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⭐Hall of fame⭐ - papers where OghmaNano has been used *

For key publications describing the development of the model click here.


[1] Wang S, "Simulation and optimization of c60-based organic light-emitting diodes", 1026, 142-146, 2021

[2] Ikyo B, Abutu F, Itodo A, "The effect of active layer thickness on the performance of tin halide perovskite (ch\_3nh\_3sni\_3)", Physics Memoir-Journal of Theoretical \& Applied Physics, 3, 48-57, 2021

[3] Mishra A, Shukla R, "Simulation of photovoltaic material (donor blends ptb7: pc70bm) polymer for solar cell application", Materials Today: Proceedings, 2021

[4] Ourahmoun O, "Effect of the interfacial materials on the performance of organic photovoltaic cells", Materials Today: Proceedings, 2021

[5] Sen S, Islam R, "Effect of different layers on the performance of p3ht: pcbm-based organic solar cell", Brazilian Journal of Physics, 1-9, 2021

[6] Tharun T, Manimegala A, Vasantharthan A, Vinitha N, Shenbagapriya M, "Optimization of layer thickness of htl free perovskite solar cell", i-Manager's Journal on Material Science, 8, 31, 2021

[7] Paramita M, "Simulasi pengaruh ketebalan perovskite terhadap nilai efisiensi pada sel surya perovskite", 2021

[8] Rachmadhana I, "Simulasi sel surya perovskite dengan penambahan double layer csi-perovskite", 2021

[9] Sadiq M, Khan M, Arif M, Naveed A, Ullah K, Afridi S, "Numerical investigation of a new approach based on perovskite ch3nh3pbi3 absorber layer for high-efficiency solar cells", Materials Research Express, 8, 095507, 2021

[10] Chakraborty K, Das A, Mandal R, Mandal D, "An analytical study on low voltage regime of natural organic semiconductor based device: physics of trap energy and ideality factor", Solid State Communications, 323, 114080, 2021

[11] Zidan M, Ismail T, Fahim I, "Effect of thickness and temperature on flexible organic p3ht: pcbm solar cell performance", Materials Research Express, 8, 095508, 2021

[12] Then F, Azhari A, Halin D, Sepeai S, Ludin N, "Simulation studies on thickness variation of perovskite absorption layer for solar cells application", 2339, 020071, 2021

[13] Wasule S, "Theory and analysis of the luminance of top-emitting and bottom-emitting oleds", 2021

[14] Zhu X, "Developing an analytical model for charge transport in organic solar cells through simulation of photocurrent", 2021

[15] Singh M, "Fabrication and simulation of multifunctional materials towards application in optoelectronic based biomedical devices", 2021

[16] Omrani M, Fallah H, Choy K, Abdi-Jalebi M, "Impact of hybrid plasmonic nanoparticles on the charge carrier mobility of p3ht: pcbm polymer solar cells", Scientific reports, 11, 1-12, 2021

[17] Neves L, Leite G, MacKenzie R, Ferreira R, Porto M, "A methodology to simulate solar cells electrical response using optical-electrical mathematical models and real solar spectra", Renewable Energy, 164, 968-977, 2021

[18] Lan Z, Zhu F, "Electrically switchable color-selective organic photodetectors for full-color imaging", ACS nano, 15, 13674-13682, 2021

[19] Palacios-G{\'o}mez D, Huerta Flores A, MacKenzie R, Pearson C, Alanazi F, Mendis B, Groves C, "Differing impacts of blended fullerene acceptors on the performance of ternary organic solar cells", ACS Applied Energy Materials, 2021

[20] Janghouri M, Jafari M, Norozi A, Mahmoudi M, "Fabrication of tunable color organic diode with thickness control of emission layer", Journal of Color Science and Technology, 15, 39-45, 2021

[21] Azman K, Idris M, Misran M, "Analysis of chitosan binder-based zno photoanode for dye-sensitized solar cell", INOTEK 2021, 1, 91-92, 2021

[22] Saha R, Chakraborty K, Choudhury M, Paul S, "Simulation study of formamidinium lead halide (fapbx3; x= i and br) based perovskite solar cells using scaps-1d device simulator", 2021

[23] Farooq W, Alshahrani T, Kazmi S, Iqbal J, Khan H, Khan M, Raja A, ur Rehman A, "Materials optimization for thin-film copper indium gallium selenide (cigs) solar cell based on distributed braggs reflector", Optik, 227, 165987, 2021

[24] Kumar A, Kumar R, Singh S, "Optimization of charge transport layer thickness for efficient perovskite solar cell", 193-202, 2021

[25] Bibi B, Farhadi B, ur Rahman W, Liu A, "A novel design of ctzs/si tandem solar cell: a numerical approach", 2021

[26] Bangash K, Kazmi S, Farooq W, Ayub S, Musarat M, Alaloul W, Javed M, Mosavi A, "Thickness optimization of thin-film tandem organic solar cell", Micromachines, 12, 518, 2021

[27] Rono N, Merad A, Kibet J, Martincigh B, Nyamori V, "A theoretical investigation of the effect of the hole and electron transport materials on the performance of a lead-free perovskite solar cell based on ch 3 nh 3 sni 3", Journal of Computational Electronics, 20, 993-1005, 2021

[28] Rodr{\'\i}guez-Mart{\'\i}nez X, San Jos{\'e} E, Campoy-Quiles M, "Accelerating organic solar cell material’s discovery: high-throughput screening and big data", Energy \& Environmental Science, 2021

[29] Maitra S, Halder S, Maitra T, Roy S, "Superior light absorbing cds/vanadium sulphide nanowalls@ tio 2 nanorod ternary heterojunction photoanodes for solar water splitting", New Journal of Chemistry, 45, 7353-7367, 2021

[30] Quandt A, Warmbier R, "Solar cell simulations based on ab initio methods", Optical Materials Express, 11, 1763-1779, 2021


[31] Mishra A, Shukla R, "Electrical and optical simulation of typical perovskite solar cell by gpvdm software", Materials Today: Proceedings, 2020

[32] Pawar A, Kadam P, Kamat R, Shinde S, "Modeling and simulation of zinc oxide anode based organic light emitting diode", Materials Today: Proceedings, 23, 230-235, 2020

[33] Hussain M, Khan S, Rahim A, Jan A, Rashid M, "Optimization of power conversion efficiency for perovskite solar cell using gpvdm", 2020

[34] Aasha D, Prince S, "Comparison of luminescence efficiency of materials in organic light emitting diode", 0952-0955, 2020

[35] Mekky A, "Electrical and optical simulation of hybrid perovskite-based solar cell at various electron transport materials and light intensity", 44, 179-184, 2020

[36] Abdallaoui M, Sengouga N, Chala A, Meftah A, Meftah A, "Comparative study of conventional and inverted p3ht: pcbm organic solar cell", Optical Materials, 105, 109916, 2020

[37] Mehmood S, Kaleem M, Nazir S, Israr A, Mirza H, "Numerical analysis of stable and low cost perovskite solar cell with an enhanced inorganic electron and hole transport layers", Journal of Nanoelectronics and Optoelectronics, 15, 725-733, 2020

[38] Patel D, "Temperature dependant performance of perovskite solar cell: a device simulation study", European Journal of Molecular \& Clinical Medicine, 7, 3943-3947, 2020

[39] Ghosh B, Rani A, Mohamad K, Saad I, "Low leakage current by solution processed ptaa-zno transparent hybrid hetero-junction device", Electronic Materials Letters, 16, 457-465, 2020

[40] Farooq W, Khan A, Khan A, Noman M, "Enhancing the power conversion efficiency of organic solar cells", Optik, 208, 164093, 2020

[41] Kazmi S, Khan A, Khan A, Rauf A, Farooq W, Noman M, Ali H, "Efficient materials for thin-film cdte solar cell based on back surface field and distributed bragg reflector", Applied Physics A, 126, 1-8, 2020

[42] Xiao B, Calado P, MacKenzie R, Kirchartz T, Yan J, Nelson J, "Relationship between fill factor and light intensity in solar cells based on organic disordered semiconductors: the role of tail states", Physical Review Applied, 14, 024034, 2020

[43] Omrani M, Fallah H, Hajimahmoodzadeh M, "High efficiency metallic nanoshells for improving polymer solar cells performance: an opto-electrical study", Solar Energy, 207, 409-418, 2020

[44] Mostoufi N, "Analysis of plasmonic enhanced thin-film solar cells as rooftop photovoltaic systems", 2020

[45] Kornegay K, "Characterizing solar cells", 2020

[46] Ghadimi A, Kiani Sarkaleh A, others, "Investigation of the effect of band offset and mobility of organic/inorganic htm layers on the performance of perovskite solar cells", Journal of Optoelectronical Nanostructures, 5, 65-78, 2020

[47] Farooq W, Khan A, Khan A, Rauf A, Khan S, Ali H, Iqbal J, Khan R, Noman M, "Thin-film tandem organic solar cells with improved efficiency", IEEE Access, 8, 74093-74100, 2020

[48] Farooq W, Musarat M, Alaloul W, "Computational modelling and analysis of fullerene based polymer solar cell", 391-394, 2020

[49] Farooq W, Tu S, Iqbal K, Khan H, Rehman S, Khan A, Rehman O, "An efficient non-toxic and non-corrosive perovskite solar cell", IEEE Access, 8, 210617-210625, 2020

[50] Kabir M, others, "Improving the efficiency of solar photovoltaic power system", 2020

[51] Khan A, Subhan F, Khan A, Khan S, Ahmad M, Rehan M, Noman M, others, "Optimization of efficient monolithic perovskite/silicon tandem solar cell", Optik, 208, 164573, 2020

[52] Anjusree S, Arya K, Das B, "Air-processed active-layer of organic solar cells investigated by conducting afm for precise defect detection", RSC Advances, 10, 24882-24892, 2020

[53] Jin Z, Zhang Z, Xiu J, Song H, Gatti T, He Z, "A critical review on bismuth and antimony halide based perovskites and their derivatives for photovoltaic applications: recent advances and challenges", Journal of Materials Chemistry A, 8, 16166-16188, 2020

[54] Majeed N, Saladina M, Krompiec M, Greedy S, Deibel C, MacKenzie R, "Using deep machine learning to understand the physical performance bottlenecks in novel thin-film solar cells", Advanced Functional Materials, 30, 1907259, 2020

[55] Ahmed M, Ahmed E, Sabri M, Abed W, "The performance of high-efficiency perovskite solar cell (psc) by using capacitance simulator", 1530, 012149, 2020

[56] R{\"o}hr J, MacKenzie R, "Analytical description of mixed ohmic and space-charge-limited conduction in single-carrier devices", Journal of Applied Physics, 128, 165701, 2020

[57] Mia J, "Familiarization with organic photo-voltaic cell and simulation of single layer and multi-layer active cell for improving efficiency and fill factor", 2020

[58] Abudulimu A, Sandoval-Torrientes R, Zimmermann I, Santos J, Nazeeruddin M, Mart{\'\i}n N, "Hole transporting materials for perovskite solar cells and a simple approach for determining the performance limiting factors", Journal of Materials Chemistry A, 8, 1386-1393, 2020

[59] Tinedert I, Saadoune A, Bouchama I, Saeed M, "Numerical modelling and optimization of cds/cdte solar cell with incorporation of cu2o ht-ebl layer", Optical Materials, 106, 109970, 2020

[60] Quandt A, Mokgosi I, Warmbier R, "Simulations of conventional and augmented types of solar cells", 249-276, 2020

[61] Руденко О, "Дослідження плівкових сонячних перетворювачів", 2020

[62] Aftab F, Duran H, Kirchhoff K, Zaheer M, Iqbal B, Saleem M, Arshad S, "A facile synthesis of feco nanoparticles encapsulated in hierarchical n-doped carbon nanotube/nanofiber hybrids for overall water splitting", Welcome to ICONN-2019, 35, 2020

[63] {\'A}lvarez Mac{\'\i}as C, "Crecimiento de nanoalambres de si para implementar en celdas solares de alta eficiencia fotovoltaica", 2020


[64] Sittirak M, Ponrat J, Thubthong K, Kumnorkaew P, Lek-Uthai J, Infahsaeng Y, "The effects of layer thickness and charge mobility on performance of fai: mabr: pbi2: pbbr2 perovskite solar cells: gpvdm simulation approach", 1380, 012146, 2019

[65] Damena K, "Investigation of organic solar cell at different active layer thickness and suns using gpvdm", 2019

[66] Puspita D, "Optimation of layers thickness design of perovskite solar cell (psc) using gpvdm simulation", Computational And Experimental Research In Materials And Renewable Energy, 2, 56-63, 2019

[67] Sinha P, Baghel R, "Effect of series resistance and layer thickness on pce and fill factor in organic solar cell with p3ht: pcbm active layer", 2019

[68] Islam R, Abrar M, Hassan F, Adnan S, "Layer thickness effect on power conversion efficiency of a p 3 ht: pcbm based organicsolar cell", 1-3, 2019

[69] Ahmed S, Shaffer J, Harris J, Pham M, Daniel A, Chowdhury S, Ali A, Banerjee S, "Simulation studies of non-toxic tin-based perovskites: critical insights into solar performance kinetics through comparison with standard lead-based devices", Superlattices and Microstructures, 130, 20-27, 2019

[70] Sen S, Islam M, "Investigation of the effects of charge carrier mobility on the performance of p3ht: pcbm based organic solar cell", Journal for Foundations and Applications of Physics, 6, 118-126, 2019

[71] Yasodharan R, Senthilkumar A, Ajayan J, Mohankumar P, "Effects of layer thickness on power conversion efficiency in perovskite solar cell: a numerical simulation approach", 1132-1135, 2019

[72] CHEE F, DUINONG M, RANI A, CHANG J, ALIAS A, SALLEH S, "Simulation of displacement damage cross section of cuprous oxide/zinc oxide (cu2o/zno) based heterojunction device", Journal of Engineering Science and Technology, 14, 1820-1834, 2019

[73] Ullah M, Khan A, Iqbal J, "Optimization of efficient copper-indium-gallium di-selenide solar cell", 1-6, 2019

[74] Abdulsalam H, Babaji G, "First principle study on lead-free ch3nh3gei3 and ch3nh3gebr3 perovskite solar cell using fhi-aims code", Journal for Foundations and Applications of Physics, 6, 76-88, 2019

[75] Kowsar A, Billah M, Dey S, Debnath S, Yeakin S, Farhad S, "Comparative study on solar cell simulators", 1-6, 2019

[76] Hima A, Lakhdar N, Benhaoua B, Saadoune A, Kemerchou I, Rogti F, "An optimized perovskite solar cell designs for high conversion efficiency", Superlattices and Microstructures, 129, 240-246, 2019

[77] Ahmed S, Harris J, Shaffer J, Devgun M, Chowdhury S, Abdullah A, Banerjee S, "Simulation studies of sn-based perovskites with cu back-contact for non-toxic and non-corrosive devices", Journal of Materials Research, 34, 2789-2795, 2019

[78] Said N, Woon L, "Fill factor and power conversion efficiency simulation of heterojunction organic solar cells (p3ht/pcbm) using zno and pedot: pss as interfacial layer", International Journal of Advanced Research in Technology and Innovation, 1, 64-71, 2019

[79] Ghosh A, Safat S, Islam M, "Stable and efficient perovskite solar cell with metal oxide transport layers", 1-5, 2019

[80] Engmann S, Barito A, Bittle E, Giebink N, Richter L, Gundlach D, "Higher order effects in organic leds with sub-bandgap turn-on", Nature communications, 10, 1-10, 2019

[81] Farooq W, Khan A, Khan M, Iqbal J, "Enhancing the absorption and power conversion efficiency of organic solar cells", International journal of engineering works, 6, 94-97, 2019

[82] Husainat A, Ali W, Cofie P, Attia J, Fuller J, "Simulation and analysis of methylammonium lead iodide (ch3nh3pbi3) perovskite solar cell with au contact using scaps 1d simulator", American Journal of Optics and Photonics, 7, 33, 2019

[83] Hossain M, Zaman A, Mahtab S, Khan M, Alam M, Khan A, Uddin M, "Efficient and stable perovskite solar cell with tio 2 thin insulator layer as electron transport", 54-58, 2019

[84] Heiber M, Wagenpfahl A, Deibel C, "Advances in modeling the physics of disordered organic electronic devices", 309-347, 2019

[85] Vieira J, "Solcelsim--a comsol app for charge transport in a multilayer solar cell", 2019

[86] $\Theta$$\varepsilon$o$\delta$$\acute{\omega}$$\sigma$$\eta$ {, "O$\pi$$\tau$o$\eta$$\lambda$$\varepsilon$$\kappa$$\tau$$\rho$o$\nu$$\iota$$\kappa$$\acute{\eta}$ $\mu$o$\nu$$\tau$$\varepsilon$$\lambda$o$\pi$o$\acute{\iota}$$\eta$$\sigma$$\eta$ o$\rho$$\gamma$$\alpha$$\nu$$\iota$$\kappa$$\acute{\omega}$$\nu$ $\varphi$$\omega$$\tau$o$\beta$o$\lambda$$\tau$$\alpha$$\ddot{\iota}$$\kappa$$\acute{\omega}$$\nu$ $\varepsilon$$\nu$$\iota$$\sigma$$\chi$$\upsilon$$\mu$$\acute{\varepsilon}$$\nu$$\omega$$\nu$ $\mu$$\varepsilon$ $\pi$$\lambda$$\alpha$$\sigma$$\mu$o$\nu$$\iota$$\kappa$$\acute{\alpha}$ $\nu$$\alpha$$\nu$o$\sigma$$\omega$$\mu$$\alpha$$\tau$$\acute{\iota}$$\delta$$\iota$$\alpha$", 2019

[87] Chalabi N, Guen-Bouazza A, "Polymer/fullerene bulk heterojunction solar cells.", Electrotehnica, Electronica, Automatica, 67, 2019

[88] Zdzis{\l}aw Szyma{\'n}ski M, {\L}uszczy{\'n}ska B, "Organic photovoltaics based on solution-processable nanostructured materials: device physics and modeling", Solution-Processable Components for Organic Electronic Devices, 483-536, 2019


[89] Hima A, Khechekhouche A, Kemerchou I, Lakhdar N, Benhaoua B, Rogti F, Telli I, Saadoun A, "Gpvdm simulation of layer thickness effect on power conversion efficiency of ch3nh3pbi3 based planar heterojunction solar cell", International Journal of Energetica, 3, 37-41, 2018

[90] Abdulsalam H, Babaji G, Abba H, "The effect of temperature and active layer thickness on the performance of ch3nh3pbi3 perovskite solar cell: a numerical simulation approach.", Journal for Foundations and Applications of Physics, 5, 141-151, 2018

[91] Erray M, Hanine M, Boufounas E, El Amrani A, "Effects of carriers charge mobility and work function on the performances of p3ht: pcbm based organic photovoltaic solar cell", 1-6, 2018

[92] Hanane M, Hadjila M, "Simulation d’une cellule solaire photovolta{\"\i}que organique {\`a} r{\'e}seau interp{\'e}n{\'e}tr{\'e} avec le logiciel gpvdm", 2018

[93] Erray M, Hanine M, Boufounas E, El Amrani A, "Combined effects of carriers charge mobility and electrodes work function on the performances of polymer/fullerene p3ht: pcbm based organic photovoltaic solar cell", The European physical journal applied physics, 82, 30201, 2018

[94] Singh N, Rastogi N, "Simulation of organic solar cell at different charge mobility and different series resistances", IFTM-Research Journal of Science, 1, 2018

[95] Rani A, Mohamad K, Ghosh B, Saad I, Ibrahim P, Alias A, Abd Rahman A, "Electrical simulation of different photoactive layer thickness on organic heterojunction solar cell", 2018

[96] Erwin W, MacKenzie R, Bardhan R, "Understanding the limits of plasmonic enhancement in organic photovoltaics", The Journal of Physical Chemistry C, 122, 7859-7866, 2018

[97] Kumari K, Chakrabarti T, Jana A, Bhattachartjee D, Gupta B, Sarkar S, "Comparative study on perovskite solar cells based on titanium, nickel and cadmium doped bifeo3 active material", Optical Materials, 84, 681-688, 2018

[98] Singh A, Mehta D, Baldua P, "Flexible electronics-organic light emitting diodes (oled)", 2018

[99] Tam H, Liu F, Djuri{\v{s}}i{\'c} A, "Recombination effects in perovskite solar cells", 67-68, 2018

[100] Kumar A, Thakur A, "Role of contact work function, back surface field, and conduction band offset in cu2znsns4 solar cell", Japanese Journal of Applied Physics, 57, 08RC05, 2018

[101] Kumar A, Thakur A, "Role of contact work function, back surface field and conduction band offset in czts solar cell", arXiv preprint arXiv:1807.02751, 2018

[102] Hela{\'c} V, {\v{S}}ami{\'c} H, Hanjali{\'c} S, Nikoli{\'c} B, "Influence of organic materials on solar cells efficiency", 1-5, 2018

[103] M{\"a}ckel H, MacKenzie R, "Determination of charge-carrier mobility in disordered thin-film solar cells as a function of current density", Physical Review Applied, 9, 034020, 2018

[104] Quandt A, Aslan T, Mokgosi I, Warmbier R, Ferrari M, Righini G, "About the implementation of frequency conversion processes in solar cell device simulations", Micromachines, 9, 435, 2018

[105] Verma L, Sharma V, Kumar M, "New delay-based fast retransmission policy for cmt-sctp", Int. J. Intell. Syst. Appl, 10, 2018

[106] Heiber M, Wagenpfahl A, Deibel C, "* center for hierarchical materials design (chimad), northwestern university, evanston, il, united states,† institut fur physik, technische universitat chemnitz, chemnitz, germany", Handbook of Organic Materials for Electronic and Photonic Devices, 309, 2018


[107] Rastogi N, Singh N, Saxena S, "Analysis of organic photovoltaic device at different series resistances", vol, 5, 83-87, 2017

[108] Singh N, Chaudhary A, Saxena S, Saxena M, Rastogi N, "Electrical simulation of organic solar cell at different charge carrier mobility", IOSR J. Appl. Phys, 9, 01-04, 2017

[109] Singh J, "Theoretical study of organic light emitting devices", 2017

[110] Patel N, "Theoretical study of the organic light emitting devices", 2017

[111] Pala J, Mordiya M, Virpariya D, Dangodara A, Gandha P, Savaliya C, Joseph J, Shiyani T, Dhruv D, Markna J, "Analysis and design optimization of organic dye sensitized solar cell based on simulation", 1837, 030004, 2017

[112] Quandt A, Warmbier R, Mokgosi I, Aslan T, "Solar cell device simulations", 1-5, 2017

[113] Erwin W, "Shape controlled plasmonic nanostructures for light harvesting applications", 2017

[114] MacKenzie R, "Organic semiconductors", 191-218, 2017

[115] Space U, "Roderick ci mackenzie", Handbook of Optoelectronic Device Modeling and Simulation: Fundamentals, Materials, Nanostructures, LEDs, and Amplifiers, Vol. 1, 191, 2017


[116] Sahdane T, Laghrabli A, Bougharraf H, Benallal R, Azize B, Kabouchi B, "Theoretical study of optical and electrical properties of organic photovoltaic cell pedot: pss/p3ht: pcbm", no, 1, 283-286, 2016

[117] Atik {, Farsakoglu O, Watsuji N, Yilmaz S, "Determination of electrical and optical design parameters of high-efficiency oled", IJARCCE., 5, 949-953, 2016

[118] Azzouzi M, "A study of the degradation of organic solar cells", 2016

[119] Sharaf S, van der Meulen G, Agunlejika E, Azzopardi B, "Structures in gas--liquid churn flow in a large diameter vertical pipe", International Journal of Multiphase Flow, 78, 88-103, 2016

Unknown year

[120] VOLUMOSO P, RA{\c{C}}{\~O}ES C, "Desempenho de novilhos superprecoces variando a", ALECSSANDRO REGAL DUTRA, 71, 2000

[121] Jahangir K, Nowsherwan G, Hussain S, Riaz S, Naseem S, "Electrical simulation and optimization of ptb7: pc70bm based organic solar cell using gpvdm simulation software"

[122] Chakraborty K, Malakar S, Mandal D, Mondal R, Maiti A, "Experimental prediction of effect of thickness of active layer of photovoltaic device on a series of electrical parameters using gpvdm software"

[123] Yusop N, Pien C, Alias A, Abd Rahman A, Ismail A, Rani A, "Electrical simulation for different thickness ratio of pcbm and ptaa in bilayer organic solar cells"

[124] Sahdane T, Laghrabli A, Benallal R, Bougharraf H, Azize B, Kabouchi B, "Research journal of pharmaceutical, biological and chemical sciences"

[125] Said N, Suboh A, "Simulation of fill factor and power conversion efficiency on heterojunction organic solar cells (p3ht: pcbm) using zno as buffer layer"

[126] Sahdane T, Azize B, Laghrabli A, Benallal R, Bougharraf H, Kabouchi B, "High fill factor and conversion efficiency in organic photovoltaic cells with pedot: pss/c60"

[127] R{\"o}hr J, "Analytical description of mixed ohmic and space-charge-limited conduction"

[128] KEMERCHOU I, ROGTI F, BENHAOUA B, HIMA A, KHECHEKHOUCHE A, "Characterization of organic/inorganic perovskite material ch3nh3pbi3 prepared by spray pyrolysis with moving nozzle method"

[129] VALENZUELA I, MAY D, SANTILL{\'A}N D, "Dise{\~n}o de generadores h{\'i}bridos basados en energ{\'i}a solar y agua de lluvia para edificios inteligentes"

[130] Hima A, Le Khouimes A, Rezzoug A, Yahkem M, Khechekhouche A, Kemerchou I, "Simulation and optimization of ch3nh3pbi3 based inverted planar heterojunction solar cell using scaps software", International journal of energetica, 4, 56-59

[131] Hima A, Khechekhouche A, Kemerchou I, "Enhancing of ch3nh3sni3 based solar cell efficiency by etl engineering."

[132] Rani A, Mohamad K, Ibrahim P, Saad I, Kumar G, Pien C, Alias A, "A hybrid inorganic-organic heterojunction device: structural morphology and electrical", Current Advances in Microdevices and Nanotechnology Series, 1

[133] Solak S, Shishegaran S, H{\"u}bler A, MacKenzie R, "Understanding printed hexagonal contacts for large area solar cells through simulation and experiment", Solar RRL

[134] Rodr{\i}guez-Mart{\i}nez X, Pascual-San-Jos{\'e} E, Campoy-Quiles M, "Accelerating organic solar cell material’s discovery: high-throughput screening and big data1"

[135] MORENO TORRES G, "Departamento de el{\'e}ctrica, electr{\'o}nica y telecomunicaciones"

Key publications that describe the development of the model

Accuracy fo the list

This list was generated using google scholar, then the list was pruned to remove papers which only cite OghmaNano rather than using it. There well may be papers which have been missed or papers which should not be here. If you spot a missing paper or a paper too many let me know.