Journal papers
The updated list is on Google Scholar. Wherever possible, the drafts are provided here.
[22] S Beniwal and C Chandraprakash, “Alumina-copper woodpile-kind locally resonant phononic crystal,” Applied Physics A, vol. 129, no. 844, 1--7 (2023) [html]
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[21] T Bhuvana, A Tiwari, and C Chandraprakash, “Green fabrication of cellulose-rich agricultural residues for scalable and biodegradable acoustic boards,” Industrial Crops and Products, vol. 204, no. 117404, 1--10 (2023) [html].
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[20] V Sharma and C Chandraprakash, “Fabrication and bandgaps of microscale metallic phononic crystals,” International Journal of Advances in Engineering Sciences and Applied Mathematics, vol. 15, no. 4, 159--166 (2023) [html].
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[19] A Kumar and C Chandraprakash, “Computer vision-based on-site estimation of contact angle from 3D reconstruction of droplets,” IEEE Transactions on Instrumentation and Measurement, vol. 72, no. 2524108, 1--8 (2023) [html].
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[18] B M Bharti, T Bhuvana, and C Chandraprakash, “Burst and physicochemical characteristics of glycerol-added chitosan films for food packaging,” ACS Food Science & Technology, vol. 3, no. 4, 772--780 (2023) [html].
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[17] S Kumar, K Jahan, A Verma, M Agarwal, and C Chandraprakash, “Agar-based composite films as effective biodegradable sound absorbers,” ACS Sustainable Chemistry & Engineering, vol. 10, no. 26, 8242--9253 (2022) [html].
This has been picked by the ACS editors for the ACS News. The work is also highlighted in the international and national science news: Phys.org, ScienceDaily, Technologynetworks, Eurekalert, Swifttelecast, Chemistryviews, New Atlas, ScienMag, Bioengineer.org, Miragenews, and Natureworld. It also attracted attention to the seaweed and music communities.
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[16] V Sharma and C Chandraprakash, “Quasi-superhydrophobic microscale two-dimensional phononic crystals of stainless steel 304,” Journal of Applied Physics, vol. 131, no. 18, 184901 (2022) [html]
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[15] C Chandraprakash, V C Venugopal, A Lakhtakia, and O O Awadelkarim, “Long-wavelength infrared characteristics of multifunctional microfibrous thin films of Parylene C,” Microwave Optics and Technology Letters, vol. 61, no. 9, 2206--2209 (2019) [html]
[14] C Chandraprakash, C V Krishnamurthy, and K Balasubramaniam, “Thermomechanical phenomenon -- A non-destructive evaluation perspective,” Transactions of the Indian Institute of Metals, vol. 72, no. 11, 2905--2915 (2019) [html]
Before IITK
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[13] I H Khawaji, C Chandraprakash, O O Awadelkarim, and A Lakhtakia, “Selectablity of mechanical and dielectric properties of Parylene-C columnar microfibrous thin films by varying deposition angle,” Flexible and Printed Electronics, vol. 2, no. 4, 045012 (2017) [html]
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[12] I H Khawaji, C Chandraprakash, O O Awadelkarim, and A Lakhtakia, “Dielectric properties of and charge transport in columnar microfibrous thin films of Parylene C,” IEEE Transactions on Electron Devices, vol. 64, no. 8, 3360--3367 (2017) [html]
[11] C Chandraprakash, A Lakhtakia, and O O Awadelkarim, “Parylene-C microfibrous thin films as phononic crystals,” Journal of Micromechanics and Microengineering, vol. 27, no. 7, 075012 (2017) [html]
[10] C Chandraprakash, A Lakhtakia, N R Brown, W Orfali, and O O Awadelkarim, “Temperature-dependent dynamic mechanical moduli of microfibrous columnar thin films of Parylene C,” Polymer Testing, vol. 53, 89--97 (2016) [html]
[9] C Chandraprakash, A Lakhtakia, and O O Awadelkarim, “Reply to comment on surface energy of Parylene C,” Materials Letters, vol. 166, 325--326 (2016) [html]
[8] C Chandraprakash, A Lakhtakia, O O Awadelkarim, and W Orfali, “Relative permittivity of bulk Parylene-C in the infrared regime,” Journal of Electromagnetic Waves and Applications, vol. 29, no. 16, 2139--2146 (2015) [html]
[7] C Chandraprakash, A Lakhtakia, and O O Awadelkarim, “Surface energy of Parylene C,” Materials Letters, vol. 153, 18--19 (2015) [html]
[6] C Chandraprakash, N M Wonderling, A Lakhtakia, O O Awadelkarim, and W Orfali, “Microfiber inclination, crystallinity, and water wettability of microfibrous thin-film substrates of Parylene C in relation to the direction of the monomer vapor during fabrication,” Applied Surface Science, vol. 345, 145--155 (2015) [html]
[5] Y Xie, C Chandraprakash, N Nama, S Yang, M Lu, Y Zhao, J D Mai, F Costanzo, and T J Huang, “Exploring bubble oscillation and mass transfer enhancements in acoustic-assisted liquid-liquid extraction with a microfluidic device,” Scientific Reports, vol. 5, no. 12572 (2015) [html]
[4] C Chandraprakash, A Lakhtakia, N R Brown, W Orfali, and O O Awadelkarim, “Frequency-and temperature-dependent storage and loss moduli of microfibrous thin films of Parylene C,” Materials Letters, vol. 116, 296--298 (2014) [html]
[3] C Chandraprakash, A Lakhtakia, O O Awadelkarim, and W Orfali, “Acoustic scattering from microfibers of Parylene C,” Journal of Applied Physics, vol. 116, no. 13, 134905 (2014) [html]
[2] C Chandraprakash, N Nama, M I Lapsley, F Costanzo, and T J Huang, “Theory and experiment on resonant frequencies of liquid-air interfaces trapped in microfluidic devices,” Journal of Applied Physics, vol. 114, no. 19, 194503 (2013) [html]
[1] C Chandraprakash, C V Krishnamurthy, K Balasubramaniam, and R V Prakash, “Thermomechanical response of metals: Maxwell vs. Kelvin--Voigt models,” Materials Science and Engineering: A, vol. 560, 54--61 (2013) [html]