High precision 96 µm CO_2 laser end-face processing of optical fibres

Boyd, Keiron; Rees, Simon; Simakov, Nikita; Daniel, J. M. O.; Swain, Robert; Mies, Eric; Hemming, Alexander; Clarkson, W.A.; Haub, John

doi:10.1364/oe.23.015065

Cited by 13 publications

(5 citation statements)

References 17 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The mirror reflection method and the knife-edge method [14] were used to measure the focal length of the fabricated lensed optical fiber and the beam size at the focal plane, respectively.…”

Section: Measurement Of the Focal Length And Beam Sizementioning

confidence: 99%

“…We note that our precise CSF cleaving technique using a femtosecond laser has been implemented previously, demonstrating its superiority over conventional micromachining, which cannot be used to precisely fabricate an optical fiber [12]. Furthermore, the proposing method is simpler than the conventional method involving polishing processes together with thermal processing [14,15].…”

Section: Introductionmentioning

confidence: 98%

See 1 more Smart Citation

Fabrication of Lensed Optical Fibers for Biosensing Probes Using CO2 and Femtosecond Lasers

et al. 2021

View full text Add to dashboard Cite

We propose a new method for precisely fabricating a lensed fiber with a desired focal length by first cleaving a coreless silica fiber using an ultrafast femtosecond laser without thermal effects and subsequently shaping the radius of curvature at the optical-fiber end using a CO2 laser. The precisely cleaved segment of the coreless silica fiber obtained with the femtosecond laser is attached to a long single-mode fiber. The beam-exposure time and laser power of the CO2 laser are adjusted to melt the coreless-fiber end to yield a uniform, consistent, and precise radius of curvature, thereby realizing a lensed optical fiber. The precision of the radius of curvature in this case is greater than those obtained with the conventional arc discharge method with thermal treatment requiring fairly complex processes and yielding relatively low fabrication accuracy. In our study, we observe a difference between the measured and calculated focal lengths of the fabricated lens, possibly because the exact value of the mode field diameter is uncertain. On the other hand, the beam size measured using the knife-edge method matches closely with the theoretical size. Our findings confirm the feasibility of fabricating lensed optical fibers for fiber-based biosensing using CO2 and femtosecond lasers.

show abstract

Section: Measurement Of the Focal Length And Beam Sizementioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

Fabrication of Lensed Optical Fibers for Biosensing Probes Using CO2 and Femtosecond Lasers

et al. 2021

View full text Add to dashboard Cite

show abstract

“…While conventional D-shaped optical fiber manufacturing technologies rely on the mechanical polishing or chemical etching method, which inevitably bring cracks and subsurface damage [3] or the introduction of contamination and impurities [4]. However, laser ablation [5] as a non-contact process method has been proved to be a promising technology for achieving ultra-smooth [6] and low defects surface. The CO2 laser is generally chosen to process optical fiber for the reason the peak absorption wavelength of the glass is just in the wavelength range of the CO2 laser [7].…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation of surface topography evolution during pulsed CO2 laser ablation of fiber

Wu²,

Ma³

2022

Sixth International Symposium on Laser Interaction With Matter

View full text Add to dashboard Cite

D-shaped fiber manufacturing by mechanical grinding or chemical acid will inevitably introduce subsurface damages or impurity during processing. Laser ablation has been proven to be a high-efficiency non-contact technique that can achieve a low-defect surface. However, the process of laser processing fiber involves the phase change of the material, which leads to a very complicated evolution process of the surface topography of the fiber. In order to predict the surface topography of fiber during irradiation by pulse laser. Herein, a 3D model has been established to assist the understanding of the thermal mechanism of pulsed CO2 laser ablation and phase change of evaporation during ablation. Furthermore, the temperature characteristics of the fiber surface during the laser irradiation are also analyzed. The simulation results show that from the second pulse, the ablation depth is basically stable, and the texture formed on the fiber surface is related to the processing parameters.

show abstract

“…However, the interfaces of fibers with other systems are largely limited to their tips, which impedes their applications in large area applications. While longitudinal symmetry in fibers can be broken through selective capillary breakup, gaining electrical, optical, or fluidic access to the devices embedded within the fiber cladding commonly relies on the low-throughput ablation methods. , A method offering access to functional features along the fiber lengths would expand the capabilities and interface density of fiber-based systems.…”

Section: Introductionmentioning

confidence: 99%

Selectively Micro-Patternable Fibers via In-Fiber Photolithography

et al. 2020

View full text Add to dashboard Cite

Multimaterial fibers engineered to integrate glasses, metals, semiconductors, and composites found applications in ubiquitous sensing, biomedicine, and robotics. The longitudinal symmetry typical of fibers, however, limits the density of functional interfaces with fiber-based devices. Here, thermal drawing and photolithography are combined to produce a scalable method for deterministically breaking axial symmetry within multimaterial fibers. Our approach harnesses a two-step polymerization in thiol–epoxy and thiol–ene photopolymer networks to create a photoresist compatible with high-throughput thermal drawing in atmospheric conditions. This, in turn, delivers meters of fiber that can be patterned along the length increasing the density of functional points. This approach may advance applications of fiber-based devices in distributed sensors, large area optoelectronic devices, and smart textiles.

show abstract

High precision 96 µm CO_2 laser end-face processing of optical fibres

Cited by 13 publications

References 17 publications

Fabrication of Lensed Optical Fibers for Biosensing Probes Using CO2 and Femtosecond Lasers

Fabrication of Lensed Optical Fibers for Biosensing Probes Using CO2 and Femtosecond Lasers

Numerical simulation of surface topography evolution during pulsed CO2 laser ablation of fiber

Selectively Micro-Patternable Fibers via In-Fiber Photolithography

Contact Info

Product

Resources

About