The Indian Institute of Technology (IIT) Madras researchers have demonstrated the possibility of generating bio-compatible lasers from carrots, exploiting a process first discovered by sir CV Raman who won the Nobel prize for Physics in 1930.
Being completely natural and fully bio-compatible, this system can be used with other bio-entities for their sensing based on the proposed laser. This ‘kitchen laser’ has the linear response for temperature which could be used for temperature sensing too.
IIT-Madras claims that it is a first-of-its-kind development across the globe. With findings of the research, scientific and industrial research can benefit from optical spectroscopy and sensing. Apart from being bio-friendly, the system they envisage is robust and reliable, with good and linear response to temperature.
Gummaluri, a PhD student, said, “We were excited to see lasing in fresh carrots, due to the carotene and cellulose found in them. We have successfully demonstrated CW-laser pumped stable stokes mode random lasing, exploiting the Raman activity of naturally occurring carotene and multiple scattering due to cellulose in carrots.”
Since biocompatibility and sustainability point to bio-derived materials, the team looked at biological molecules as probable lasing sources. Organic chemical based lasing sources has been around for decades, nearly as long as semiconductor sources. Random Lasers (RL), for example, have traditionally use plasmonic/dielectric scatterers and gain media such as chemical dyes and fluorescent polymers.
While the traditional polymers used were toxic and non-biodegradable, there has been searching for more eco-friendly fluorescent polymers. Cellulose fibres, for example, have been shown to facilitate multiple scattering of phonons, suggesting the possibility of an organic/eco-friendly bio-compatible scattering medium. This work published in the leading journal of the Optical Society of America, Optics Letters.
Carrots, in addition to having carotenoids, also have cellulose fibers, that contribute to multiple scattering of photons and resultant optical amplification for Raman random lasing. They were not wrong in their expectation.
“Organic bio-pigments like carotenoids found in carrots and porphyrins found in chlorophyll are interesting optically active media because of their visible light absorption properties. Although the fluorescence quantum yield of carotenoids is much less compared to standard organic laser dyes, the vibrational spectra can be obtained even with extremely low concentrations of carotenoids. The Research team naturally chose carotenoid, as a possible lasing source,” said Sivaraman Krishnan, assistant professor physics department, IIT-Madras,
The Research was undertaken by a team comprising prof. C. Vijayan, Sivarama Krishnan, assistant professor, physics department, IIT Madras, and Venkata Siva Gummaluri, PhD research scholar, physics department, IIT Madras.
“There is now a move towards development of green, sustainable materials for various applications, including in photonics. The need for green photonic technologies in obvious in the current times where sustainability, bio-compatibility and -degradability are of paramount importance,” said C. Vijayan.
Light Amplification by Stimulated Emission of Radiation, more commonly known as LASER, is one of the most important discoveries of the 20th century, as has been shown by its plethora of exciting applications in daily life. Laser is created when electrons in some special materials absorb energy and become ‘excited.’ These electrons emit ‘particles of light’ or photons when they return to their original state.
The photons are coherent, which makes the light emitted powerful and sharp. These lasing materials are usually solid-state and semiconductor materials, such as Nd-YAG, which are expensive, and involve environmental issues during production and/or use.
Lasers are ubiquitous sources of light with extraordinary properties such as high degree of directionality and sharpness. They are indispensable in a dazzling range of products and technologies including communication, lithography, medicine, military operations, scientific research, engineering, displays, and data storage. In this case, a particular class of lasers called ‘random lasers’ have been demonstrated in carrots where a Raman process plays a central role along with the cellulose network.