Rajan Jha Group
Nanophotonics and Plasmonics Lab
IIT Bhubaneswar
2025
146.
S Sahu, C Jacob, A Kumar, and Rajan Jha,” On-Chip Apodized Hybrid Photonic-Plasmonic Cavity QEDfor Polarized Single Photons Coupling", Adv. Quantum Technology, 2400712(2025).
145.
P Mishra, D Goswami, S Kumar, and Rajan Jha,” Polymer-Layered Optical Wearable (PLOW) for Healthcare Applications: Temperature and Stretching Monitoring", ACS Applied Materials & Interfaces, 17(5) (2025).
144.
N Kitamura, H Javid, S Watanabe, Rajan Jha, H Lee, Y Mizuno,” Polymer optical fiber tactile sensing enabled by minimal grating structures", Japanese Journal of Applied Physics, 64(2), 028002 (2025).
2024
143.
A K Maurya, K Chatterjee, and Rajan Jha,” Ultra-wide range non-contact surface profilometry based on reconfigurable fiber interferometry", Optics Letters, 49(13) (2024).
142.
S. Sahu, K. P. Nayak, K. R. Mangipudi, and Rajan Jha,” Slot Waveguide Enhanced Asymmetric Photonic Crystal Nanofiber Cavity for Fiber-Coupled Single Photons ”, Applied Physics Letters, 124(3) (2024). [Editor's Pick]
141.
K Chatterjee, C Marques, V Arumuru, S Sahu, J Nedoma, and Rajan Jha,” Integrated interferometers’ system for in situ real-time optical signal modulation”, Photonics Research, 12 (9), 2018-2026 (2024).
140.
K Chatterjee, and Rajan Jha,” Dynamic Field Magnetometry Using Tunable Cavity Assisted PCF Modal Interferometer”, IEEE Transactions on Instrumentation and Measurement, 73, 9513507 (2024).
139.
S. Sahu, and Rajan Jha,” Efficient coupling of single photons from chromium-vacancy centers in nanodiamonds into end-to-end aligned optical nanowires”, Journal of Physics B: Atomic, Molecular and Optical Physics, 57 (22), 225401, (2024).
138.
K Ozaki, K Kikuchi, G Zhu, K Noda, Y Yao, Y Lu, Rajan Jha, H Lee, Y Mizuno,”Noise mechanism clarification in external-modulation Brillouin optical correlation-domain reflectometry with double-sideband modulator”, Japanese Journal of Applied Physics 63 (7), 070904 (2024).
137.
Rajan Jha, P Gorai, A Shrivastav, and A Pathak,” Label-Free Biochemical Sensing Using Processed Optical Fiber Interferometry: A Review”, ACS Omega, (2024). [Invited Review]
136.
P Gorai, C Marques, AM Shrivastav, and Rajan Jha,”Precise detection of trace level protein using MIP-MoS2 nanocomposite functionalized PCF based interferometer”, Optics Express,32 (6), 10033-10045(2024).
135.
Rajan Jha, P Mishra, S Kumar,”Advancements in optical fiber-based wearable sensors for smart health monitoring”, Biosensors and Bioelectronics,116232(2024).
134.
MS Soares, R Singh, S Kumar, Rajan Jha, J Nedoma, R Martinek, C Marques,”The role of smart optical biosensors and devices on predictive analytics for the future of aquaculture systems”, Optics & Laser Technology,177, 111049 (2024).
133.
G. Zhu, K. Goya, K. Noda, Rajan Jha, H. Lee, and Y. Mizuno, ”Brillouin characterization of ZBLAN fiber for strain and temperature sensing”, Journal of Lightwave Technology, (2024).
132.
Sarita ,Rajan Jha, and RK Singh,”Enhancing plasmonic response by scattering of a beam under spherical aberration”, Optics & Laser Technology 179, 111397 (2024).
131.
Sarita ,Rajan Jha, and RK Singh,”Mie scattering of tightly focused beams by a core-shell nanoparticle”, Optics Communications,130306 (2024).
2023
130.
K. Chatterjee, R K Singh, and Rajan Jha,” Detection of Vortex Charge and Beam Displacement by Wavefront Division Interferometry”, Applied Physics Letters 123 (12),(2023). [Editor's Pick]
129.
S Sahu, T Srivastava, and Rajan Jha,” Plexcitonic system for high photonic spin Hall effect”, Applied Physics Letters 123 (20),(2023).
128.
P Gorai, G Brambilla, and Rajan Jha” Fast, selective, and sensitive detection of 2, 4-dichlorophenol by an imprinted polymer functionalized core-offset U-shaped fiber sensor”, Optics Letters 48 (20), 5391-5394,(2023).
127.
P Mishra, PK Sahu, H Kumar, and Rajan Jha,” Human Pulse and Respiration Monitoring: Reconfigurable and Scalable Balloon-Shaped Fiber Wearables”, Advanced Materials Technologies, 2300429
126.
P Gorai, Y Mizuno, M Kumar, and Rajan Jha,” Molecular Imprinting Polymer Nanoparticles Coupled with an Optical Sensor for Sensitive and Label-Free Detection of p‑Cresol”, ACS Applied Nano Materials
125.
P Mishra, K Chatterjee, H Kumar, and Rajan Jha,” Flexible and wearable photonic-crystal fiber interferometer for physiological monitoring and healthcare”, ACS Applied Optical Materials 1 (2), 569-577
124.
S Sahu, and Rajan Jha,” Efficient Coupling of Single Photons into Tilted Nanofiber Bragg Gratings”, Indian Journal of Pure & Applied Physics (IJPAP) 61 (7), 546-553
123.
A K Maurya, R Kumar, V Arumuru, and Rajan Jha,” An all-optical system for transit time estimation in fluids using single source and detector”, IEEE Transaction on instrumentation and measurements.
122.
Sarita, Rajan Jha, and R K Singh,” Tightly focused linearly and radially polarized beam effect on the LSPR peak with varying particle size”, Physica Scripta 98 (11), 115523 (2023)
121.
M Muthumanikkam, A Vibisha, MC Lordwin Prabhakar, P Suresh, K B Rajesh, Z Jaroszewicz,, and Rajan Jha,” Numerical Investigation on High-Performance Cu-Based Surface Plasmon Resonance Sensor for Biosensing Application”, Sensors 23 (17), 7495 (2023)
120.
GA Vibisha, MG Daher, SMH Rahman, Z Jaroszewicz, KB Rajesh, and Rajan Jha,” Designing high sensitivity and high figure of merit SPR biosensor using copper and 2D material on CaF2 prism”, Results in Optics 11, 100407 (2023)
119.
P Maheswari, V Ravi, KB Rajesh, SMH Rahman, and Rajan Jha,” High performance SPR biosensor using Cu-Pt bimetallic layers and 2D materials.”, Digest Journal of Nanomaterials & Biostructures 18 (1) (2023)
118.
M Pandaram, R Veeran, RK Balasundaram, Z Jaroszewicz, and Rajan Jha,” Hybrid Structured (Cu-BaTiO3-BP-Graphene) SPR Biosensor for Enhanced Performance”, Plasmonics 18 (1), 385-393 (2023)
117.
W Zhang, R Singh, Z Wang, G Li, Y Xie, R Jha, C Marques, B Zhang, and S. Kumar,” Humanoid shaped optical fiber plasmon biosensor functionalized with graphene oxide/multi-walled carbon nanotubes for histamine detection”, Optics Express 31 (7), 11788-11803 (2023)
2022
116.
P. Mishra, H. Kumar, S. Sahu, and Rajan Jha,” Flexible and Wearable Optical System Based on U-shaped cascaded microfiber Interferometer”, Advanced Materials Technologies, 2200661 (2022)
115.
S Sahu, KP Nayak, and Rajan Jha, “ Optimization of nanofiber gratings for efficient single-photon collection", Journal of Optics, 24 (11), 115401 (2022)
114.
S. Murmu, A. Kumar, and Rajan Jha, “ Unidirectional Photon Coupling Using Asymmetric Diamond Emitters with Enhanced Spontaneous Emission” Advanced Quantum Technologies, 5 (2022)
113.
K. Chatterjee, V Arumuru, D Patil, and Rajan Jha,” Multipoint Monitoring of Instantaneous Amplitude, Frequency, Phase and Sequence of Vibrations Using Concatenated Modal Interferometers”, Scientific Reports, 12(3798), (2022)
112.
P Gorai, S Kumar, C Marques, PK Singh, and Rajan Jha, " Imprinted Polymer Functionalized Concatenated Optical Microfiber: Hypersensitive and Selective" IEEE Sensors Journal 23 (1), 329-336
111.
A. Kumar, S. Sahu, and Rajan Jha, "Small Angles Vector Magnetometer Based on Anisotropic Ferromagnetic Nanofluid Functionalized Fiber Interferometer" Journal of Physics D: Applied Physics 55 (40), 405102 (2022)
110.
G. Yadav, S. Sahu,R. Kumar,and Rajan Jha, "Bound States in the Continuum Empower Subwavelength Gratings for Refractometers in Visible", MDPI Photonics, 9(5), 292, 2022
109.
T. Srivastava, S. Chitriv, S. Sahu, P. Gorai, and Rajan Jha, "Photonic Spin Hall Effect in Hybrid Tamm Plasmon Polariton" Journal of Applied Physics, 132, 203103 (2022)
108.
S. Khamari, A. Kumar, N. Mohapatra, and Rajan Jha, “ NiFe2O4 Ferrofluid to Detect Magnetic Field Tunability Using Microfiber Interferometry, IEEE Sensors, 99 (2022)
107.
B. Maharana, Rajan Jha, and S Chatterjee "Metal oxides as buffer layers for CZTS based solar cells: A numerical analysis by SCAPS-1D software." Optical Materials 131C, 112734 (2022)
106.
T. Srivastava, and Rajan Jha, "On the performance of 2D materials based plexcitonic sensor: Numerical Analysis" Journal of Physics: Condensed Matter 51 (3), 034002 (2022)
105.
M Pandaram, R Veeran, RK Balasundaram, Z Jaroszewicz, Rajan Jha, and H Rahman, "Hybrid Structured (Cu-BaTiO3-BP-Graphene) SPR Biosensor for Enhanced Performance." Plasmonics 1-9 (2022)
104.
Y Wang, R Singh, M Li, R Min, Q Wu, BK Kaushik, Rajan Jha, B Zhang, and S Kumar "Cardiac Troponin I Detection using Gold/Cerium-Oxide Nanoparticles assisted Hetro-Core Fiber Structure." IEEE Transactions on NanoBioscience 11 (3) (2022)
103.
M Pandaram, S Santhanakumar, R Veeran, RK Balasundaram, Rajan Jha, and Z. Jaroszewicz "Platinum Layers Sandwiched Between Black Phosphorous and Graphene for Enhanced SPR Sensor Performance." Plasmonics 17 (1) (2022)
102.
GA Vibisha, MG Daher, SMH Rahman, Z Jaroszewicz, KB Rajesh, and Rajan Jha, "Sensitivity Enhancement of Surface Plasmon Resonance-based Biosensor using Aluminium-Cobalt-Tungsten Disulfide-Graphene Heterostructure" J. Environ. Nanotechnol 11 (4), 05-13 (2022)
101.
P Maheswari, V Ravi, KB Rajesh, and Rajan Jha "High-Performance Bimetallic (Cu-Co) Surface Plasmon Resonance Sensor using Hybrid Configuration of 2D Materials." J. Environ. Nanotechnol 11 (3) (2022)
100.
B. Ortaç, D Jain, Rajan Jha, J Hu, and B Ung, “Specialty optical fiber modeling, fabrication, and characterization: introduction”, Journal of Optical Society of America B, (2022)
2021
99.
K. Chatterjee, S. K. Pal and Rajan Jha,” Reconfigurable Optical Magnetometer for Static and Dynamic Fields”, Advanced Optical Materials 9(3), (2021).
98.
P. Gorai and Rajan Jha,”Articial Receptor-Based Optical Sensors (AROS): Ultra-Sensitive Detection of Urea ”, Advanced Photonics Research, 2 (2021).
97.
S. Murmu, A. Kumar, and Rajan Jha, “Bidirectional Coupling of Diamond Emitters to Optical Nanowire: Tuneable and Efficient” JOSA B, 38(12) (2021)
96.
S.Dass,K. Chatterjee,S. Kachhap, Rajan Jha , “In reflection metal coated diaphragm based Microphone using PCF modal interferometer”, Journal of Lightwave Technology, 39(12), (2021)
95.
B Maharana , S Ratha , A S. Shajahan , B Chakraborty , Rajan Jha, and S Chatterjee, "High Charge-Storage Performance of Morphologically Modified Anatase TiO2: Experimental and Theoretical Insight", Physical Review Applied, 15(3), (2021)
94.
S. Dass and Rajan Jha, “Under Water Low Acoustic Frequency Detection Based on In-line Mach-Zehnder Interferometer”, Journal of Optical Society of America B, 38(2), (2021).
93.
Z Wang, R Singh, C Marques, Rajan Jha, B Zhang, and S Kumar, “Taper-in-taper fiber structure-based LSPR sensor for alanine aminotransferase detection”, Opt. Exp., 29(26) (2021).
92.
P. Maheswari, S. Subanya, A. Nisha, V. Ravi, K. B. Rajesh, and Rajan Jha, “Sensitivity enhancement of SPR sensor using Ni/ZnO nanocomposite assisted with graphene”, Optical and Quantum Electronics, 53 (2021).
91.
T. R KDora, R.Gouda, A.Sahadevan, A. HemaChand, Rajan Jha, P.S.De, R.S.Kottada, N.Nayan and S.Gollapudi, “Investigations into sample geometry effects on the superelastic and fatigue behavior of Nitinol: Modeling and experiments”, materialia, 29(26) (2021).
90.
S Kumar, Z Guo, R Singh, Q Wang, B Zhang, S Cheng, F Z Liu, C Marques, B K Kaushik, and Rajan Jha, “MoS2 Functionalized Multicore Fiber Probes for Selective Detection of Shigella Bacteria Based on Localized Plasmon”, Journal of Lightwave Technology , 39(12), (2021).
89.
T Srivastava, and Rajan Jha,”Tailoring Surface Plasmon-Exciton Polariton for High-Performance Refractive Index Monitoring”, Journal of Optics, 23(4), (2021).
88.
H. Gupta, V. Arumuru, and Rajan Jha, “Industrial Fluid Flow Measurement using Optical Fiber Sensors: A review”, IEEE Sensors Journal 21(6) ,7130 - 7144, (2021)
87.
Y Wang, G Zhu, M Li, R Singh, C Marques, R Min, BK Kaushik, B Zhang, Rajan Jha and S. Kumar,” Water pollutants p-Cresol detection based on Au-ZnO nanoparticles modified tapered optical fiber”, IEEE Transactions on NanoBioscience, 32(1), (2021).
86.
G. Zhu, Y. Wang, Z. Wang, R. Singh, C. Marques, Q. Wu, B K Kaushik, Rajan Jha, B. Zhang, and S. Kumar,” Localized Plasmon Based Multicore Fiber Biosensor for Acetylcholine Detection”, IEEE Transactions on Instrumentation and Measurement , (2021).
85.
S. Das , A. Kumar , A. Kumar , J. Singh , Rajan Jha , M. Kumar,” UV Light Detection Using Resonance Frequency of Piezoelectric Quartz Crystal”, IEEE Transactions on Electron Devices 68 (6), 2791-2795 (2021).
2020
84.
T. Srivastava, and Rajan Jha, “Plexcitonic nose based on an organic semiconductor”, Applied Physics Letters 117 (9), 093301, (2020).
83.
R. Singh, S. Kumar, F. Z. Liu, C. Shuan, B. Zhang, Rajan Jha, B.K. Kaushik, “Etched multicore fiber sensor using copper oxide and gold nanoparticles decorated graphene oxide structure for cancer cells detection”, Biosensors and Bioelectronics 168, 112557, (2020).
82.
S. Kumar, G. Zhu, R. Singh, Q. Wang, B. Zhang, S. Cheng, F.Z. Liu, C. Marques, B. K. Kaushik, Rajan Jha, “MoS2 Functionalized Multicore Fiber Probes for Selective Detection of Shigella Bacteria based on Localized Plasmon”, Journal of Lightwave Technology (2020).
81.
V. Arumuru, A. Kodam, Rajan Jha, “Bi-Directional Interferometric Flowmeter with Linear Sensitivity and Large Dynamic Range”, IEEE Transactions on Instrumentation and Measurement, (2020).
80.
K. V. Sreekanth, P. Mahalakshmi, S. Han, D. Vigneswaran, M. S. Mani Rajan, Rajan Jha, and R. Singh, “A terahertz Brewster switch based on superconductor hyperbolic metamaterial”, Journal of Applied Physics, 128, 173106 (2020).
79.
N. Agrawal, C. Saha, C. Kumar, R. Singh, B. Zhang, Rajan Jha, S. Kumar, "Detection of L-Cysteine using Silver Nanoparticles and Graphene Oxide Immobilized Tapered SMS Optical Fiber Structure”, IEEE Sensors Journal, 20(19),11372 – 11379, (2020).
78.
J. N. Dash, Rajan Jha, R Das,” Micro-air cavity incorporated tapered-tip photonic crystal fiber based compact refractometer”, Laser Physics Letters 17 (5), 055101, (2020).
77.
G. A. Vibisha, J. K. Nayak, P. Maheswari, N. Priyadharsini, A. Nisha, R. Rajesh, Rajan Jha,” Sensitivity enhancement of surface plasmon resonance sensor using hybrid configuration of 2D materials over bimetallic layer of Cu–Ni”, Optics Communications 463, 125337, (2020).
2019
76.
A. M. Shrivastav, G. Sharma, and Rajan Jha, “Hypersensitive and Selective Biosensing based on Microfiber Interferometry and Molecular Imprinted Nanoparticles”, Biosensor and Bioelectronics, 141, 111347, (2019).
75.
V. Arumuru, J.N. Dash, D. Dora and Rajan Jha,”Vortex Shedding Optical Flowmeter based on Photonic Crystal Fiber”, Scientific Report, 9, 8313-7 (2019).
74.
J. N. Dash, Rajan Jha and R. Das, “Enlarge-Tapered, Micro-air Channelled Cavity for Refractive Index Sensing in SMF”, Journal of Lightwave Technology, DOI, 10.1109/JLT.2019.2935083, (2019).
73.
G. Sharma, A. M. Shrivastav, A.Kumar, and Rajan Jha, “Non-graphene two-dimensional nanosheets for temperature sensing based on microfiber interferometric platform: Performance analysis”, Sensors and Actuators A, 289, 180–187 (2019).
72.
S. Dass, S. Kachhap, Rajan Jha, “Hearing the Sounds of Aquatic Life Using Optical Fiber Micro-tip based Hydrophone", IEEE Transactions on Instrumentation and Measurement, DOI: 10.1109/TIM.2019.2943732 (2019).
2018
71.
A. M. Shrivastav, G. Sharma, A. Rathore and Rajan Jha, “Hypersensitive and selective interferometric nose for ultra-trace ammonia detection with fast response utilizing PANI@SnO2 nanocomposite”, ACS Photonics, (2018).
70.
S. Dass and Rajan Jha, “Micro-tip Cantilever as Low Frequency Microphone”, Nature Scientific Report, 8, 12701-7 (2018).
69.
T. Srivastava and Rajan Jha, “Black phosphorus: a new platform for gaseous sensing based on surface plasmon resonance”, Photonics Technology Letters 30(4), 319-322 (2018).
68.
G. Sharma, A M Shrivastava, A Jana, Rajan Jha, “Synthesized Fe3O4 Nanoflowers Coated Microfiber as Magnetometer”, Photonics Technology Letters 30(22), 1925-1928 (2018).
67.
J. K. Nayak and Rajan Jha, “Graphene-oxide coated Ag-island based Inline LSPR fiber sensor”, Photonics Technology Letters, 30 (19), 1667-1670 (2018).
66.
S. Dass and Rajan Jha “Bending Sensor Based on Square Knot Resonator”, Photonics Technology Letters, 30 (18), 1649-1652 (2018).
65.
J. N. Dash, R. Das and Rajan Jha, “AZO Coated Microchannel Incorporated PCF-Based SPR Sensor”, Photonics Technology Letters, 30 (11), 1032-1035 (2018).
2017
64.
S. Dass and Rajan Jha, “Tapered Fiber Attached Nitrile Diaphragm Based Acoustic Sensor”, Journal of Lightwave Technology, 35 (24), 5411-5417 (2017).
63.
J. N. Dash, N. Negi and Rajan Jha, "Graphene Oxide Coated PCF Interferometer for Enhanced Strain Sensitivity”, Journal of Lightwave Technology, 35(24), 5385-5390 (2017).
62.
J. N. Dash, and Rajan Jha, “Cascaded Taper Collapsed Region Based PCF Sensor: Wavelength and Intensity Interrogation”, IEEE Sensor Journal, 17(24), 8338-8342 (2017).
61.
J. N. Dash, and Rajan Jha, “Fabrication of Inline Fiber Micro Air Cavity with Choice Based Dimensions”, Photonics Technology Letters, 29(14), 1147-1150 (2017).
60.
J. K. Nayak, and Rajan Jha, “Numerical simulation on the performance analysis of a graphene-coated optical fiber plasmonic sensor at anti-crossing”, Applied Optics, 56(12), 3510-3517, (2017).
59.
J. K. Nayak, P. K. Maharana, and Rajan Jha, “Dielectric over-layer assisted graphene, its oxide and MoS2-based fibre optic sensor with high field enhancement”, Journal of Physics D: Applied Physics, 50, 405112 (2017).
58.
J. N. Dash, S. Dass and Rajan Jha, “Microfiber Assisted Highly Birefringent PCF Based Interferometric Sensors”, IEEE Sensor Journal, 17(5), 1342 (2017).
2016
57.
J. N. Dash, and Rajan Jha, "Fabry-Perot Cavity on Demand for Hysteresis Free Interferometric Sensors”, Journal of Lightwave Technology, 34(13), 3188 (2016).
56.
J. N. Dash, and Rajan Jha, "Temperature insensitive PCF interferometer coated with graphene oxide tip sensor", Photonics Technology Letters, 28 (9), 1006 (2016).
55.
J. N. Dash, and Rajan Jha, “Mach–Zehnder interferometer based on tapered PCF with an up-tapered joint for curvature, strain and temperature interrogation”, Journal of Optics 18, 105002-08 (2016). (Chosen as Journal of Optics Paper of the Week)
54.
J. K. Nayak, P. Parhi and Rajan Jha, “Experimental and Theoretical studies on Localized Surface Plasmon Resonance based Fiber optic Sensor using Graphene oxide coated Silver nanoparticles”, Journal of Physics D: Applied Physics, 49, 285101 (2016).
53.
A. Pattnaik, J. K. Nayak, K. Senthilnathan and Rajan Jha, “Localized Plasmon based optical fiber sensing platform for operation in Infrared”, Photonics Technology Letters, 28(19), 2054 (2016).
52.
S. Dass, and Rajan Jha, “Microfiber Wrapped Bi-conical Tapered SMF for Curvature Sensing”, IEEE Sensor Journal, 16 (10), 3649-3652, (2016).
51.
S. Dass, J. N. Dash and Rajan Jha, “Photonic Crystal Fiber Microcavity Based Bend and Temperature Sensor Using Micro Fiber”, Sensors and Actuators A, 244, 24–29 (2016).
50.
P. Padhy, P. K. Sahu and Rajan Jha, “Metal Wire Waveguide Based All Plasmonic Refractive Index Sensor for Terahertz Frequencies", Sensors and Actuators B, 225, 115-120 (2016).
49.
S. Dass, and Rajan Jha, “Micrometer wire assisted Inline Mach-Zehnder Interferometric Curvature Sensor”, Photonics Technology Letters, 28(1), 31-34 (2016).
48.
S. Dass, J. N. Dash and Rajan Jha, “Intensity modulated SMF cascaded tapers with hollow core PCF based micro cavity for curvature sensing”, Journal of Optics, 18 (2016) 035006, (2016).
47.
A. Purkayastha, and Rajan Jha, “Ultrasensitive THz – Plasmonics gaseous sensor using doped graphene”, Sensors and Actuators B, 227, 291-295 (2016).
2015
46.
J. N. Dash, Rajan Jha, J. Villatoro and S. Dass, “Nano-displacement sensor based on photonic crystal fiber modal interferometer”, Optics Letters, 40 (3), (2015).
45.
J. N. Dash, and Rajan Jha, "Inline Microcavity Based PCF Interferometer for Refractive Index and Temperature sensing", Photonics Technology Letters, 27(12), 1325-1328 (2015).
44.
P.K. Maharana, Rajan Jha, Punnag Padhy, “On the Electric Field Enhancement and Performance of SPR Gas Sensor based on Graphene for Visible and near Infrared”, Sensors and Actuators B, 207, 117-122, (2015).
43.
J. N. Dash, and Rajan Jha, “Fabry–Perot based strain insensitive photonic crystal fiber modal interferometer for inline sensing of refractive index and temperature”, Applied Optics, 54 (35), 10479-10486, (2015).
42.
J. K. Nayak, P. Parhi and Rajan Jha, "Graphene oxide encapsulated gold nanoparticles based stable fiber optic sucrose sensor", Sensors and Actuators B, 221, 835-841, (2015).
41.
A Patnaik, K Senthilnathan, Rajan Jha, “Graphene Based Conducting Metal Oxide Coated D-Shaped Optical Fiber SPR Sensor”, Photonics Technology Letters, 27 (23), 2437-2440, (2015).
40.
R. Das, T. Srivastava, and Rajan Jha, “On the performance of Tamm-plasmon and surface-plasmon hybrid-mode refractive-index sensor in metallo-dielectric heterostructure configuration”, Sensors and Actuators B, 206, 443-448, (2015).
39.
T. Srivastava, R. Das, P. Padhy and Rajan Jha, “THz mode-coupling in photonic-crystal-surface-plasmon-coupled waveguides”, Applied Physics B, 118, 387–392, (2015).
38.
J. N. Dash, and Rajan Jha, “On the performance of Graphene Based D- shaped Photonic Crystal Fiber Biosensor using Surface Plasmon Resonance”, Plasmonics, 10, 1123-1131, (2015).
37.
J. N. Dash, and Rajan Jha, “Refractometry Based on Macrobending Using Photonic Crystal Fiber Modal Interferometer”, IEEE Sensors Journal, 15(9), 5291-5295, (2015).
2006-2014
36.
R. Das, T. Srivastava, and Rajan Jha, "Tamm-plasmon and surface-plasmon hybrid-mode based refractometry in photonic bandgap structures", Optics Letters, 39(4), 896-899 (2014).
35.
J. N Dash and Rajan Jha, “Graphene-Based Birefringent Photonic Crystal Fiber Sensor Using Surface Plasmon Resonance”, Photonics Technology Letters, 26 (11), 1092-1095, (2014).
34.
J. N Dash and Rajan Jha, "SPR Biosensor based on Polymer PCF coated with conducting metal oxide", Photonics Technology Letters, 26 (6), 595-598, (2014).
33.
P.K. Maharana, T. Srivastava, Rajan Jha, “Low index dielectric mediated surface plasmon resonance sensor based on graphene for near infrared measurements”, J. Phys. D: Appl. Phys., 47, 385102 (2014).
32.
R. Das, A. Pandey, T. Srivastava, and Rajan Jha, " Guided-Mode Analysis of Tamm-Plasmon Polariton at Metal–Heterostructure Dielectric Interface", Journal of Lightwave Technology, 32(6), 1221-1227 (2014).
31.
P.K. Maharana, Rajan Jha, S. Palei, "Sensitivity enhancement by air mediated graphene multilayer based surface plasmon biosensor for near infrared", Sensors and Actuators B, 190, 494-501 (2014).
30.
P.K. Maharana, T. Srivastava, Rajan Jha, " On the performance of highly sensitive and accurate graphene on aluminium and silicon based SPR biosensor for visible and near infrared", Plasmonics, 9, 1113-1120 (2014).
29.
P.K. Maharana, T. Srivastava, Rajan Jha, "Ultrasensitive plasmonic Imaging biosensor based on graphene and Silicon", Photonics Technology Letters, 25(2), 122-125 (2013).
28.
P.K. Maharana, P. Padhy, Rajan Jha, "On the field enhancement and performance of an ultra-stable SPR biosensor based on graphene", Photonics Technology Letters, 25(22), 2156-2159 (2013).
27.
T. Srivastava, R. Das, Rajan Jha, "Mode coupling between surface plasmon modes and band gap guided modes: A comprehensive study and applications", Journal of Lightwave Technology, 31(22), 3518-3524 (2013).
26.
P.K. Maharana, S. Bhardwaj, Rajan Jha, "Electric field enhancement in surface plasmon resonance bimetallic configuration based on chalcogenide prism", Journal of Applied Physics, 114, 014304-4 (2013).
25.
T. Srivastava, R. Das, Rajan Jha, "Highly sensitive plasmonic temperature sensor based on photonic crystal surface plasmon waveguide”, Plasmonics, 8, 515-521 (2013).
24.
P.K. Maharana and Rajan Jha, " Chalcogenide Prism and Graphene Multilayer based Surface Plasmon Resonance affinity Biosensor for High Performance, Sensors and Actuators B, 169, 161-166 (2012).
23.
T. Srivastava, Rajan Jha and R. Das, "High-performance bimetallic SPR sensor based on photonic crystal-waveguides ", Photonics Technology Letters, 23(20), 1448-1450 (2011).
22.
R. Verma, B. D. Gupta and Rajan Jha, "Sensitivity enhancement of a surface plasmon resonance based biomolecules sensor using graphene and silicon layers" Sensors and Actuators B, 160, 623-631 (2011).
21.
T. Srivastava, R. Das and Rajan Jha, "Highly Accurate and Sensitive Surface Plasmon Resonance Sensor based on Channel Photonic Crystal Waveguides", Sensors and Actuators B, 157, 246-252 (2011).
20.
Rajan Jha and A. K. Sharma, “Design considerations for plasmonic-excitation based optical detection of liquid and gas media in infrared”, Sensors and Actuators A, 165(2), 271-275 (2011).
19.
T. Srivastava, R. Das and Rajan Jha, "Design considerations and propagation characteristics of channel Bragg-plasmon-coupled-waveguides", Applied Physics Letters, 97, 213104 (2010).
18.
Rajan Jha and A. K. Sharma, “Design of silicon based plasmonic biosensor chip for human blood group detection”, Sensors and Actuators B, 145, 200-204 (2010).
17.
Na Lou, Rajan Jha, J. L. Dominguez, V. Finazi, J. Villatoro, G. Badenes, and V. Pruneri, “Embedded optical micro-nano-fiber for stable devices”, Optics Letters, 35(4), 571-573 (2010).
16.
Anuj K. Sharma, Rajan Jha and H. S. Pattanaik, “Design consideration for surface plasmon resonance sensor based detection of human blood group in near infrared”, Journal of Applied Physics, 107, 034107 (2010). (Selected for Virtual Journal of Biological Physics Research)
15.
Rajan Jha, and A. K. Sharma “SPR based infrared detection of aqueous and gaseous media with silicon substrate”, Europhysics Letters, 87, 10007 (2009).
14.
Rajan Jha and A. K. Sharma, “Chalocogenide glass prism based SPR sensor with Ag-Au bimetallic nanoparticles alloy in infrared wavelength regime”, Journal of Optics, 11, 045502 (2009).
13.
J. Villatoro, M. Kruzer, Rajan Jha, V. Minkovich, V. Finnazi, G. Badenes and V. Pruneri, “Photonic crystal fiber interferometer for chemical vapor detection with high sensitivity”, Optics Express, 17(3), 1447-1453 (2009).
12.
Rajan Jha, J. Villatoro, G. Badenes, and V. Pruneri, “Refractometry based on photonic crystal fiber interferometer”, Optics Letters, 34(5), 617-619 (2009).
11.
Rajan Jha and A. K. Sharma, “High performance sensor based on surface plasmon resonance with chalcogenide prism and aluminum for detection in infrared”, Optics Letters, 34(6), 749-751 (2009).
10.
Rajan Jha and G. Badenes, “Effect of fiber core dopant concentration on the performance of surface plasmon resonance based fiber optic sensor”, Sensors and Actuators A, 150, 212-217 (2009).
9.
R. Das and Rajan Jha, “On the modal characteristic of surface plasmon polaritons at a metal Bragg interface at optical frequencies”, Applied Optics, 48, 4904-4908 (2009).
8.
A. K. Sharma and Rajan Jha, “SPR based gas sensor with chalcogenide glass and bimetallic alloy nanoparticles layer”, Journal of Applied Physics, 106, 103101 (2009).
7.
Rajan Jha, J. Villatoro and G. Badenes, “Ultra stable in reflection photonics crystal fiber modal interferometer for accurate refractive index sensing”, Applied Physics Letters, 93, 191106 (2008).
6.
Rajan Jha, R. K. Verma and B.D. Gupta, “Surface plasmon resonance-based tapered fiber optic sensor: Sensitivity enhancement by introducing a Teflon layer between core and metal layer”, Plasmonics, 3, 151-156 (2008).
5.
A. K. Sharma, Rajan Jha and B.D. Gupta, “Fiber optic sensors based on surface plasmon resonance: A comprehensive review”, IEEE Sensors Journal, 7, 1118-1129 (2007).
4.
Rajan Jha, Subhash Chand and B. D. Gupta, “Surface plasmon resonance based fiber-optic sensor for detection of pesticide”, Sensors and Actuators B, 123, 661-666 (2007).
3.
A. K. Sharma, Rajan Jha and B. D. Gupta, “Influence of different dopants on the performance of a fiber optic SPR sensor”, Optics Communications, 274, 320-326 (2007).
2.
Rajan Jha, A. K. Sharma and B. D. Gupta, “Fiber optic sensor based on long-range surface plasmon resonance: A theoretical analysis”, Journal of Optics, 9, 682-687 (2007).
1.
Rajan Jha, S. Chand and B. D. Gupta, “Fabrication and characterization of a surface plasmon resonance based fiber-optic sensor for bittering component-naringin”, Sensors and Actuators B, 115, 344-348 (2006).
Patents
P13.
Rajan Jha, and Arvind Kumar Maurya, “A System and Method for Remotely Tuning the Sensitivity in Optical Fiber- Interferometers”,Application No..
P12.
Rajan Jha, and M M Mohapatra , “Fiber laser interferometry based stress measurement device.”,Application No.202531031072.
P11.
Rajan Jha, Arvind Kumar Maurya, and Rishi Raj, “Optical System and Method for Capturing Acoustic Emissions in Harsh Environment.”,Application No.202431039103.
P10.
Rajan Jha, Kalipada Chatterjee, Arvind Kumar Maurya, Sumit Dass, and Umesh Chandra Sahoo, “Traffic Monitoring Method and Weigh in Motion System Using Processed Optical Fiber Interferometers.”, Application no. 202331053335.
P9.
Rajan Jha, Arvind Kumar Maurya, and Kalipada Chatterjee, “Portable interferometry system for real-time surface profiling and displacement measurement with large dynamic range.”, Application no. 202331051062.
P8.
Rajan Jha,Kalipada Chatterjee ,Pratik Mishra, and Hemant Kumar, “An Optical System For Physiological Activity Monitoring.”, Application no. 202231014885.
P7.
Rajan Jha, Hemant Kumar, and Pratik Mishra, “Reconfigurable Optical Interferometer Based Wearable, Skin Mountable, and Multifunctional Flexible Sensor System”, Application no. 202131053181.
P6.
Rajan Jha, Venugopal Arumuru, Kalipada Chatterjee, and Subrat Sahu, "Optical System and Method for Active Modulation of Optical Signals." Application no. 202131047683
P5.
Rajan Jha, Venugopal Arumuru and Kalipada Chatterjee, “A System and Method for Multipoint Sensing”, Application number 202031053901.[Granted]
P4.
Rajan Jha, Venugopal Arumuru and Dhrubraj Dora, “A modal interferometer based system to improve performance of vortex flowmeter and a method thereof”, Application no. 201831019721. [Granted]
P3.
Rajan Jha and Jitendra Naryan Dash, “Fabrication process for tuning the major and minor axis of Inline Fiber Micro Air Cavity on demand”, Application no. 201731009380. [Granted]
P2.
Rajan Jha and Sumit Dass, “Optical fiber microphone/hydrophone based on cascaded single mode fiber tapers”, Application no. 201731014677.
P1.
Rajan Jha, Jitendra Narayan Dash and Sumit Dass, “Micro-g accelerometer based on solid core photonic crystal fiber modal interferometer”, Application no. 201631016588. [Granted]
Conferences
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S. Sahu, K. P. Nayak, & Rajan Jha, “Single-Sided Cavity QED Effect on an Optical Nanowire.”, Frontiers in Optics Laser Science (FIO + LS 2024), Denver, Colorado, USA, (2024).
A. Maurya, K. Chatterjee, & Rajan Jha, “Topographical Characterization System Using Fiber-based Interferometers’ Combination.”, Frontiers in Optics Laser Science (FIO + LS 2024), Denver, Colorado, USA, (2024).
K. Chatterjee, & Rajan Jha, “Real Time Dynamic Physical Field Monitoring Using Optical Interferometric Systems.”, International Conference on Advances in Optics and Photonics Instrumentation (OPTOIn 2024), CSIO-CSIR Chandigarh, India, (2024). [Best Thesis Award]
B. K. Patra, P. Gorai, A. Kumar, & Rajan Jha, “Selective Detection of Food Adulterant Using Photonic Crystal Fiber based Interferometer.”, International Conference on Advances in Optics and Photonics Instrumentation (OPTOIn 2024), CSIO-CSIR Chandigarh, India, (2024).
P. Mishra, H. Kumar, & Rajan Jha, “Cavity-Based Ultrasensitive Wearable System for Health Monitoring.”, International Conference on Advances in Optics and Photonics Instrumentation (OPTOIn 2024), CSIO-CSIR Chandigarh, India, (2024).
S. Sahu, K. P. Nayak, & Rajan Jha, “One-Sided Optical Nanofiber Cavity: A Novel Workbench for Cavity-QED.”, PHOTONICS 2024, IIT Kharagpur, India, (2024). [Best Paper]
P. Mishra, H. Kumar, & Rajan Jha, “An Advanced Optical Wearable Technology for Healthcare.”, PHOTONICS 2024, IIT Kharagpur, India, (2024).
T. Srivastava, S. Sahu, & Rajan Jha, “Enhanced Photonic Spin Hall Effect in Plexcitonic System.”, PHOTONICS 2024, IIT Kharagpur, India, (2024).
S. Sahu, K. P. Nayak, & Rajan Jha, “One-sided Slotted Photonic Crystal Nanofiber for Cavity QED.”, CLEO - 2024, Charlotte, NC, USA, (2024).
S. Sahu, K. P. Nayak, & Rajan Jha, “Slotted Photonic Crystal Optical Nanofiber for Cavity QED.”, OPTIQ - 2023, CUSAT, Kerala, India, (2023). [Best Paper]
S. Murmu, A. Kumar, & Rajan Jha, “Fano line-shaped transmission and emission coupling in hybrid optical nanowire structure.”, OPTIQ - 2023, CUSAT, Kerala, India, (2023). [Best Paper]
A. K. Maurya, R. Kumar, & Rajan Jha, “Time-Resolved Monitoring of Disturbance Propagation with Autocorrelation Fiber Interferometry.”, OPTIQ - 2023, CUSAT, Kerala, India, (2023).
S. Sahu, & Rajan Jha, “Slotted Photonic Crystal Nanofiber for Cavity QED.”, FIO + LS 2023, Tacoma, USA, (2023).
P. Mishra, H. Kumar, & Rajan Jha, “Comparative Analysis of Jacket Coated and Uncoated Arched SMF Based Health Monitoring System.”, FIO + LS 2023, Tacoma, USA, (2023).
S. Sahu, & Rajan Jha, “Ultrawide Wavelength Tunability Using Lesser Grating Periods in Optical Nanowire.”, Photonics 2023, IISc Bengaluru, India, (2023).[Best Paper]
K. Chatterjee, A. K. Maurya, & Rajan Jha, “Integrated Modal and Cavity Interferometer for Ultrasensitive Magnetometry.”, Photonics 2023, IISc Bengaluru, India, (2023). [Best Paper]
P. Mishra, H. Kumar, & Rajan Jha, “Arched Fiber Interferometry Based Wearable System for Health Monitoring.”, Photonics 2023, IISc Bengaluru, India, (2023). [Best Paper]
P. Gorai, & Rajan Jha, “Selective Detection of Melamine Using Misalignment Fiber Interferometer.”, Photonics 2023, IISc Bengaluru, India, (2023).
P. Gorai, & Rajan Jha, “Fiber Optic Interferometry Based Water Pollutant Detection.”, ICMOCE - 2023, IIT Bhubaneswar, India, (2023). [Best Paper]
K. Chatterjee, & Rajan Jha, “Optical Magnetometer for Dynamic Magnetic Field Monitoring.”, ICMOCE - 2023, IIT Bhubaneswar, India, (2023).
P. Mishra, H. Kumar, & Rajan Jha, “Double Micro Fiber Based Optical Wearable System.”, ICMOCE - 2023, IIT Bhubaneswar, India, (2023).
A. K. Maurya, R. Kumar, & Rajan Jha, “Temperature-Insensitive PCF-Based Low Amplitude Vibration Sensor for Broad Frequency Application.”, ICMOCE - 2023, IIT Bhubaneswar, India, (2023).
S. Sahu, & Rajan Jha, “Optical Nanowire Gratings: An Efficient Single Photon Collector and Refractometer.”, ICMOCE - 2023, IIT Bhubaneswar, India, (2023).
S. Murmu, A. Kumar, & Rajan Jha, “Elliptical Faceted Diamond Nanowire for Higher Coupling with Bidirectional Tunable.”, ICMOCE - 2023, IIT Bhubaneswar, India, (2023).
S. Sahu, & Rajan Jha, “Single Photon Source Integrated with Optical Nanowire for Quantum Applications.”, Research Scholar’s Day - 2023, IIT Bhubaneswar, India, (2023).
S. Murmu, A. Kumar, & Rajan Jha, “Diamond Impurities Integrated with Optical Waveguide for Quantum Applications.”, Research Scholar’s Day - 2023, IIT Bhubaneswar, India, (2023).
P. Mishra, H. Kumar, & Rajan Jha, “Light Empowered Next-Gen Wearable Devices for Healthcare.”, Research Scholar’s Day - 2023, IIT Bhubaneswar, India, (2023).
K. Chatterjee, & Rajan Jha, “Series Combination of Modal Interferometers for Detecting Independent Vibration Fields and Their Sequence.”, COPaQ 2022, IIT Roorkee, India, (2022).
P. Gorai, & Rajan Jha, “Imprinted Polymer Functionalized PCF Sensor for Water Pollutant: Hypersensitive and Selective.”, COPaQ 2022, IIT Roorkee, India, (2022).
S. Sahu, & Rajan Jha, “Unidirectional Coupling of Single Photon in Optical Nanofiber with Inline Cavity.”, COPaQ 2022, IIT Roorkee, India, (2022).
P. Mishra, K. Chatterjee, H. Kumar, & Rajan Jha, “Cardiac Monitoring with Modal Interferometer Based Wearable System.”, COPaQ 2022, IIT Roorkee, India, (2022).
S. Murmu, A. Kumar, & Rajan Jha, “Non-conventional Transmission and Reflection in Asymmetric Diamond Nanowire.”, COPaQ 2022, IIT Roorkee, India, (2022).
K. Chatterjee, & Rajan Jha, “Optical Systems from Lab to Land.”, Research Scholar Day, IIT Bhubaneswar, India, (2022).
P. Gorai, & Rajan Jha, “Hypersensitive Optical Systems for Specific Biochemical Detection.”, Research Scholar Day, IIT Bhubaneswar, India, (2022).
S. Sahu, & Rajan Jha, “Efficient Single-Photon Coupling to Optical Nanofiber with Inline Cavity.”, Frontiers in Optics and Photonics 2021, IIT Delhi, India, (2021).
P. Mishra, K. Chatterjee, H. Kumar, & Rajan Jha, “Wearable Optical Sensor Based on Photonic Crystal Fiber Interferometer.”, Frontiers in Optics and Photonics 2021, IIT Delhi, India, (2021).
K. Chatterjee, & Rajan Jha, “Optical Magnetometer for Field Measurements.”, International Conference on Optics and Electro-optics, DRDO, Dehra Dun, India, (2019).
P. Gorai, & Rajan Jha, “Tapered Fiber for Biochemical Detection.”, International Conference on Optics and Electro-optics, DRDO, Dehra Dun, India, (2019).
K. Chatterjee, & Rajan Jha, “Generation of Optical Vortices Using Standard Single Mode Fiber.”, Topical Meeting on Advances in Photonics, NISER Bhubaneswar, India, (2019).
P. Gorai, & Rajan Jha, “Optical Fiber Based Sensor for Urea Detection Using Molecular Imprinting Polymer.”, Topical Meeting on Advances in Photonics, NISER Bhubaneswar, India, (2019).
S. Dass, & Rajan Jha, “Microfiber Attached Polymer Diaphragm as a Versatile Microphone.”, JSAP–OSA Joint Symposia 2018, Nagoya, Japan, (2018).
S. Dass, & Rajan Jha, “Fabrication and Theoretical Analysis of Square Knot Resonator for Sensing Applications.”, IEEE Workshop on Recent Advances in Photonics (WRAP), Hyderabad, India, (2017).
S. Dass, S. Halder, J. Sharma, & Rajan Jha, “Fiber Cantilever Based Acoustic Sensor.”, Frontiers in Optics 2017, Washington, D.C., United States, (2017).
J. N. Dash, & Rajan Jha, “Fabrication of Fiber Based Inline Micro Air Cavities with Tunable Geometrical Parameters.”, Frontiers in Optics 2017, Washington, D.C., United States, (2017).
J. K. Nayak, & Rajan Jha, “Fiber Optic Biosensor for the Detection of Bovine Serum Albumin Using Graphene Oxide.”, Frontiers in Optics 2017, Washington, D.C., United States, (2017).
S. Dass, & Rajan Jha, “Diaphragm Based Single Mode Fiber Taper Acoustic Sensor.”, European Conference on Lasers and Electro-Optics, Munich, Germany, (2017).
J. N. Dash, & Rajan Jha, “Photonic Crystal Fiber Based Interferometric Sensor with Macro Bending.”, International Conference on Fiber Optics and Photonics, IIT Kanpur, India, (2016).
J. N. Dash, & Rajan Jha, “Dual Tapered Photonic Crystal Fiber Based Curvature and Temperature Sensor.”, International Conference on Fibre Optics and Photonics, IIT Kanpur, India, (2016).
J. N. Dash, & Rajan Jha, “Refractometer Using Microcavity Based PCF Modal Interferometer.”, Workshop on Recent Advances in Photonics, IISc Bangalore, India, (2015).
J. N. Dash, & Rajan Jha, “Polymer PCF Based SPR Sensor Using Indium Tin Oxide.”, International Conference on Optics and Photonics, Calcutta, India, (2015).
A. Purkayastha, & Rajan Jha, “Terahertz Plasmonics Based Gaseous Sensing with Graphene Monolayer.”, International Conference on Optics and Photonics, Calcutta, India, (2015).
J. N. Dash, S. Dass, & Rajan Jha, “Highly Birefringent PCF Based Micro-Displacement Sensor Using Tapered Fiber.”, Laser Science Conference, San Jose, California, USA, (2015).
J. K. Nayak, S. Dass, P. Parhi, & Rajan Jha, “Graphene Oxide Based Fiber Optic SPR Biosensor for Sucrose Sensing.”, International Conference on Optics and Photonics, Calcutta, India, (2015).
P. K. Maharana, T. Srivastava, & Rajan Jha, “Graphene Based Low Loss Surface Plasmon Resonance Biosensor in Visible.”, International Conference on Optics and Photonics, Calcutta, India, (2015).
S. Dass, J. N. Dash, M. Manjunatha, & Rajan Jha, “Interferometry Based Accelerometer for Micro-g Sensing.”, International Conference on Optics and Photonics, Calcutta, India, (2015).
J. N. Dash, Rajan Jha, & S. Dass, “Ultrasensitive Displacement Sensor Based on Photonic Crystal Fiber Modal Interferometer.”, Advanced Photonics, Barcelona, Spain, (2014).
J. N. Dash, & Rajan Jha, “Photonic Crystal Fiber Based Interferometric Sensor with Macro Bending.”, 12th International Conference on Fiber Optics and Photonics, IIT Kharagpur, India, (2014).
P. K. Maharana, T. Srivastava, & Rajan Jha, “Low Loss Surface Plasmon Excitation in Graphene Based Dielectric-Metal-Dielectric Configuration.”, 12th International Conference on Fiber Optics and Photonics, IIT Kharagpur, India, (2014).
R. Das, T. Srivastava, & Rajan Jha, “Accurate Refractive-Index Sensing with Tamm-Plasmon and Surface-Plasmon Based Hybrid Configurations.”, 12th International Conference on Fiber Optics and Photonics, IIT Kharagpur, India, (2014).
S. Dass, J. N. Dash, & Rajan Jha, “Optical Accelerometer Based on Multiple Interferometry for Milli-g Range.”, Conference on Recent Trends in Information Optics and Quantum Optics, IIT Patna, India, (2014).
J. N. Dash, & Rajan Jha, “Graphene Based D-Shaped Photonic Crystal Fiber Sensor Using Surface Plasmon Resonance.”, ICOL-2014, Dehradun, India, (2014).
Rajan Jha, J. N. Dash, & S. Dass, “Highly Stable PCF Based Nanodisplacement Sensor.”, IOQO-2014, Patna, India, (2014).
P. K. Maharana, & Rajan Jha, “Enhancing Performance of SPR Sensor Through Electric Field Intensity Enhancement Using Graphene.”, Workshop on Recent Advances in Photonics (WRAP), New Delhi, India, (2013).
J. N. Dash, & Rajan Jha, “PCF Based Graphene Coated SPR Biosensor.”, Workshop on Recent Advances in Photonics (WRAP), New Delhi, India, (2013).
P. K. Maharana, & Rajan Jha, “Plasmonic Biosensor Based on Graphene Multilayer.”, XXXVII National Symposium of Optical Society of India, Pondicherry, India, (2013).
P. K. Maharana, S. Pillai, & Rajan Jha, “Graphene Based Long Range Surface Plasmon Resonance Sensor for Near Infrared.”, XXXVII National Symposium of Optical Society of India, Pondicherry, India, (2013).
P. Padhy, & Rajan Jha, “Nanosphere as a Parallel Combination of Nanoinductor and Nanocapacitor.”, XXXVII National Symposium of Optical Society of India, Pondicherry, India, (2013).
P. Padhy, & Rajan Jha, “Nanocircuits: Extending Circuit Theory to Optical Regime.”, Recent Trends in Laser and Photonics, Ravenshaw University, Cuttack, Bhubaneswar, India, (2013).
Rajan Jha, T. Srivastava, & R. Das, “Photonic Crystal Surface Plasmon Waveguide Sensors for High and Accurate Temperature Measurement.”, 3rd Asia Pacific Optical Fiber Sensors Conference (APOS), Sydney, Australia, (2012).
R. Das, T. Srivastava, & Rajan Jha, “Avoided-Crossings in Dispersion Properties of Photonic-Crystal-Surface-Plasmon-Waveguides.”, PHOTONICS 2012, Chennai, India, (2012).
P. K. Maharana, T. Srivastava, & Rajan Jha, “Surface Plasmon Resonance Imaging Biosensor Based on Graphene Multilayer.”, PHOTONICS 2012, Chennai, India, (2012).
S. Bharadwaj, P. K. Maharana, R. Das, & Rajan Jha, “Effect of Chalcogenide Glass and Plasmonic Metal on Electric Field Enhancement in Surface Plasmon Resonance Sensor.”, PHOTONICS 2012, Chennai, India, (2012).
R. Das, Rajan Jha, & T. Srivastava, “Resonant Mode-Coupling at Anti-Crossing Points in the Regime.”, Frontiers in Optics and Photonics (FOP 2011), IIT Delhi, India, (2011).
T. Srivastava, R. Das, & Rajan Jha, “High Performance Bragg Plasmon Coupled Waveguide Sensor.”, FOP 2011, IIT Delhi, India, (2011).
Rajan Jha, T. Srivastava, & R. Das, “Photonic Crystal Surface Plasmon Waveguide Sensors for Temperature Measurement.”, FOP 2011, IIT Delhi, India, (2011).
Rajan Jha, R. Das, & T. Srivastava, “Photonic Crystal Waveguide Based SPR Sensor.”, PHOTONICS 2010, IIT Guwahati, India, (2010).
Rajan Jha, & R. Das, “SPR Based Liquid and Gaseous Detection in Infrared with Single Silicon Chip.”, PHOTONICS 2010, IIT Guwahati, India, (2010).
R. Das, Rajan Jha, & T. Srivastava, “Channeled Bragg-Plasmon-Coupled-Waveguide.”, PHOTONICS 2010, IIT Guwahati, India, (2010).
Rajan Jha, & A. K. Sharma, “Highly Accurate Surface Plasmon Resonance Based Fiber Optic Sensor as a Human Blood Group Identifier.”, 2010 Sensors Topical Meeting, Karlsruhe, Germany, (2010).
N. Lou, Rajan Jha, J. L. Domínguez-Juárez, V. Finazzi, J. Villatoro, & V. Pruneri, “Stable Devices Based on Embedded Optical Micro-Nano-Fibers.”, OFC 2010, San Jose, United States, (2010).
J. Villatoro, Rajan Jha, & G. Badenes, “Photonic Crystal Fiber Modal Interferometers for Accurate Refractometry.”, Fiber Optic Sensors and Applications VI, Orlando, Florida, USA, (2009).
Rajan Jha, J. Villatoro, M. Kruzer, V. Finazzi, & V. Pruneri, “Highly Versatile in Reflection Photonic Crystal Fiber Interferometer.”, 20th International Conference on Optical Fiber Sensors (OFS-20), Edinburgh, United Kingdom, (2009).
Rajan Jha, & A. K. Sharma, “Surface Plasmon Resonance Based High Performance Chalcogenide Glass Sensor.”, International Conference on Optics and Photonics (ICOL), Chandigarh, India, (2009).
Rajan Jha, & G. Badenes, “Surface Plasmon Resonance Based Chalcogenide Fiber Optic Sensor for Higher Accuracy.”, PHOTONICS 2008, New Delhi, India, (2008).
Rajan Jha, R. K. Verma, & B. D. Gupta, “Surface Plasmon Resonance Based Tapered Fiber Optic Probe with Teflon Layer Between Metal and Fiber Core.”, PHOTONICS 2008, New Delhi, India, (2008).
Rajan Jha, S. Chand, & B. D. Gupta, “Fiber-Optic Biosensor Based on Surface Plasmon Resonance for the Detection of Organophosphate - Chlorpyrifos.”, BIOHORIZON 2007, New Delhi, India, (2007).
Rajan Jha, S. Chand, & B. D. Gupta, “Fiber-Optic Sensor Based on Surface Plasmon Resonance for Organophosphate Detection.”, PHOTONICS 2006, Hyderabad, India, (2006).
Rajan Jha, S. Chand, & B. D. Gupta, “Surface Plasmon Resonance Based Fiber-Optic Sensor for Pesticide Detection.”, 18th International Conference on Optical Fiber Sensors, Cancun, Mexico, (2006).
Rajan Jha, S. Chand, & B. D. Gupta, “Surface Plasmon Resonance Based Fiber-Optic Sensor for Detection of Pesticides.”, International Conference on Optics and Optoelectronics (ICOL-2005), Dehradun, India, (2005).
Rajan Jha, S. Chand, & B. D. Gupta, “Surface Plasmon Resonance Based Fiber-Optic Sensor for Detection of Bittering Component - Naringin.”, PHOTONICS 2004, Cochin, Kerala, India, (2004).