Doctoral Student at National Institute of Technology Goa, India
Ruchika Thayil is a dedicated researcher in material science with expertise in low-dimensional nanomaterials and their applications in sensing, environmental, and antimicrobial technologies. She has been recognized for her academic achievements and contributions to research through prestigious awards and scholarships. Her work aims to bridge the gap between fundamental research and practical applications, particularly in developing innovative solutions for environmental and health challenges.
Professional Profile
Education 🎓
Ruchika Thayil is currently a Doctoral Researcher in the Department of Applied Sciences at the National Institute of Technology (NIT) Goa, India. She earned her B.Sc. in Physics from Carmel College of Arts, Science, and Commerce for Women, Nuvem-Goa, and completed her M.Sc. in Physics from Goa University, India..
Research Interests:
Ruchika’s primary research interests lie in material science, specifically the synthesis and characterization of nanostructured materials and 2D materials such as molybdenum dichalcogenides. Her research focuses on the development of high-performance gas sensors capable of detecting harmful gases at room temperature, SERS-based sensors, and microwave-absorbing materials. She has also explored antimicrobial studies and the use of nanomaterials for environmental applications, including the removal of harmful organic dyes from water.
Professional Experience:
Ruchika has been actively involved in research focused on advanced material science, particularly nanostructured and low-dimensional materials. She has published nine high-impact journal papers and presented her findings at several international conferences. Her work has been recognized with the INSPIRE Award from the Department of Science and Technology (DST) and a scholarship from the Japan Science and Technology Agency (JST) to participate in the SUKURA Science Exchange Programme. She is also a member of professional organizations, including SPIE and the Sukura Science Club of Japan.
Top Notes Publications 📚
1. Tuning MoS2 nanostructures for superior room-temperature toluene sensing
Journal: Talanta Open
Year: 2025
Volume: 11
Article Number: 100402
- Focuses on tuning MoS₂ nanostructures for detecting toluene gas at room temperature.
- Open access; citation details are unavailable yet.
2. Biofunctionalized magnetic nanoparticles incorporated MoS2 nanocomposite for enhanced n-butanol sensing at room temperature
Journal: Scientific Reports
Year: 2024
Volume: 14
Issue: 1
Article Number: 24508
- Explores a biofunctionalized MoS₂-based nanocomposite with magnetic nanoparticles for effective n-butanol sensing.
- Citations: 1
3. Tuning ZnSe nanostructures for enhanced ammonia sensing at room temperature
Journal: Materials Letters
Year: 2024
Volume: 371
Article Number: 136919
- Investigates ZnSe nanostructures for efficient ammonia gas sensing at ambient temperatures.
- Citations: 6
4. Recent advances and prospects on MoX2 (X=S, Se, Te) nanostructure-based sensors for room temperature gas detection: A review
Journal: Surfaces and Interfaces
Year: 2024
Volume: 52
Article Number: 104966
- A comprehensive review on the development of MoX₂ (X=S, Se, Te) nanostructures in gas sensing technologies.
- Citations: 6
5. Exploring the multifunctionality of MoS2 and MoSe2 nanostructures: Enhanced ammonia sensing, antimicrobial activity, and organic dye adsorption
Journal: Microchemical Journal
Year: 2024
Volume: 204
Article Number: 111175
- Highlights the versatility of MoS₂ and MoSe₂ in various applications, including ammonia sensing, antimicrobial effectiveness, and dye adsorption.
- Citations: 3
Conclusion
Ms. Ruchika Thayil is a highly deserving candidate for the Best Scholar Award due to her innovative research, strong publication record, and contributions to addressing critical challenges in environmental and health sciences. Her achievements, international exposure, and recognition through prestigious awards make her a competitive contender for this accolade. Enhancing her global impact, collaborative engagements, and leadership roles can further solidify her position as a top scholar in her field.