Low-cost Custom Fabrication and Mode-locked Operation of an All-normal-dispersion Femtosecond Fiber Laser for Multiphoton Microscopy

Kai Zhang; Nima Davoudzadeh; Guillaume Ducourthial; Bryan Q. Spring

doi:10.3791/60160

Low-cost Custom Fabrication and Mode-locked Operation of an All-normal-dispersion Femtosecond Fib...

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JoVE Journal Engineering

Low-cost Custom Fabrication and Mode-locked Operation of an All-normal-dispersion Femtosecond Fiber Laser for Multiphoton Microscopy

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08:48 min

November 22, 2019

DOI: 10.3791/60160-v

Kai Zhang^1,2, Nima Davoudzadeh^1,2, Guillaume Ducourthial^1,2, Bryan Q. Spring^1,2,3

¹Translational Biophotonics Cluster,Northeastern University, ²Department of Physics,Northeastern University, ³Department of Bioengineering,Northeastern University

Overview

This article presents a method for constructing a low-cost, mode-locked femtosecond fiber laser, which has potential applications in multiphoton microscopy, endoscopy, and photomedicine. The laser is built using commercially available parts and basic splicing techniques, making it an accessible option for researchers.

Key Study Components

Area of Science

Neuroscience
Optics
Biomedical Engineering

Background

Femtosecond pulse lasers are essential tools in multiphoton microscopy.
They offer advantages over traditional solid-state ultrafast lasers, including cost-effectiveness and compactness.
Fiber lasers eliminate the need for water cooling, reducing system size.
These lasers are robust against vibration due to the lack of alignment requirements.

Purpose of Study

To provide a cost-effective alternative to commercial ultrafast lasers.
To facilitate the use of femtosecond lasers in various biomedical applications.
To demonstrate the feasibility of building a laser using readily available components.

Methods Used

Construction of a femtosecond all-normal dispersion fiber laser.
Utilization of commercially available parts for assembly.
Application of basic splicing techniques.
Evaluation of the laser's performance in multiphoton microscopy.

Main Results

The constructed laser is compact and robust.
It significantly reduces costs compared to commercial alternatives.
The system's design allows for easy integration into existing setups.
Performance tests indicate suitability for multiphoton microscopy applications.

Conclusions

This method provides a viable option for researchers needing femtosecond lasers.
The low-cost design encourages broader access to advanced imaging techniques.
Future work may explore further enhancements and applications in photomedicine.

Frequently Asked Questions

What are the applications of femtosecond lasers?

Femtosecond lasers are used in multiphoton microscopy, endoscopy, and photomedicine.

How does this laser compare to commercial options?

It is significantly cheaper and does not require water cooling, making it more compact.

What components are needed to build this laser?

The laser can be constructed using commercially available parts and basic splicing techniques.

Is the system robust against vibrations?

Yes, the fiber components do not require alignment, enhancing robustness.

Can this laser be used in existing setups?

Yes, its compact design allows for easy integration into current systems.

What is the significance of using fiber lasers?

Fiber lasers offer advantages in size, cost, and ease of use compared to solid-state lasers.

A method is presented to build a custom low-cost, mode-locked femtosecond fiber laser for potential applications in multiphoton microscopy, endoscopy, and photomedicine. This laser is built using commercially available parts and basic splicing techniques.

Femtosecond pulse lasers have broad applications in multiphoton miscroscopy. This protocol can be used to fabricate a femtosecond all-normal dispersion fiber laser that is compact, robust, and inexpensive. Compared with commercial solid-state ultrafast lasers, the laser produced in this technique costs much less because it consists of only commercially available parts.

Also, fiber lasers do not need water cooling, so the size of the system is smaller. Last but not least, the fiber components do not require alignment, which makes the system robust to vibration. Unlike commercially available systems, this laser does not have a cover to block unwanted beams.

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