The booming economy of Bangladesh in recent times has created a significant need for energy. Consequently, the increasing demand for power generation has led Bangladesh to become more reliant on fossil fuels. This paper highlights the current situation of the power sector in Bangladesh, proposes practical steps that can be taken to tackle the increasing energy demands and discusses the current state of research taking place in Bangladesh regarding the development of photovoltaic solar cells and the potential for thin-film solar cells to effectively harness solar energy. The use of different kinds of plasmonic metal nanoparticles (NPs) such as core-shell NPs, NP dimers made of metallic alloys and hybrid bow-tie shaped NPs with thin-film solar cells are discussed. These nanoparticles are found to significantly improve the efficiency of thin-film solar cells. The societal, environmental, and health impact of shifting from traditional fossil fuel-based energy resources towards harnessing renewable energy, primarily solar energy using thin-film solar cells is also discussed. The paper concludes with a discussion on the economic sustainability of using such proposed high efficiency thin-film solar cells so that such technologies may help lead Bangladesh towards a cleaner, greener and more secure future.

Bangladesh; plasmonics; renewable energy; solar cells; thin-film solar cells

Asian Development Bank, 2020. Bangladesh: Economy. Retrieved from the World Wide Web: https://www.adb.org/countries/bangladesh/economy.

Tetra Tech ES, Inc., 2020. Challenges in the development of variable renewable energy in Bangladesh. Arlington, VA: USAID.

Kannan N. and D. Vakeesan, 2016. Solar energy for future world: A review. Renewable and Sustainable Energy Reviews 62: 1092-1105.

Green M.A., Dunlop E.D., Levi D.H., Hohl‐Ebinger J., Yoshita M. and Ho‐Baillie A.W., 2019. Solar cell efficiency tables (version 54). Progress in Photovoltaics: Research and Applications 27(7): 565-575.

Catchpole K.A. and A. Polman, 2008. Plasmonic solar cells. Optics Express 16(26): 21793-21800.

Meier J., Vallat-Sauvain E., Dubail S., Kroll U., Dubail J., Golay S., Feitknecht L., Torres P., Fay S., Fischer D. and Shah A., 2001. Microcrystalline/ micromorph silicon thin-film solar cells prepared by VHF-GD technique. Solar Energy Materials and Solar Cells 66(1-4): 73-84.

Ferry V.E., Sweatlock L.A., Pacifici D. and Atwater H.A., 2008. Plasmonic nanostructure design for efficient light coupling into solar cells. Nano Letters 8(12): 4391-4397.

Hägglund C., Zäch M., Petersson G. and Kasemo B., 2008. Electromagnetic coupling of light into a silicon solar cell by nanodisk plasmons. Applied Physics Letters 92(5): 053110.

Ashraf N.I., Shaky M.M., Rifat R.A. and Chowdhury M.H., 2019. Use of plasmonic metal core-dielectric shell composite nanoparticles embedded within the absorbing layer to enhance the efficiency of thin-film solar cells. In Proceedings of the 2019 IEEE Region 10 Symposium (TENSYMP) 479-484.

Choudhury S.A. and M.H. Chowdhury, 2016. Use of plasmonic metal nanoparticles to increase the light absorption efficiency of thin-film solar cells. In Proceedings of the 2016 IEEE International Conference on Sustainable Energy Technologies (ICSET) 196-201.

Choudhury S.A., Nawshin N. and Chowdhury M.H., 2017. Influence of particle shape on the efficacy of plasmonic metal nanoparticles to enhance the energy conversion efficiency of thin-film solar cells. In Proceedings of TENCON 2017-2017 IEEE Region 10 Conference 2393-2398.

Arefin S.M.N, Islam S., Fairooz F., Hasan J., and Chowdhury M.H., 2020. Computational study of “sandwich” configuration of plasmonic nanoparticles to enhance the optoelectronic performance of thin-film solar cells (Article in Press). In Proceedings of the 2020 IEEE Region 10 Symposium (TENSYMP).

Shaky M.M. and M.H. Chowdhury, 2019. Use of novel hybrid plasmonic nanoparticle complexes to increase the efficiency of thin-film solar cells. In Proceedings of the TENCON 2019-2019 IEEE Region 10 Conference (TENCON) 203-208.

Fairooz F., Hasan J., Arefin S.M.N., Islam S., and Chowdhury M.H., 2020. Use of plasmonic nanoparticles made of aluminum and alloys of aluminum to enhance the optoelectronic performance of thin-film solar cells (Article in Press). In Proceedings of the 2020 IEEE Region 10 Symposium (TENSYMP).

BPDB, 2019. Annual Report 2018-19. Power Division, Misinstry of Power, Energy and Mineral Resources, Government of Bangladesh.

PETROBANGLA, 2019. Annual Report 2018. Energy and Mineral Resources Division, Misinstry of Power, Energy and Mineral Resources, Government of Bangladesh.

Dudley B., 2019. BP Statistical Review of World Energy. London, UK: BP Statistical Review.

PSMP, 2016. Power System Master Plan 2016. Power Division, Misinstry of Power, Energy and Mineral Resources, Government of Bangladesh.

IQAir, 2020. Dhaka Air Quality Index (AQI) and Bangladesh Air Pollution - Airvisual. Retrieved from the World Wide Web: www.iqair.com/us/bangladesh/dhaka.

Mondal M.A.H. and M. Denich, 2010. Assessment of renewable energy resources potential for electricity generation in Bangladesh. Renewable and Sustainable Energy Reviews 14(8): 2401-2413.

Kabir E., Kim K.H. and Szulejko J.E., 2017. Social impacts of solar home systems in rural areas: A case study in Bangladesh. Energies 10(10): 1615.

Mohammad H., 2013. Achieving sustainable energy targets in Bangladesh. UN Chronicle 52(3): 36-39.

Shah R. and N. Mithulananthan, 2009. Interconnection of PV based generator and its impact on Bangladesh power system stability. In Proceedings of the 2009 1st International Conference on the Developments in Renewable Energy Technology (ICDRET). Dhaka, Bangladesh, 17-19 December. IEEE.

Ahmed M., Parvez M. S., Hossain M.M., Pal A.K., Hassan H.M.I., and Iqbal M.S., 2015. Minimization of power shortage by using renewable solar energy through smart grid, perspective: Bangladesh. In Proceedings of the 2015 3rd International Conference on Green Energy and Technology (ICGET). Dhaka, Bangladesh, 11-11 September. IEEE.

Ahmed A. and M.I. Rony, 2014. Towards a novel sensorless dual axis solar tracking algorithm for Bangladeshi PV modules. In Proceedings of the 17th International Conference on Computer and Information Technology (ICCIT). Dhaka, Bangladesh, 22-23 December. IEEE.

Paul S., Khan M.K.A., Adibullah M., and Anzum S.N., 2013. Determination of optimal angle for maximum power of a PV module under Bangladeshi climatic condition. In Proceedings of the 2013 International Conference on Energy Efficient Technologies for Sustainability. Nagercoil, India, 10-12 April. IEEE.

Ahmed S., Mia M.M.A., Acharjee S., and Ansary M.A.A., 2014. More efficient use of photovoltaic solar panel using multiple fixed directed mirrors or aluminum foils instead of solar trackers in rural perspective of Bangladesh. International Journal of Scientific and Technology Research 3(4): 294-298.

Hasan M.M., Hasan N., and Rahman M., 2018. Observation of fuel cell technology and upgraded photovoltaic system for rural telecom system in Bangladesh. Bangladesh Army University of Engineering and Technology Journal 2(2): 71-78.

Mahmud T., Reja M.I., and Akhtar J., 2018. Photovoltaic performance analysis of plasmonic solar cell based on Ti and Pt nanoparticles and different spacer layer thicknesses. In Proceedings of the 2018 International Conference on Computer, Communication, Chemical, Material and Electronic Engineering (IC4ME2) 1-5. IEEE.

Hossain M.I., Qarony W., Hossain M.K., Debnath M.K., Uddin M.J., and Tsang,Y.H., 2017. Effect of back reflectors on photon absorption in thin-film amorphous silicon solar cells. Applied Nanoscience, 7(7): 489-497.

Islam Z. and M.Z. Islam, 2017, December. Plasmonic solar cell with annular apertures and Ag grating supporting fabry-perot modes. In Proceedings of the 2017 IEEE International Conference on Telecommunications and Photonics (ICTP) 259-262. IEEE.

Islam M.Z., Snigdha F., and Hasan M.S., 2018, March. Plasmonically-enhanced absorption in organic solar cells with metal nanostructures. In Proceedings of the 2018 9th International Renewable Energy Congress (IREC) 1-5. IEEE.

Winans J.D., Hungerford C., Shome K., Rothberg L.J., and Fauchet P.M., 2015. Plasmonic effects in ultrathin amorphous silicon solar cells: performance improvements with Ag nanoparticles on the front, the back, and both. Optics Express 23(3): A92-A105.

Isabella O., Vismara R., Linssen D.N.P., Wang K.X., Fan S., and Zeman M., 2018. Advanced light trapping scheme in decoupled front and rear textured thin-film silicon solar cells. Solar Energy 162: 344-356.

Lee C., Bae S.Y., Mobasser S., and Manohara H., 2005. A novel silicon nanotips antireflection surface for the micro sun sensor. Nano Letters 5(12): 2438-2442.

Lee Y.J., Ruby D.S., Peters D.W., McKenzie B.B., and Hsu J.W., 2008. ZnO nanostructures as efficient antireflection layers in solar cells. Nano Letters 8(5): 1501-1505.

Bouhafs D., Moussi A., Chikouche A., and Ruiz J.M., 1998. Design and simulation of antireflection coating systems for optoelectronic devices: Application to silicon solar cells. Solar Energy Materials and Solar Cells 52(1-2): 79-93.

Chen H.C., Lin C.C., Han H.W., Tsai Y.L., Chang C.H., Wang H.W., Tsai M.A., Kuo H.C., and Yu P., 2011. Enhanced efficiency for c-Si solar cell with nanopillar array via quantum dots layers. Optics Express 19(105): A1141-A1147.

Lin G.R., Chang Y.C., Liu E.S., Kuo H.C., and Lin H.S., 2007. Low refractive index Si nanopillars on

Si substrate. Applied Physics Letters 90(18): 181923.

Heidarzadeh H., Rostami A., Dolatyari M., and Rostami G., 2016. Plasmon-enhanced performance of an ultrathin silicon solar cell using metal-semiconductor core-shell hemispherical nanoparticles and metallic back grating. Applied Optics 55(7): 1779-1785.

Li J., Yu H., Li Y., Wang F., Yang M., and Wong S.M., 2011. Low aspect-ratio hemispherical nanopit surface texturing for enhancing light absorption in crystalline Si thin film-based solar cells. Applied Physics Letters 98(2): 021905.

Catchpole K.A. and A. Polman, 2008. Plasmonic solar cells. Optics Express 16(26): 21793-21800.

Hoener C.F., Allan K.A., Bard A.J., Campion A., Fox M.A., Mallouk T.E., Webber S.E., and White J.M., 1992. Demonstration of a shell-core structure in layered cadmium selenide-zinc selenide small particles by x-ray photoelectron and Auger spectroscopies. The Journal of Physical Chemistry 96(9): 3812-3817.

Zhou H.S., Sasahara H., Honma I., Komiyama H., and Haus J.W., 1994. Coated semiconductor nanoparticles: The CdS/PbS system's photoluminescence properties. Chemistry of Materials 6(9): 1534-1541.

Liu F., Qu D., Xu Q., Xie W., and Huang Y., 2011. Plasmonic core-shell nanoparticle-based thin film solar cells. In Proceedings of the SPIE 8011, 22nd Congress of the International Commission for Optics: Light for the Development of the World 80114J.

Fairooz F., Choudhury S.A., Ashraf N.I., Mahdi W., and Chowdhury M.H., 2019, February. Use of bimetallic plasmonic nanoparticle complexes for enhancing thin-film solar cell efficiency. In Proceedings of the 2019 International Conference on Electrical, Computer and Communication Engineering (ECCE) 1-6. IEEE.

Fairooz F., Arefin S.M.N., and Chowdhury M.H., 2019, December. Use of nanoparticles arrays made of alloys of plasmonic metals of varying compositions to enhance the opto-electronic performance of thin-film solar cells. In Proceedings of the 2019 International Conference on Innovation in Engineering and Technology (ICIET) (Article in Press). IEEE.

Shaky M.M., Ashraf N.I., Rifat R.A., and Chowdhury M.H., 2019. Use of hybrid bow-tie based plasmonic nanostructure to enhance the efficiencies of thin film solar cells. In Proceedings of the 2019 International Conference on Electrical, Computer and Communication Engineering (ECCE). Cox’s Bazar, Bangladesh, 7-9 February. IEEE.

Chaudhuri R.G. and S. Paria, 2012. Core/shell nanoparticles: Classes, properties, synthesis mechanisms, characterization, and applications. Chemical Reviews 112(4): 2373-2433.

Santbergen R., Liang R., and Zeman M., 2010. Amorphous silicon solar cells with silver nanoparticles embedded inside the absorber layer. MRS Online Proceedings Library Archive 1245.

International Energy Agency (IEA), 2011. CO2 Emissions from Fuel Combustion. Luxembourg: Imprimerie Centrale.

World Bank, 2015. World Development Indicators 2015. Washington D.C., USA: World Bank.

Hsu D.D., O’Donoughue P., Fthenakis V., Heath G.A., Kim H.C., Sawyer P., Choi J., and Turney D.E., 2012. Life cycle greenhouse gas emissions of crystalline silicon photovoltaic electricity generation: Systematic review and harmonization. Journal of Industrial Ecology 16: S122-S135.

Kim H.C., Fthenakis V., Choi J., and Turney D.E., 2012. Life cycle greenhouse gas emissions of thin‐film photovoltaic electricity generation: Systematic review and harmonization. Journal of Industrial Ecology 16: S110-S121.

Whitaker M., Heath G.A., O’Donoughue P., and Vorum, M., 2012. Life cycle greenhouse gas emissions of coal-fired electricity generation: Systematic review and harmonization. Journal of Industrial Ecology 16: S53-S72.

O'Donoughue P.R., Heath G.A., Dolan S.L., and Vorum M., 2014. Life cycle greenhouse gas emissions of electricity generated from conventionally produced natural gas: Systematic

review and harmonization. Journal of Industrial Ecology 18(1): 125-144.

Council C. and C. Council, 2020. 11 Countries Leading the Charge On Renewable Energy. Climate Council. Retrieved from the World Wide Web: https://www.climatecouncil.org.au/11-countries-leading-the-charge-on-renewable-energy/.

Mondal M.A.H., 2010. Economic viability of solar home systems: Case study of Bangladesh. Renewable Energy 35: 1125–1129.

SunShot, 2015. Photovoltaic System Pricing Trends. Historical, Recent, and Near-Term Projections, 2015 Edition. Washington, D.C., USA: SunShot, U.S. Department of Energy.

Sarti D. and R. Einhaus, 2002. Silicon feedstock for the multi-crystalline photovoltaic industry. Solar Energy Materials and Solar Cells 72(1-4): 27-40.

Green M.A., 2001. Crystalline silicon photovoltaic cells. Advanced Materials 13(12-13): 1019-1022.

Terheiden B., Ballmann T., Horbelt R., Schiele Y., Seren S., Ebser J., Hahn G., Mertens V., Koentopp M.B., Scherff M., and Muller J.W., 2015. Manufacturing 100‐μm‐thick silicon solar cells with efficiencies greater than 20% in a pilot production line. Physica Status Solidi (a) 212(1): 13-24.

Fthenakis V., 2009. Sustainability of photovoltaics: The case for thin-film solar cells. Renewable and Sustainable Energy Reviews 13(9): 2746-2750.