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Publications

1. Rana, S.; Subbaraman, H.; Fleming, A.; Kandadai, N. Numerical Analysis of Radiation Effects on Fiber Optic Sensors. Sensors 2021, 21, 4111.

2. Rana, S.; Kandadai, N.; Subbaraman, H. Reflective Long Period Grating Based Temperature Sensor.; International Society for Optics and Photonics, 2021; Vol. 11682, p. 1168219.

3.Rana, S.; Kandadai, N.; Subbaraman, H. Reflective Long Period Grating Based Refractive Index Sensor.; IEEE, 2021; pp. 1–2.

4.Rana, S.; Fleming, A.; Kandadai, N.; Subbaraman, H. Active Compensation of Radiation Effects on Optical Fibers for Sensing Applications. Sensors 2021, 21, 8193.

5.Dhamala, A.S.; Manzi, J.; Subbaraman, H.; Kandadai, N. Simulation of 2D Model of Dielectric Barrier Discharge for Flexible Hybrid Electronics.; IEEE, 2021; pp. 1–1.

6.Subbaraman, H.; Rana, S.; Kandadai, N. Reflective Long Period Grating. 2020.

7.Rana, S.; Kandadai, N.; Subbaraman, H. Towards the Design of a Wideband Reflective Long Period Grating Distributed Sensor. Journal of Physics Communications 2020, 4, 065015.

8.Rana, S.; Badamchi, B.; Subbaraman, H.; Kandadai, N. A Simple and Cost-Effective Metal Coating Method for Reflective Long Period Grating Sensors.; SPIE, 2020; Vol. 11503, pp. 82–87.

9.Guidara, N.; Lamb, J.; Pearlman, M.; Rektor, A.; Kandadai, N. Biomedical Applications of Near-Infrared Thermography. 2020.

10. Rana, S.; Subbaranman, H.; Kandadai, N.; McCary, K.M.; Fleming, A.D.; Daw, J.E. Out-of-Pile Testing of Radiation Hard Optical Fibers; Idaho National Lab.(INL), Idaho Falls, ID (United States); Boise State Univ â€¦, 2019;

11. Rana, S.; Subbaraman, H.; Kandadai, N. Role of Metal Coating Parameters on the Reflective Long Period Grating Spectrum.; Optical Society of America, 2019; pp. ETh1A-5.

12.Rana, S.; Subbaraman, H.; Kandadai, N. Fiber Optic Sensors for Real Time Temperature Monitoring in Harsh Environments. 2019.

13. Rana, S.; Badamchi, B.; Joshi, B.; Subbaraman, H.; Kandadai, N. Towards a Time Stable Fiber Optic Sensors for Harsh Environments. 2019.

14.Huff, J.S.; Davis, P.H.; Christy, A.; Kellis, D.L.; Kandadai, N.; Toa, Z.S.; Scholes, G.D.; Yurke, B.; Knowlton, W.B.; Pensack, R.D. DNA-Templated Aggregates of Strongly Coupled Cyanine Dyes: Nonradiative Decay Governs Exciton Lifetimes. The Journal of Physical Chemistry Letters 2019, 10, 2386–2392.

15.Da Silver, T.H.; Butler, D.; Biaggne, A.; Kandadai, N.; Subbaraman, H.; Daw, J.; Li, L. First-Principles Studies of Dopant and Radiation Defect Effects on Optical Fiber Sensors. 2019.

16. Badamchi, B.; Kandadai, N.; Simon, A.; Mitkova, M.; Subbaraman, H. A Novel High Temperature Optical Waveguide Sensor for Nuclear Reactors. 2019.

17. Wilson, B.A.; Rana, S.; Subbaraman, H.; Kandadai, N.; Blue, T.E. Modeling of the Creation of an Internal Cladding in Sapphire Optical Fiber Using the 6 Li (n, α) 3 H Reaction. Journal of Lightwave Technology 2018, 36, 5381–5387.

18. Rana, S.; Kandadai, N.; Subbaraman, H. A Highly Sensitive, Polarization Maintaining Photonic Crystal Fiber Sensor Operating in the THz Regime.; Multidisciplinary Digital Publishing Institute, 2018; Vol. 5, p. 40.

19. Badamchi, B.; Kandadai, N.; Ahmed Simon, A.-A.; Mitkova, M.; Subbaraman, H. A Novel High Temperature Sensor Architecture for Harsh Environments. 2018.

20.Hurley, D.; Jensen, C.; Schley, R.; Khafizov, M.; Kandadai, N.; Long, M.; Subbaraman, H. FY17 Status Report for the Development of Infrared Thermography for In-Pile Fuel Behavior Applications; Idaho National Lab.(INL), Idaho Falls, ID (United States), 2017;

21.Wang, C.; Wagner, C.; Dyer, G.; Gaul, E.; Kandadai, N.; Riley, N.; Kuk, D.; McCary, E.; Meadows, A.; Pomerantz, I. Full-Aperture Backscatter Diagnostics and Applications at the Texas Petawatt Laser Facility. Chinese Optics Letters 2014, 12, S23201.

22. Gaul, E.; Kandadai, N.; Dyer, G.; Borger, T.; Martinez, M.; Spinks, M.; Donovan, M.; Ditmire, T. Pulse Contrast Measurements of the Texas Petawatt Laser.; Optical Society of America, 2014; pp. JW2A-23.

23. Timneanu, N.; Iwan, B.; Andreasson, J.; Bergh, M.; Seibert, M.; Bostedt, C.; Schorb, S.; Thomas, H.; Rupp, D.; Gorkhover, T. Fragmentation of Clusters and Recombination Induced by Intense and Ultrashort X-Ray Laser Pulses.; SPIE, 2013; Vol. 8777, pp. 112–119.

24.Thomas, H.; Helal, A.; Hoffmann, K.; Kandadai, N.; Keto, J.; Andreasson, J.; Iwan, B.; Seibert, M.; Timneanu, N.; Hajdu, J. Explosions of Xenon Clusters in Ultraintense Femtosecond X-Ray Pulses from the LCLS Free Electron Laser. Physical review letters 2012, 108, 133401.

25.Kandadai, N.K. Interaction of Clusters with Ultra Short X-Ray Free Electron Laser Pulses. 2012.

26.  Kandadai, N.; Hoffmann, K.; Thomas, H.; Helal, A.; Keto, J.; Ditmire, T.; Iwan, B.; Timneanu, N.; Andreasson, J.; Seibert, M. Explosions of Methane Clusters Driven by Intense X-Ray FEL Pulses.; Optical Society of America, 2011; p. QTuC2.

27. Hoffmann, K.; Murphy, B.; Kandadai, N.; Erk, B.; Helal, A.; Keto, J.; Ditmire, T. Rare-Gas-Cluster Explosions under Irradiation by Intense Short XUV Pulses. Physical Review A 2011, 83, 043203.

28. Hoffmann, K.; Kandadai, N.; Thomas, H.; Helal, A.; Keto, J.; Ditmire, T.; Iwan, B.; Timneanu, N.; Andreasson, J.; Seibert, M. Explosions of Xenon Doped Methane Clusters in Intense X-Ray FEL Pulses.; Optical Society of America, 2011; p. JThB45.

29. Erk, B.; Hoffmann, K.; Kandadai, N.; Helal, A.; Keto, J.; Ditmire, T. Observation of Shells in Coulomb Explosions of Rare-Gas Clusters. Physical Review A 2011, 83, 043201.

30. Hoffmann, K.; Murphy, B.; Erk, B.; Helal, A.; Kandadai, N.; Keto, J.; Ditmire, T. High Intensity Femtosecond XUV Pulse Interactions with Atomic Clusters. High Energy Density Physics 2010, 6, 185–189.

31.Hoffmann, K.; Kandadai, N.; Thomas, H.; Helal, A.; Keto, J.; Ditmire, T.; Iwan, B.; Timneanu, N.; Andreasson, J.; Seibert, M. LASERS AND ELECTRO-OPTICS/QUANTUM ELECTRONICS AND LASER SCIENCE CONFERENCE: 2010 LASER SCIENCE TO PHOTONIC APPLICATIONS, CLEO/QELS 2010. 2010.

32. Hoffmann, K.; Kandadai, N.; Thomas, H.; Helal, A.; Keto, J.; Ditmire, T.; Iwan, B.; Timneanu, N.; Andreasson, J.; Seibert, M. Explosions of Clusters in Intense X-Ray Pulses.; IEEE, 2010; pp. 1–2.