The primary objective of this research is to evaluate the feasibility and potential benefits of integrating solar Photovoltaic (PV) systems in educational institutions within the new capital. The Hybrid Optimization of Multiple Energy Resources (HOMER) energy modeling software was utilized to achieve this, enabling a detailed analysis of the project's viability for investment over a specified timeframe. Key metrics such as Net Present Cost (NPC), Cost of Energy (COE), and Break-Even Point (BEP) were emphasized to assess the economic implications of the project. The findings of the research reveal that the rooftop solar PV system for schools in Ibu Kota Nusantara (IKN) has NPC of IDR 15,865,110,000.00, COE of IDR 1,174.26 per kWh, and a BEP occurring in the sixteenth year, as indicated by the simulation results. These outcomes suggest that the rooftop solar PV project is not only a viable solution but also holds significant potential for development. Furthermore, it supports the overarching goals of the capital relocation program while promoting the adoption of renewable energy sources in Indonesia, thereby contributing to a more sustainable future for the nation.

1 E. P. Laksana, Y. Prabowo, Sujono, R. Sirait, N. Fath, A. Priyadi, and M. H. Purnomo, "Potential Usage of Solar Energy as a Renewable Energy Source in Petukangan Utara, South Jakarta," Jurnal Rekayasa Elektrika, vol. 17, no. 4, pp. 212-216, 2021.

2 H. A. J. Sihite and Y. G. Sucahyo, "Recommendation for Smart Building Systems Designs for Residence in Capital City of the Archipelago (IKN)," in the 10th International Conference on ICT for Smart Society, Bandung, Indonesia, 2023.

3 M. Rino, "Scenario Planning for Renewable Energy Development towards Net Zero Emission in Indonesia's New Capital City Nusantara,"Euro. J. Bus. Manag. Res., vol. 8, no. 6, pp. 77-86, 2023.

4 N. Heryana, H. R. Iskandar, and J. Furqani, "Utilization of Renewable Energy for Charging Station in Indonesia New Appointed Capital City, Nusantara," in the 4th International Conference on High Voltage Engineering and Power Systems, Denpasar, Indonesia, 2023.

5 G. B. A Kumar and Shivashankar, “Optimal power point tracking of solar and wind energy in a hybrid wind solar energy system,”Int. J. Energy Environ. Eng., vol. 13, no. 1, pp. 77-103, 2022.

6 Z. Arifin, S. D. Prasetyo, D. D. D. P. Tjahjana, R. A. Rachmanto, A. R. Prabowo, and N. F. Alfaiz, "The application of TiO2 nanofluids in photovoltaic thermal collector systems," Energy Reports, vol. 8, pp. 1371-1380, 2022.

7 S. K. Gupta and S. Pradhan, "A review of recent advances and the role of nanofluid in solar photovoltaic thermal (PV/T) systems,"Mater. Today Proc., vol. 44, pp. 782-791, 2021.

8 M. A. Muliawan, B. Winardi, and B. Setiyono, "Analysis Of Solar Power Plant Design At Sma Negeri 4 Semarang Using the HOMER Application,"Transient Sci. J. Electric. Eng., vol. 9, no. 4, pp. 497-502, 2020.

9 S. Baqaruzi, K. Kananda, and A. Muhtar, "Perbandingan Penempatan Panel Fotovoltaik Di Atas Tanah (Ground Mounting Pv) Atau Di Atas Atap (Rooftop Pv) Sebagai Implementasi Pemanfaatan Plts Yang Efisien Di Itera," Jurnal Elektro, vol. 13, no. 1 pp. 31-38, 2020. (in Indonesia).

10 A. Trivaldo and R. Gianto, "Planning Study of On-Grid Based Solar Power Plant at Senior High School of Negeri 1 Meliau,"J. Electric. Eng. Energy Inf. Tech., vol. 12, no. 1, 2024.

11 Z. Arifin, Suyitno, D. D. D. P. Tjahjana, M. Muqoffa, S. D. Prasetyo, N. F. Alfaiz, and A. Sanusi, “Grid-Connected Hybrid PV-Wind System Simulation in Urban Java,” J. Europ. des Systemes Automatises, vol. 55, no. 4, pp. 477-483, 2022.

12 A. Mahesh and K. S. Sandhu, “Hybrid wind/photovoltaic energy system developments: Critical review and findings,”Renew. Sustain. Energy Rev., vol. 52, pp. 1135-1147, 2015.

13 N. E. Benti, Y. S. Mekonnen, A. A. Asfaw, M. D. Lerra, T. A. Woldegiyorgis, C. A. Gaffe, and A. B. Aneseyee, “Techno-economic analysis of solar energy system for electrification of rural schools in Southern Ethiopia,” Cogent Eng., vol. 9, no. 1, article no. 2021838, 2022.

14 R. A. Rachmanto, F. J. Regannanta, Ubaidillah, Z. Arifin, D. Widhiyanuriyawan, E. Yohana, and S. D. Prasetyo, "Analysis of Development of Public Electric Vehicle Charging Stations Using On-Grid Solar Power Plants in Indonesia," Int. J. Transp. Dev. Integr., vol. 7, no. 3, pp. 215-222, 2023.

15 L. Khalil, K. L. Bhatti, M. A. I. Awan, M. Riaz, K. Khalil, and N. Alwaz, “Optimization and designing of hybrid power system using HOMER pro,” Mater. Today Proc., vol. 47, pp. S110-S115, 2020.

16 H. Alsamamra and J. Shoqeir, "Solar Photovoltaic Systems on Public Schools Buildings: A Case Study in Palestine," Am. J. Electric. Power Energy Sys., vol. 10, no. 1, pp. 1-5, 2021.

17 S. Çiftçi, M. Solak, and M. Kuncan, "Powered by the sun: designing and analyzing technical and economic aspects of a school sustained by photovoltaics." J. Mech. Artif. Intel. Eng., vol. 1, no. 1, pp 21-32, 2020.

18 S. D. Yoon, S. Vuthy, and H. S. Choi. "Design of Solar Modules for Building Façades at Educational Facilities in Korea," Energy., vol. 14, article no. 2441, 2021.

19 L. Bilir and N. Yildirim,"Photovoltaic system assessment for a school building." Int. J. Hydrogen Energy, vol. 42, pp. 17856-17868, 2017.

20 A. Oscar, D. Nyqvist, and S. Robertsson. "Solar energy production at Heby Skola: A pilot study of a photovoltaic installation in Sweden." Uppsala: Uppsala Universitet, 2013.

21 D. W. F. S. N. Giyatno, L. Subekti, A. B. Pradana, I. Nurmawati, and I. Wibowo, "Optimizing Wind and Solar Energy Capacity with Microgrid Configuration Based on Load Characteristics," Technoscience J., vol. 10, no. 2, pp. 170-178, 2021.

22 E. Widianto, D. B. Santoso, K. Kardiman, and N. Fauji, "Analysis of the Potential for Photovoltaic-Wind Turbines Power Plants at Sedari Beach, Karawang," J. Sci. Tech. Res., vol. 3, no. 1, pp. 41-47, 2019. (in Indonesia).

23 S. A. Prahastono, A. A. Setiawan, and W. Wilopo, "The Design Of Hybrid Renewable Energies Utilization To Increase Electrification Ratio (Case Study: Tulakan, Pacitan Regency)," J. Electronics Sci. Energy Sys., vol. 02, no. 02, pp. 18-29, 2023. (in Indonesia).

24 D. N. Akbar, B. S. Gumilang, and A. Zuroida, "Study of Potential Development of PV-Genset Hybrid Power Plants in the Coastal Area of Malang Regency,"J. Electric. Sys., vol. 10, no. 1, pp. 94-98, 2023. (in Indonesia).

25 L. Sinaga, Hermawan, and A. Nugroho, "Optimasi Sistem Pembangkit Listrik Hibrida Tenaga Surya, Angin, Biomassa, Dan Diesel Di Pulau Nyamuk Karimunjawa Jawa Tengah Dengan Menggunakan Perangkat Lunak Homer," Transient, vol. 4, no. 4, pp. 1029-1037, 2015. (in Indonesia).

26 R. Asri and K. Canada, "Design and Feasibility Analysis of Hybrid PV-Diesel-Grid Systems at the Sumatra Institute of Technology (ITERA)," JE-Unisla, vol. 3, no. 2, pp. 30-36, 2018. (in Indonesia).

27 L. M. Hayusman and N. Saputera, "Studi Perencanaan Panel Kendali Plts-Pln Berdasarkan Kapasitas Baterai Untuk Plts Off-Grids," Jurnal Sains Terapan, vol. 8, no. 1, pp. 35-44, 2022. (in Indonesia).

28 M. Zulni and S. Bandri, "Planning on Solar Power Plant 900 Va Power Grid Using Micropower Homer Household Application Planning on Solar Power Plant Ongrid Power 900 Va Using Micropower Homer Household Application," Indonesian J. Electric. Eng. Renew. Energi, vol. 3, pp. 29-35, 2023. (in Indonesia).

29 Dyah Ayu Kartika Sari, Fransisco Danang Wijaya, and Husni Rois Ali, "Optimization of Hybrid Power Generation Systems on Enggano Island," National J. Electric. Eng. Inf. Tech., vol. 11, no. 2, pp. 154-160, 2022.

30 M. N. Huda and I. H. Kurniawan, "Design of a Hybrid Power Generation System (Wind Power and Solar Power) in the Widuri Area, Pemalang Regency Using Homer Software," J. Electric. Eng. Res., vol. 5, no. 1, pp. 33-46, 2023. (in Indonesia).