81 dB/m at 4.8 µm. A maximum MIR output power of 46 mW and a tuning range of 180 nm (from 4644 to 4824 nm) are obtained by using an advanced 2.33-µm narrow-linewidth fibre laser. This demonstration represents the longest-wavelength silica-based fibre laser to date, while the absorption loss of bulk silica at 4824 nm is up to 13, 000 dB/m. Further wavelength expansion could be achieved simply by changing the pump absorption line. This work paves the way for the MIR silica fibre laser beyond 5 µm.

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“…Emerging anti-resonant reflection offers an alternative approach to achieve field confinement 32 – 36 . This approach has been successfully applied in hollow-core fibers 32 – 34 , effectively confining optical modes within the lower-refractive-index air core.…”

Section: Introductionmentioning

confidence: 99%

Anti-resonant acoustic waveguides enabled tailorable Brillouin scattering on chip

Lei,

Xu,

Bai

et al. 2024

Nat Commun

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Empowering independent control of optical and acoustic modes and enhancing the photon-phonon interaction, integrated photonics boosts the advancements of on-chip stimulated Brillouin scattering (SBS). However, achieving acoustic waveguides with low loss, tailorability, and easy fabrication remains a challenge. Here, inspired by the optical anti-resonance in hollow-core fibers and acoustic anti-resonance in cylindrical waveguides, we propose suspended anti-resonant acoustic waveguides (SARAWs) with superior confinement and high selectivity of acoustic modes, supporting both forward and backward SBS on chip. Furthermore, this structure streamlines the design and fabrication processes. Leveraging the advantages of SARAWs, we showcase a series of breakthroughs for SBS within a compact footprint on the silicon-on-insulator platform. For forward SBS, a centimeter-scale SARAW supports a large net gain exceeding 6.4 dB. For backward SBS, we observe an unprecedented Brillouin frequency shift of 27.6 GHz and a mechanical quality factor of up to 1960 in silicon waveguides. This paradigm of acoustic waveguide propels SBS into a new era, unlocking new opportunities in the fields of optomechanics, phononic circuits, and hybrid quantum systems.

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Loss in hollow-core optical fibers: mechanisms, scaling rules, and limits

Cited by 59 publications

References 254 publications

Hollow‐Core Fiber: Breaking the Nonlinearity Limits of Silica Fiber in Long‐Distance Green Laser Pulse Delivery

Hollow‐Core Fiber: Breaking the Nonlinearity Limits of Silica Fiber in Long‐Distance Green Laser Pulse Delivery

4.8-μm CO-filled hollow-core silica fibre laser

Anti-resonant acoustic waveguides enabled tailorable Brillouin scattering on chip

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