SN Applied Sciences
L. Fernando, K. Pemasiri, B.S. Dassanayake (2020). Combined effects of rice husk ash and nylon fiber on engineering properties of cement mortar, SN Applied Sciences
. SN Applied Sciences, 2 (3): 379.
DOI: https://link.springer.com/article/10.1007%2Fs42452-020-2198-1
Carbohydrate Polymers
J.W.M.E.S. Weerappuliarachchi, I.C. Perera, S.S. Gunathilakea, S.K.S. Thennakoon and B.S. Dassanayake (2020). Synthesis of cellulose microcrystals (CMC)/nylon 6,10 composite by incorporating CMC isolated from Pandanus ceylanicus. Carbohydrate Polymers, 241: 116227.
https://www.sciencedirect.com/science/article/abs/pii/S014486172030401X
Electrochimica Acta
M.A.K.L. Dissanayake, T. Liyanage, T. Jaseetharan, G.K.R. Senadeera and B.S. Dassanayake (2020). Effect of PbS quantum dot-doped polysulfide nanofiber gel polymer electrolyte on efficiency enhancement in CdS quantum dot-sensitized TiO2 solar cells. Electrochimica Acta, 347: 136311.
https://www.sciencedirect.com/science/article/pii/S0013468620307039
Int. J. Electrochem. Sci
S.A.D.R. Madhusanka, R.D.L. Sandaruwan, M. M. Athar, M. Zaib, Hashitha M.M. Munasinghe Arachchige, B.S. Dassanayake, M. Yoshio and N. Gunawardhana (2020). TiO2 Microparticles/Reduced Graphene Oxide Composite as Anode Material for Lithium Ion Battery. Int. J. Electrochem. Sci, 15: 2792 – 2805.
https://www.electrochemsci.org/papers/vol15/150302792.pdf
Silver nanowire-containing wearable thermogenic smart textiles with washing stability
K.B. Dhanawansha, R.
Senadeera, S.S. Gunathilake, B.S. Dassanayake (2020). Advances in nano research. Silver nanowire-containing wearable thermogenic smart textiles with washing stability, 9 (2): 123-131.
https://www.techno-press.org/content/?page=article&journal=anr&volume=9&num=2&ordernum=6
Semiconductors
R.K.K.G.R.G. Kumarasinghe,
W.G.C. Kumarage, R.P. Wijesundera, N. Kaur, E. Comini and B.S. Dassanayake (2020). A Comparative Study on CdS
Film Formation under Variable and Steady Bath-Temperature Conditions. Semiconductors, 54: 838–843.
DOI: https://link.springer.com/article/10.1134/S1063782620080126
Semicon. Sci. Technol.
W.G.C. Kumarage, R.P. Wijesundera, V.A. Seneviratne, C.P. Jayalath and B.S. Dassanayake, (2017). A study on the enhancement of optoelectronic properties of CdS thin films: seed-assisted fabrication, . Semicon. Sci. Technol., 32: 045014 (11pp).
Mat. Sci Semicon. Proc
P. K. K. Kumarasinghe, Amila Dissanayake, B. M. K. Pemasiri, and B. S. Dassanayake, (2017). Effect of post deposition heat treatment on microstructure parameters, optical constants and composition of thermally evaporated CdTe thin films,. Mat. Sci Semicon. Proc, 58: 51–60.
J Mater Sci: Mater Electron
P. K. K. Kumarasinghe, Amila Dissanayake, B. M. K. Pemasiri, and B. S. Dassanayake, (2016). Variation of optical, structural, electrical and compositional properties of thermally evaporated CdTe thin films due to substrate temperature,. J Mater Sci: Mater Electron, .
DOI: https://dx.doi.org/10.1007/s10854-016-5521-2
Nuclear Instruments and Methods in Physics Research
S.J. Wickramarachchi, T. Ikeda, D. Keerthisinghe, B.S. Dassanayake and J.A. Tanis, (2016). Incident energy and charge deposition dependences of electron transmission through a microsized tapered glass capillary,. Nuclear Instruments and Methods in Physics Research, 382: 60-66.
J. Phys. D: Appl. Phys.
W.G.C. Kumarage, R.P. Wijesundera, V.A. Seneviratne, C.P. Jayalath and B.S. Dassanayake, (2016). Tunable optoelectronic properties of CBD-CdS thin films via bath temperature alterations,. J. Phys. D: Appl. Phys., 49: 095109 (7pp).
Nuclear Instruments and Methods in Physics Research B
D. Keerthisinghe, B. S. Dassanayake, S. J. Wickramarachchi, N. Stolterfoht, and J. A. Tanis, (2016). Transmission of electrons through insulating PET foils: Dependence, on charge deposition, tilt angle and incident energy,. Nuclear Instruments and Methods in Physics Research B, 382: 67-70.
Proc. Engineering
W.G.C. Kumarage, K.I.H. Senevirathne, V.A. Seneviratne, C.P. Jayalath, B.S. Dassanayake, (2016). Influence of Bath Temperature on CBD-CdS Thin Films,. Proc. Engineering, 139: 64-68.
Phys. Rev. A
S.J. Wickramarachchi, T. Ikeda, B.S. Dassanayake, D. Keerthisinghe and J.A. Tanis, (2016). Electron-beam transmission through a micrometer-sized tapered-glass capillary: Dependence on incident energy and angular tilt angle,. Phys. Rev. A, 94: 022701.
Phys. Rev. A,
D. Keerthisinghe, B. S. Dassanayake, S. J. Wickramarachchi, N. Stolterfoht, and J. A. Tanis, (2015). Elastic and inelastic transmission of electrons through insulating polyethylene terephthalate nanocapillaries,. Phys. Rev. A,, 92: 012703.
4th International Conference on Structural Engineering and Construction Management
W.G.C. Kumarage, K.I.H. Senevirathne, V.A. Seneviratne, C.P. Jayalath, B.S. Dassanayake, (2013). Solution Grown CDS as a Window Layer for Solar Applications, Proceedings of the Special Session on Advanced Materials,. 4th International Conference on Structural Engineering and Construction Management, : 134.
Nuclear Instruments and Methods in Physics Research B
S.J. Wickramarachchi, T. Ikeda, D. Keerthisinghe, B.S. Dassanayake and J.A. Tanis, (2013). Angular dependence of electron transmission through a microsized tapered glass capillary,. Nuclear Instruments and Methods in Physics Research B, 317: 101-104.
Phys. Scr.
A. Ayyad, B.S. Dassanayake, D. Keerthisinghe1, T. Ikeda, A. Kayani and J.A. Tanis, (2013). Transmission of fast highly charged ions through straight and tapered glass capillaries,. Phys. Scr., T156: 014058.
AIP Conf. Proc.
D. Keerthisinghe, B. S. Dassanayake, S. Wickramarachchi, A. Ayyad, N. Stolterfoht and J. A. Tanis, (2013). Transmission and guiding of fast electrons through insulating PET nanocapillaries,. AIP Conf. Proc., 1525: 36.
Nuclear Instruments and Methods in Physics Research B
B. S. Dassanayake, D. Keerthisinghe, S. Wickramarachchi, A. Ayyad, S. Das, N. Stolterfoht and J. A. Tanis, (2013). Temporal evolution of electron transmission through insulating PET nanocapillaries,. Nuclear Instruments and Methods in Physics Research B, 298: 1-4.
Phys. Scr.
S. J. Wickramarachchi, B. S. Dassanayake, D. Keerthisinghe, T. Ikeda and J. A. Tanis, (2013). Dependence of electron transmission on charge deposited in tapered glass macrocapillaries at a tilt angle of 5.0o,. Phys. Scr., T156: 014057 (4pp).
Nuclear Instruments and Methods in Physics Research B
D. Keerthisinghe, B. S. Dassanayake, S. Wickramarachchi, N. Stolterfoht and J. A. Tanis, (2013). Charge dependence and energy loss of electrons transmitted through insulating nanocapillaries,. Nuclear Instruments and Methods in Physics Research B, 317: 105.
Phys. Rev. A
B.S. Dassanayake, S. Das, A. Ayyad, R.J. Bereczky, K. Tőkési and J.A. Tanis, (2011). Time evolution of electron transmission through a single glass macrocapillary: charge build-up, sudden discharge, and recovery. Phys. Rev. A, 83: 012707.
Nuclear Instruments and Methods in Physics Research B
B.S. Dassanayake, S. Das, A. Ayyad, R.J. Bereczky, K. Tőkési and J.A. Tanis, C (2011). harge evolution and energy loss associated with electron transmission through a macroscopic single glass capillary. Nuclear Instruments and Methods in Physics Research B, 269: 1243.
Physics Research B
G.G. De Silva, B.S. Dassanayake, D. Keerthisinghe, A. Ayyad and J.A. Tanis, (2011). Electron transmission through a micro size tapered glass capillary Nuclear Instruments and Methods in. Physics Research B, 269: 1248.
AIP Conference Proceedings
B.S. Dassanayake, S. Das, and J.A. Tanis, (2011). Inelastic transmission of electrons through a single macro-glass capillary and secondary electron emission,. AIP Conference Proceedings, 1336: 154.
AIP Conference Proceedings
A. Ayyad, B.S. Dassanayake, A. Kayani, and J.A. Tanis, (2011). Transmission of fast ions through a single macro-glass capillary. AIP Conference Proceedings, 1336: 91.
Phys. Scr.
B.S. Dassanayake, S. Das, and J.A. Tanis, (2011). Electron transmission through a single glass macro capillary: Dependence of energy and time,. Phys. Scr. , 2011: 014041.
Phys. Rev. A
B.S. Dassanayake, S. Das, R.J. Bereczky, K. Tőkési and J.A. Tanis, (2010). Energy dependence of electron transmission through a single glass macrocapillary,. Phys. Rev. A, 81,: 020701(R).
Revista Mexicana de Fisica
B.S. Dassanayake, S. Das, N. Stolterfoht, and J.A. Tanis, (2010). Guiding of Electrons Through Insulating PET Nanocapillaries,. Revista Mexicana de Fisica, S56 (2): 71.
Revista Mexicana de Fisica
S. Das, B.S. Dassanayake, N. Stolterfoht, and J.A. Tanis, (2010). Inelastic processes associated with electron guiding through insulating PET nanocapillaries,. Revista Mexicana de Fisica, S56 (2): 66.
AIP Conference Proceedings
B.S. Dassanayake, S. Das, A. Ayyad, A. Kayani, N. Stolterfoht, and J.A. Tanis, (2009). Guiding of electrons and fast ions through insulating nanocapillaries,. AIP Conference Proceedings, 1099: 125.
Nuclear Instruments and Methods Physics Research Section B
M. Winkworth, P.D. Fainstein, M.E. Galassi, J. Baran, B.S. Dassanayake, S. Das, A. Kayani and J.A. Tanis, (2009). Interferences in Electron Emission from O2by 30 MeV O5,8+ Impact,. Nuclear Instruments and Methods Physics Research Section B, 267: 373.
J. Phys.: Conf. Sr.
M. Winkworth, P.D. Fainstein, M.E. Galassi, J. Baran, S. Das, B.S. Dassanayake, A. Kayani and J.A. Tanis, (2009). Interference effects in electron emission spectra for 3 MeV/u H++ O2 collisions. J. Phys.: Conf. Sr., 163: 012044.
Phys. Rev. A
S. Das, B.S. Dassanayake, M. Winkworth, J.L. Baran, N. Stolterfoht, and J.A. Tanis, (2007). Inelastic guiding of electrons in polymer nanocapillaries,. Phys. Rev. A, 76: 042716.