Emerging Energy Research Driving Sustainable Development Goals in Developing Countries with an Indonesian Perspective

Filda Citra Yusgiantoro; Purnomo Yusgiantoro; Muhammad Indra Al Irsyad; Bono Pranoto; Joni Jupesta

doi:10.5109/7420064

ISSN:2189-0420 (Print until Mar 2020)
ISSN:2432-5953 (Online)

4.1

2025CiteScore

64th percentile

SNIP: 1.192

		4.3 2024CiteScore 69th percentile Powered by
Metrics by SCOPUS 2024 CiteScore 4.3 SJR 0.391 SNIP 1.192

Emerging Energy Research Driving Sustainable Development Goals in Developing Countries with an Indonesian Perspective

Filda Citra Yusgiantoro1, Purnomo Yusgiantoro2, Muhammad Indra Al Irsyad3, Bono Pranoto4,*, Joni Jupesta5

1Faculty of Economic and Business, Atma Jaya Catholic University of Indonesia, Indonesia

2Bandung Institute of Technology, Indonesia

3Research Centre of Behaviour and Circular Economy, National Research and Innovation Agency, Indonesia

4Research Center for Limnology and Water Resources, National Research and Innovation Agency, Indonesia

5Center for Transdisciplinary and Sustainability Sciences (CTSS), IPB University, Indonesia

*Author to whom correspondence should be addressed:
E-mail: bono001@brin.go.id (BP)

Evergreen, Vol. 13, Iss. 02, pp. 466–498, 2026
DOI: 10.5109/7420064

Creative Commons Attribution 4.0 International

Received: July 04, 2025 | Revised: November 05, 2025 | Accepted: March 10, 2026 | Published: June 2026

Abstract

This study analyzes Indonesia's energy research landscape via bibliometric analysis of 19,588 Scopus publications. Findings reveal a dominant shift towards renewables (72.2% of publications), led by bioenergy, and high institutional specialization. Thematic mapping identifies robust themes like biomass but underexplored areas such as ocean energy. The study underscores the need for strategic collaborations and policy support to bridge research gaps, foster innovation, and guide Indonesia toward energy self-sufficiency, providing a data-driven foundation for future research and policy development.

Keywords

bibliometric analysis; energy studies; fossil fuels; renewable energy; research collaboration; thematic research map

Available Repositories

Journal DOI Zenodo Archive

Article Metrics

Views

Downloads

Citations

Export Citation

BibTeX RIS Semantic Scholar CrossRef Mendeley Google Scholar

Full Text

References

1) U.K. Pata, S. Karlilar, and M.T. Kartal, "On the road to sustainable development: the role of ICT and R&D investments in renewable and nuclear energy on energy transition in Germany," Clean Technol. Environ. Policy, 26 (7) 2323-2335 (2024) doi:10.1007/s10098-023-02677-y
2) F.F. Liza, F. Ahmad, L. Wei, K. Ahmed, and A. Rauf, "Environmental technology development and renewable energy transition role toward carbon-neutrality goals in G20 countries," Clean Technol. Environ. Policy, 26 (10) 3369-3390 (2024) doi:10.1007/s10098-024-02804-3
3) J. Li, Z. Liu, X. Li, and N. Guo, "Research on the low-carbon effect of technological innovation," Clean Technol. Environ. Policy, 26 (9) 3127-3149 (2024) doi:10.1007/s10098-024-02787-1
4) A. Swain, C. Bruch, T. Ide, P. Lujala, R.A. Matthew, E. Weinthal, and T. Deligiannis, "The US withdrawal from the Paris agreement—implications for global climate governance and security," Environ. Secur., 3 (1) 3-7 (2025) doi:10.1177/27538796251322680
5) F. Groba, and J. Cao, "Chinese renewable energy technology exports: the role of policy, innovation and markets," Environ. Resour. Econ., 60 (2) 243-283 (2015) doi:10.1007/s10640-014-9766-z
6) T.N. Do, P.J. Burke, H.N. Nguyen, I. Overland, B. Suryadi, A. Swandaru, and Z. Yurnaidi, "Vietnam’s solar and wind power success: policy implications for the other asean countries," Energy Sustain. Dev., 65 1-11 (2021) doi:10.1016/j.esd.2021.09.002
7) MEMR, "Handbook of energy & economic statistics of indonesia 2023," (2024). https://www.esdm.go.id/en/publication/handbook-of-energy-economic-statistics-of-indonesia-heesi
8) A.P. Muyasyaroh, "Rethinking energy security in indonesia from a net zero perspective," Indones. J. Energy, 7 (1) 16-26 (2024) doi:10.33116/ije.v7i1.197
9) A. Soemanto, and R.H.T. Koestoer, "Scenario insight of energy transition," Indones. J. Energy, 6 (1) 48-59-48-59 (2023). doi:https://orcid.org/0000-0003-1701-0419
10) T.W.S. Panjaitan, A.H. Pandyaswargo, T.D. Atmaja, F.A. Firman, and M.I. Al Irsyad, "Drawing insights from Japan’s energy efficiency policies for Indonesia’s progress," Indones. J. Energy, 7 (2) 107-123 (2024) doi:10.33116/ije.v7i2.212
11) M.I. Al Irsyad, A. Halog, R. Nepal, and D.P. Koesrindartoto, "The impacts of emission reduction targets in Indonesia electricity systems," Indones. J. Energy, 2 (2) 118-130 (2019) doi:10.33116/ije.v2i2.42
12) L. Li, "Reskilling and upskilling the future-ready workforce for industry 4.0 and beyond," Inf. Syst. Front., 26 (5) 1697-1712 (2024) doi:10.1007/s10796-022-10308-y
13) X. Lyu, T. Ruan, W. Wang, and X. Cai, "A bibliometric evaluation and visualization of global solar power generation research: productivity, contributors and hot topics," Environ. Sci. Pollut. Res., 31 (5) 8274-8290 (2024) doi:10.1007/s11356-023-31715-x
14) M.H. Abdul Jabar, R. Srivastava, N. Abdul Manaf, S. Thangalazhy-Gopakumar, F.E. Ab Latif, M.T. Luu, and A. Abbas, "The solar end game: bibliometric analysis, research and development evolution, and patent activity of hybrid photovoltaic/thermal—phase change material," Environ. Sci. Pollut. Res., 30 (55) 116934-116951 (2023) doi:10.1007/s11356-023-27641-7
15) S. Afrane, J.D. Ampah, and E.A. Mensah, "Visualization and analysis of mapping knowledge domains for the global transition towards clean cooking: a bibliometric review of research output from 1990 to 2020," Environ. Sci. Pollut. Res., 1-28 (2022) doi:10.1007/s11356-021-17340-6
16) Y. Yu, K. Chen, J. Liao, and W. Zhu, "Detecting the research trends and evolution of energy resilience: a bibliometric analysis," Environ. Sci. Pollut. Res., 30 (8) 21797-21814 (2023) doi:10.1007/s11356-022-23768-1
17) K. Liang, W. Li, J. Wen, W. Ai, and J. Wang, "Research characteristics and trends of power sector carbon emissions: a bibliometric analysis from various perspectives," Environ. Sci. Pollut. Res., 30 (2) 4485-4501 (2023) doi:10.1007/s11356-022-22504-z
18) S. Afrane, J.D. Ampah, and E.M. Aboagye, "Investigating evolutionary trends and characteristics of renewable energy research in Africa: a bibliometric analysis from 1999 to 2021," Environ. Sci. Pollut. Res., 29 (39) 59328-59362 (2022) doi:10.1007/s11356-022-20125-0
19) Y. Zhang, Q. Yu, and J. Li, "Bioenergy research under climate change: a bibliometric analysis from a country perspective," Environ. Sci. Pollut. Res., 28 26427-26440 (2021) doi:10.1007/s11356-021-12448-1
20) Z. Wang, Y. Wang, S. Peng, B. Niu, C. Cui, and J. Wu, "Mapping the research of energy subsidies: a bibliometric analysis," Environ. Sci. Pollut. Res., 26 28817-28828 (2019) doi:10.1007/s11356-019-06025-w
21) R. Rachmad, M.I. Irawan, and S. Hanoum, "Renewable energy and carbon trading: A bibliometric analysis," in: AIP Conf. Proc., AIP Publishing, 2024 doi:10.1063/5.0235602
22) R. Suciati, S. Hidayati, and A.A.S. Mashuri, "Green finance’s impact on renewable energy: a comprehensive review and bibliometric analysis," Int. J. Green Econ., 18 (4) 390-409 (2024) doi:10.1504/IJGE.2024.142401
23) B.K. Ngetich, N. Nuryakin, and I.N. Qamari, "How research in sustainable energy supply chain distribution is evolving: bibliometric review," J. Distrib. Sci., 20 (7) 47-56 (2022) doi:10.15722/jds.20.07.202207.47
24) K. Kristia, and M.F. Rabbi, "Exploring the synergy of renewable energy in the circular economy framework: a bibliometric study," Sustainability, 15 (17) 13165 (2023) doi:10.3390/su151713165
25) F.I. Maulana, P.D.P. Adi, N.H. Hari, M. Hamim, and D. Lestari, "Applications of artificial intelligence in renewable energy: a bibliometric analysis of the scientific production indexed in Scopus," in: E3S Web Conf., EDP Sciences, 2024: p. 1016 doi:10.1051/e3sconf/202450101016
26) D. Nasrudin, A. Setiawan, D. Rusdiana, and Liliasari, "Systems thinking on renewable energy: A bibliometric analysis," in: AIP Conf. Proc., AIP Publishing LLC, 2023: p. 120004 doi:10.1063/5.0156393
27) F. Kuok, S. Sdok, S. Ho, and I.A. Muhamad, "Barriers to ASEAN renewable energy: a systematic review and bibliometric analysis," CET Journal-Chemical Eng. Trans., 113 (2024) doi:10.3303/CET24113086
28) I. Hamidah, R.E. Pawinanto, B. Mulyanti, and J. Yunas, "A bibliometric analysis of micro electro mechanical system energy harvester research," Heliyon, 7 (3) (2021) doi:10.1016/j.heliyon.2021.e06406
29) T. Widianti, and H. Firdaus, "A decade of organic rankine cycle research trends and evolution: a bibliometric analysis," Evergreen, 11 (3) 2479-2503 (2024) doi:10.5109/7236890
30) A. Saxena, J. Mahajan, V. Bhagat, M. V Subha, B.P. Paul, and V. Jain, "The intellectual structure of application of artificial intelligence in forecasting methods: a literature review using bibliometric thematic analysis," Artif. Intell. Forecast., 283-303 (2024) doi:10.1201/9781003399292-18
31) G. Verasoundarapandian, C.-Y. Wong, N.A. Shaharuddin, C. Gomez-Fuentes, A. Zulkharnain, and S.A. Ahmad, "A review and bibliometric analysis on applications of microbial degradation of hydrocarbon contaminants in arctic marine environment at metagenomic and enzymatic levels," Int. J. Environ. Res. Public Health, 18 (4) 1671 (2021) doi:10.3390/ijerph18041671
32) J.K. Tamala, E.I. Maramag, K.A. Simeon, and J.J. Ignacio, "A bibliometric analysis of sustainable oil and gas production research using Vosviewer," Clean. Eng. Technol., 7 100437 (2022) doi:10.1016/j.clet.2022.100437
33) T.A. Mim, C. Kathiravan, and B. Maniam, "The 50-year-old oil crisis and its impact on the global economy: a bibliometric analysis," Int. J. Energy Econ. Policy, 14 (4) 81-91 (2024) doi:10.32479/ijeep.16028
34) O. Omoregbe, and A. Hart, "Global trends in heavy oil and bitumen recovery and in-situ upgrading: a bibliometric analysis during 1900-2020 and future outlook," J. Energy Resour. Technol., 144 (12) 123007 (2022) doi:10.1115/1.4054535
35) L. Tan, F. Liu, S. Dai, and J. Yao, "A bibliometric analysis of two-decade research efforts in turning natural gas hydrates into energy," Energy, 299 131440 (2024) doi:10.1016/j.energy.2024.131440
36) M. Malekli, A. Aslani, Z. Zolfaghari, R. Zahedi, and A. Moshari, "Advanced bibliometric analysis on the development of natural gas combined cycle power plant with CO2 capture and storage technology," Sustain. Energy Technol. Assessments, 52 102339 (2022) doi:10.1016/j.seta.2022.102339
37) R. Zahedi, A. Aslani, M.A.N. Seraji, and Z. Zolfaghari, "Advanced bibliometric analysis on the coupling of energetic dark greenhouse with natural gas combined cycle power plant for co2 capture," Korean J. Chem. Eng., 39 (11) 3021-3031 (2022) doi:10.1007/s11814-022-1233-x
38) T.L. Baiyegunhi, C. Baiyegunhi, and B.K. Pharoe, "Global research trends on shale gas from 2010-2020 using a bibliometric approach," Sustainability, 14 (6) 3461 (2022) doi:10.3390/su14063461
39) P. Zhang, Y. Du, S. Han, and Q. Qiu, "Global progress in oil and gas well research using bibliometric analysis based on Vosviewer and citespace," Energies, 15 (15) 5447 (2022) doi:10.3390/en15155447
40) M. Mehrpooya, C.-M. Chang, S.A. Mousavi, M.R. Ganjali, and Y.-S. Ho, "Research trends and performance evaluation of natural gas in the web of science category of energy and fuels: a bibliometric study," J. Therm. Anal. Calorim., 148 (17) 8747-8763 (2023) doi:10.1007/s10973-023-12287-x
41) L. Yang, Q. Wang, X. Bai, J. Deng, and Y. Hu, "Mapping of trace elements in coal and ash research based on a bibliometric analysis method spanning 1971-2017," Minerals, 8 (3) 89 (2018) doi:10.3390/min8030089
42) F. Yang, and D. Qiu, "Exploring coal spontaneous combustion by bibliometric analysis," Process Saf. Environ. Prot., 132 1-10 (2019) doi:10.1016/j.psep.2019.09.017
43) Q. Zhang, B. Wu, J. Wu, Y. Qi, W. Chu, L. Qiao, B. Zhang, P. Shen, and T. Tang, "Study on arsenic, selenium, and lead produced in coal combustion: bibliometric method," Environ. Sci. Pollut. Res., 28 (25) 32190-32199 (2021) doi:10.1007/s11356-021-14197-7
44) C. Xu, T. Yang, K. Wang, S. Ma, M. Su, and A. Zhou, "Research on the evolution law of hot spots in the field of coal seam hydraulic fracturing based on bibliometric analysis: review from a new scientific perspective," Environ. Sci. Pollut. Res., 30 (37) 86618-86631 (2023) doi:10.1007/s11356-023-28589-4
45) S.S. Seyıtoglu, and A. Kılıçarslan, "The related study tendencies in the field of gasification: a bibliometric approach," Gazi Univ. J. Sci., 35 (3) 980-995 (2022) doi:10.35378/gujs.874093
46) Q. Chen, Y. Gou, T. Wang, P. Liu, and J. Zhu, "The evolutionary path and emerging trends of circulating fluidized bed technology: an integrated analysis through bibliometric assessment and data visualization," Energies, 17 (14) 3514 (2024) doi:10.3390/en17143514
47) A. Saramak, and D. Saramak, "Coal modeling investigations in international collaboration in the light of bibliometric analysis of the problem," Energies, 15 (16) 6040 (2022) doi:10.3390/en15166040
48) H. Wang, Z. Fu, W. Lu, Y. Zhao, and R. Hao, "Research on sulfur oxides and nitric oxides released from coal-fired flue gas and vehicle exhaust: a bibliometric analysis," Environ. Sci. Pollut. Res., 26 17821-17833 (2019) doi:10.1007/s11356-019-05066-5
49) J. Misiak, and B. Uliasz-Misiak, "Coal research trends-a bibliometric approach," Gospod. Surowcami Miner., 40 (2024) doi:10.24425/gsm.2024.152715
50) B. Peng, D. Guo, H. Qiao, Q. Yang, B. Zhang, T. Hayat, A. Alsaedi, and B. Ahmad, "Bibliometric and visualized analysis of China’s coal research 2000-2015," J. Clean. Prod., 197 1177-1189 (2018) doi:10.1016/j.jclepro.2018.06.283
51) M. Batur, and R.M. Alkan, "Bibliometric analysis of the greatest nuclear disasters: what is known so far and what are the prospects?," Int. Arch. Photogramm. Remote Sens. Spat. Inf. Sci., 48 61-68 (2024) doi:10.5194/isprs-archives-XLVIII-4-W9-2024-61-2024
52) N. Apriandi, K. Rozi, M.H. Kusuma, B.F.T. Kiono, R. Raharjanti, Y.D.S. Pambudi, M. Yunus, S.L. Butarbutar, S. Hatmoko, and A. Pramesywari, "A pager framework-enhanced bibliometric analysis of global nuclear desalination research trends (2005-2024)," Desalination, 118564 (2025) doi:10.1016/j.desal.2025.118564
53) P. Fernández-Arias, D. Vergara, and Á. Antón-Sancho, "Bibliometric review and technical summary of pwr small modular reactors," Energies, 16 (13) 5168 (2023) doi:10.3390/en16135168
54) A.K. Khakimova, O. V Zolotarev, and M.A. Berberova, "Visualization of bibliometric networks of scientific publications on the study of the human factor in the operation of nuclear power plants based on the bibliographic database dimensions," Sci. Vis., 12 (2) (2020) doi:10.26583/SV.12.2.10
55) E. Adar, "The state of the art of nuclear energy and its bibliometric analysis," Environ. Res. Technol., 4 (2) 102-107 (2021) doi:10.35208/ert.840369
56) I. Dutt, A. Kumar, and N. Singh, "Published research documents of India in nuclear and high energy physics: A bibliometric analysis," in: AIP Conf. Proc., AIP Publishing, 2022 doi:10.1063/5.0086113
57) L. Obregon, C. Orozco, J. Camargo, J. Duarte, and G. Valencia, "Research trend on nuclear energy from 2008 to 2018: a bibliometric analysis," Int. J. Energy Econ. Policy, 9 (6) 542-551 (2019) doi:10.32479/ijeep.8515
58) T.N. Van Leeuwen, and R.J.W. Tijssen, "Assessing multidisciplinary areas of science and technology: a synthetic bibliometric study of Dutch nuclear energy research," Scientometrics, 26 115-133 (1993) doi:10.1007/BF02016796
59) S. Harichandan, S.K. Kar, R. Bansal, S.K. Mishra, M.S. Balathanigaimani, and M. Dash, "Energy transition research: a bibliometric mapping of current findings and direction for future research," Clean. Prod. Lett., 3 100026 (2022) doi:10.1016/j.clpl.2022.100026
60) C.-R. Chen, M.-C. Chen, C.-J. Chou, C.-Y. Lee, and C.-C. Chen, "Promoting the surge immunity techniques of an uninterruptible hydro plant power system under the surge environment of high exposure," 82 274-280 (2016) doi:10.1016/j.ijepes.2016.03.029
61) A.F. Madsuha, E.A. Setiawan, N. Wibowo, M. Habiburrahman, R. Nurcahyo, and S. Sumaedi, "Mapping 30 years of sustainability of solar energy research in developing countries: Indonesia case," Sustainability, 13 (20) 11415 (2021) doi:10.3390/su132011415
62) S. Damayanti, and A. Dinaseviani, "Mapping of Household Photovoltaic Research in Indonesia: A literature review using bibliometric analysis," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2024: p. 12014 doi:10.1088/1755-1315/1344/1/012014
63) D.I. Setyanansyach, M. Setiyo, and T. Raja, "Review and bibliometric analysis of biogas power plants in Indonesia," Adv. Sustain. Sci. Eng. Technol., 5 (3) 2303015 (2023) doi:10.26877/asset.v5i3.16806
64) M.A. Shafii, A.G. Abdullah, S. Pramudtya, T. Setiadipura, and K. Anzhar, "Two decades of nuclear energy policy and its impact on Indonesia: a bibliometric review," 2024, (2024) doi:10.24294/jipd.v8i7.4449
65) I. Akbar, D. Arisaktiwardhana, and P. Naomi, "How does Indonesian scientific production on renewable energy successfully support the policy design? a journey towards sustainable energy transition," Probl. Ekorozwoju, 15 (2) 41-52 (2020) doi:10.35784/pe.2020.2.05
66) I. Fitriana, N. Niode, A. Darmawan, A. Hadi, and A. Nurrohim, "Rooftop solar power system for EV charging station of household customers in indonesia: a review and an opportunity for developing countries," Evergreen, 11 (2) 24 (2024) doi:10.5109/7183364
67) N. Nurwidiana, B.M. Sopha, and A. Widyaparaga, "Modelling photovoltaic system adoption for households: a systematic literature review," Evergreen, 8 (1) 12 (2021) doi:10.5109/4372262
68) M.A. Santoso, Y. Wijayanti, R.B. Prasetyo, O. Setyandito, A. Subandriya, A.T. Kurniawan, A. Sudaryanto, and B. Sutejo, "A mini review: wave energy converters technology, potential applications and current research in Indonesia," Evergreen, 10 (3) 8 (2023) doi:10.5109/7151712
69) D. Aji, N. Darsono, L. Roza, D.S. Khaerudini, and G.E. Timuda, "Bibliometric analysis of carbon-based electrode perovskite solar cells progress," Sol. Energy, 274 112587 (2024) doi:10.1016/j.solener.2024.112587
70) M. Choifin, A.F. Rodli, A.K. Sari, T. Wahjoedi, and A. Aziz, "A study of renewable energy and solar panel literature through bibliometric positioning during three decades," Libr. Philos. Pract., (2021). doi:https://digitalcommons.unl.edu/libphilprac/5749
71) D.I. Permana, D. Rusirawan, and I. Farkas, "A bibliometric analysis of the application of solar energy to the organic rankine cycle," Heliyon, 8 (4) (2022) doi:10.1016/j.heliyon.2022.e09220
72) H.B. Tambunan, "A Bibliometric Study of Solar Photovoltaic," in: 2022 Int. Conf. Technol. Policy Energy Electr. Power, IEEE, 2022: pp. 180-185 doi:10.1109/ICT-PEP57242.2022.9988834
73) H.B. Tambunan, W. Digwijaya, and A. Nurfanani, "Global research trends in building-integrated photovoltaics: a bibliometric analysis (1971-2022)," Bull. Electr. Eng. Informatics, 14 (1) 43-59 (2025) doi:10.11591/eei.v14i1.7453
74) A.A. Abd, M.R. Othman, Z. Helwani, and J. Kim, "An overview of biogas upgrading via pressure swing adsorption: navigating through bibliometric insights towards a conceptual framework and future research pathways," Energy Convers. Manag., 306 118268 (2024) doi:10.1016/j.enconman.2024.118268
75) E. Krisnaningsih, Marimin, Y. Arkeman, and E. Hambali, "Bibliometric mapping of biomass for energy supply chain model: Review and future research agenda," in: AIP Conf. Proc., AIP Publishing LLC, 2023: p. 130007 doi:10.1063/5.0105064
76) D. Mangindaan, E.R. Kaburuan, and B. Meindrawan, "Black soldier fly larvae (hermetia illucens) for biodiesel and/or animal feed as a solution for waste-food-energy nexus: bibliometric analysis," Sustainability, 14 (21) 13993 (2022) doi:10.3390/su142113993
77) J.H. Pratama, Z. Rahmawati, A.R. Widyanto, T. Gunawan, W.N.W. Abdullah, N.L.A. Jamari, A. Hamzah, and H. Fansuri, "Advancements in green diesel production for energy sustainability: a comprehensive bibliometric analysis," RSC Adv., 14 (48) 36040-36062 (2024) doi:10.1039/d4ra06262k
78) N.R. Putra, I. Veza, and I. Irianto, "Harnessing wood waste for sustainable biofuel: a bibliometric analysis and review of valorisation strategies," Waste Manag. Bull., (2024) doi:10.1016/j.wmb.2024.11.006
79) M. Setiyo, D. Yuvenda, and O.D. Samuel, "The concise latest report on the advantages and disadvantages of pure biodiesel (B100) on engine performance: literature review and bibliometric analysis," Indones. J. Sci. Technol., 6 (3) 469-490 (2021) doi:10.17509/ijost.v6i3.38430
80) A.G. Abdullah, D.L. Hakim, N.T. Sugito, and D. Zakaria, "Investigating evolutionary trends of hybrid renewable energy systems: a bibliometric analysis from 2004 to 2021," Int. J. Renew. Energy Res., 13 (1) 376-391 (2023) doi:10.20508/ijrer.v13i1.13766.g8690
81) S. Sarjana, J.R. Widokarti, H. Fachri, and D. Pranita, "Hybrid energy to drive renewable energy diversity in bibliometric analysis," Int. J. Energy Econ. Policy, 12 (1) 500-506 (2022) doi:10.32479/ijeep.11956
82) J.P.M. Yanuar, P.N. Bambang, A. Saleh, and F.W. Akhmad, "The suitable location for a hybrid renewable energy wind-solar power plant: A review by bibliometric," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2023: p. 12090 doi:10.1088/1755-1315/1266/1/012090
83) M.I. Al Irsyad, A.B. Halog, R. Nepal, and D.P. Koesrindartoto, "Selecting tools for renewable energy analysis in developing countries: an expanded review," Front. Energy Res., 5 (34) (2017) doi:10.3389/fenrg.2017.00034
84) M. Aria, C. Cuccurullo, M. Misuraca, M. Spano, A. Belfiore, L. D’Aniello, and A. Gnasso, "BIBLIOMETRIX," 2024 (24 December) (2024). https://www.bibliometrix.org/home/
85) M. Aria, and C. Cuccurullo, "Bibliometrix: an r-tool for comprehensive science mapping analysis," J. Informetr., 11 (4) 959-975 (2017) doi:10.1016/j.joi.2017.08.007
86) E.C. Campioni, and J.P. Cordia, "Gasoline sweetening operations, Palembang Refinery," in: World Pet. Congr. Proc., 1951: pp. 254-262. https://www.scopus.com/pages/publications/85058171226?inward
87) M. Raynaud, V. Goutaudier, K. Louis, S. Al-Awadhi, Q. Dubourg, A. Truchot, R. Brousse, N. Saleh, A. Giarraputo, and C. Debiais, "Impact of the covid-19 pandemic on publication dynamics and non-covid-19 research production," BMC Med. Res. Methodol., 21 1-10 (2021) doi:10.1186/s12874-021-01404-9
88) A. Suhadi, A. Aprilio, and E. Febriyanti, "Structural strength degradation of oil and gas refinery equipment. case study: heat exchanger tubes of hydrocarbon vapor," Evergreen, 2449-2455 (2023) doi:10.5109/7162005
89) K.F. Hartono, A.K. Permadi, U.W.R. Siagian, A.L.L. Hakim, S. Paryoto, A.H. Resha, Y. Adinugraha, and E.A. Pratama, "The impacts of co2 flooding on crude oil stability and recovery performance," J. Pet. Explor. Prod. Technol., 14 (1) 107-123 (2024) doi:10.1007/s13202-023-01699-y
90) M.S. Indah, A. Haris, and M. Natsir, "Integrated of sequences seismic stratigraphy, accoustic impedance invertion, and petrophysical for resources exploration in offshore southern Ardjuna northwest Java basin, Indonesia," IOP Conf. Ser. Mater. Sci. Eng., 546 (7) 6-11 (2019) doi:10.1088/1757-899X/546/7/072002
91) D. Rosadi, S. Kasmungin, and R. Setiati, "Evaluation of engineering in esp installation with various reservoir properties in the offshore x field," IOP Conf. Ser. Earth Environ. Sci., 802 (1) (2021) doi:10.1088/1755-1315/802/1/012029
92) T. Marhaendrajana, T. Ariadji, and A.K. Permadi, "Performance prediction of a well under multiphase flow conditions," SPE Asia Pacific Oil Gas Conf. Exhib., SPE-80534-MS (2003) doi:10.2118/80534-MS
93) P.A. Aziz, T. Marhaendrajana, and U.W.R. Siagian, "Sanding phenomena vulnerability observations due to CO2 injection at the air benakat reservoir in south sumatera," J. Phys. Conf. Ser., 2734 (1) (2024) doi:10.1088/1742-6596/2734/1/012015
94) M.R. Luthfan, A. Haris, D. Hernadi, and R.M. Zainal, "3D facies modelling of tuban formation, north east Java basin," Eur. Conf. Math. Geol. Reserv. 2022, ECMOR 2022, (2022) doi:10.3997/2214-4609.202244005
95) N. Isniarny, A. Haris, and S. Nurdin, "Fractured-basement reservoir modeling using continuous fracture modeling (cfm) method," AIP Conf. Proc., 1711 (1) 70004 (2016) doi:10.1063/1.4941645
96) J. Tetelepta, O. Firdaus, R. Setiati, M.T. Fathaddin, P.A. Rakhmanto, and I. Sumirat, "The effectiveness of fir wood lignosulphonate surfactant stability on intermediate oil as biomaterial engineering," AIP Conf. Proc., 3019 (1) 90006 (2024) doi:10.1063/5.0226331
97) R. Setiati, S. Siregar, T. Marhaendrajana, and D. Wahyuningrum, "Influence of middle phase emulsion and surfactant concentration to oil recovery using SLS surfactant synthesized from bagasse," IOP Conf. Ser. Earth Environ. Sci., 212 (1) 0-8 (2018) doi:10.1088/1755-1315/212/1/012076
98) M.T. Fathaddin, A. Nugrahanti, P.N. Buang, and K.A. Elraies, "Surfactant-polymer flooding performance in heterogeneous two-layered porous media," IIUM Eng. J., 12 (1) 31-38 (2011) doi:10.31436/iiumej.v12i1.37
99) H.Z.R.R.A.I. Andy Noorsaman Dea Amrializzia, "Machine learning algorithms for failure prediction model and operational reliability of onshore gas transmission pipelines," Int. J. Technol., 14 (3) 680-689 (2023) doi:10.14716/ijtech.v14i3.6287
100) M.A. Budiyanto, T.W. Pribadi, G. Kurnia, and T. Shinoda, "Optimization of principal dimensions of the ship hull for small-scale LNG carrier," Evergreen, 11 (2) 1383-1388 (2024) doi:10.5109/7183450
101) Semin, A.R. Ismail, and R.A. Bakar, "Comparative performance of direct injection diesel engines fueled using compressed natural gas and diesel fuel based on gt-power simulation ," Am. J. Appl. Sci., 5 (5) (2008) doi:10.3844/ajassp.2008.540.547
102) E.C.W. Pribadi, Semin, A. Santoso, B. Cahyono, A. Iswantoro, H. Prasutiyon, and F.M. Felayati, "Lateral swirl combustion system development of dual fuel diesel engine piston to improve efficiency and reduce nox emission ," A Br. Rev. , 12 (4) 218-225 (2024) doi:10.15866/irea.v12i4.23008
103) F.M. Felayati, Semin, B. Cahyono, and R.A. Bakar, "Numerical investigation of dual-fuel engine improvements using split injection natural gas coupled with diesel injection timings at low load condition," Int. J. Eng. Appl., 9 (1) 31-38 (2021) doi:10.15866/irea.v9i1.19622
104) S. Soemardan, W.W. Purwanto, and Arsegianto, "Optimization of the gas production rate by marginal cost analysis ," Influ. Sales Gas Press. Gas Price Durat. Gas Sales Contract , 18 396-404 (2014) doi:10.1016/j.jngse.2014.03.017
105) M. Nizami, H.M.U. Ayub, Slamet, M. Lee, and W.W. Purwanto, "Exploring optimal pathways of the high-co2 content natural gas source to chemicals and fuels using superstructure multi-objective optimization," J. Clean. Prod., 435 140576 (2024) doi:10.1016/j.jclepro.2024.140576
106) A. Muhammad Idrus, Nasruddin, Senoadi, M.B. Perdana, Ratiko, and N. Muhammad Idrus Alhamid Senoadi , M. Bayu Perdana, Ratiko, "Effect of methane gas flow rate on adsorption capacity and temperature distribution of activated carbon," Int. J. Technol., 6 (4) 291-319 (2015) doi:10.14716/ijtech.v6i4.1019
107) C.B. Cecil, F.T. Dulong, J.C. Cobb, and Supardi, "Allogenic and autogenic controls on sedimentation in the central Sumatra basin as an analogue for Pennsylvanian coal-bearing strata in the Appalachian basin," Spec. Pap. Geol. Soc. Am., 286 3-22 (1993) doi:10.1130/SPE286-p3
108) A. Suwono, "Upgrading the Indonesian’s low rank coal by superheated steam drying with tar coating process and its application for preparation of cwm," Coal Prep., 21 (1) 149-159 (1999) doi:10.1080/07349349908945614
109) Hariana, A. Prismantoko, G.A. Ahmadi, and A. Darmawan, "Ash evaluation of Indonesian coal blending for pulverized coal-fired boilers," J. Combust., 2021 (2021) doi:10.1155/2021/8478739
110) S. Suyatno, H. Hariana, A. Prismantoko, H. Prida Putra, N. Mayang Sabrina Sunyoto, A. Darmawan, H. Ghazidin, and M. Aziz, "Assessment of potential tropical woody biomass for coal co-firing on slagging and fouling aspects," Therm. Sci. Eng. Prog., 44 (March) 102046 (2023) doi:10.1016/j.tsep.2023.102046
111) H.T. Petrus, M. Olvianas, M.F. Shafiyurrahman, I.G. Pratama, S.N. Jenie, W. Astuti, M.I. Nurpratama, J.J. Ekaputri, and F. Anggara, "Circular economy of coal fly ash and silica geothermal for green geopolymer: characteristic and kinetic study," Gels, 8 (4) (2022) doi:10.3390/gels8040233
112) F. Anggara, A.A. Patria, B. Rahmat, H. Wibisono, M.Z.J. Putera, H.T.B.M. Petrus, F. Erviana, E. Handini, and D.H. Amijaya, "Signature characteristics of coal geochemistry from the Eocene Tanjung formation and the miocene warukin formation, barito basin: insights into geological control on coal deposition and future critical element prospection," Int. J. Coal Geol., 282 104423 (2024) doi:10.1016/j.coal.2023.104423
113) C.S. Yudha, E. Apriliyani, M. Arinawati, and T. Paramitha, "Carboxylic acid assisted synthesis of crystalline silicon derived from coal fly-ash for li-ion batteries anode material," Evergreen, 11 (3) 8 (n.d.) doi:10.5109/7236882
114) R. Sutriadi, M.I. Yudanto, R.A. Romdan, B.A. Araminta, and I. Alifa, "The multiple effects of mining activities on the ecology and economic development in East Kalimantan province, Indonesia," Evergreen, 11 (2) 11 (n.d.) doi:10.5109/7183384
115) M. Gozali, M. Nuramin, D.W. Karmiadji, W. Sulistiyo, and H. Purnomo, "Structural strength analysis of 57-ton capacity flat carriage coal transporter with 2x20 feet container subjected to operation conditions," Evergreen, 10 (3) 2029-2037 (2023) doi:10.5109/7151770
116) T.S.B. Abd Manan, S. Beddu, D. Mohamad, N.L. Mohd Kamal, W.H.M. Wan Mohtar, T. Khan, H. Jusoh, A. Sarwono, M.M. Ali, Z. Che Muda, F. Mohamed Nazri, M.H. Isa, A.A.J. Ghanim, A. Ahmad, N. Wan Rasdi, and N.A.N. Basri, "Physicochemical and leaching properties of coal ashes from Malaysian coal power plant," Chem. Phys. Lett., 769 138420 (2021) doi:10.1016/j.cplett.2021.138420
117) A.K. Permana, C.R. Ward, Z. Li, and L.W. Gurba, "Distribution and origin of minerals in high-rank coals of the south walker creek area, Bowen basin, Australia," Int. J. Coal Geol., 116-117 185-207 (2013) doi:10.1016/j.coal.2013.03.001
118) H.T.B.M. Petrus, T. Hirajima, Y. Oosako, M. Nonaka, K. Sasaki, and T. Ando, "Performance of dry-separation processes in the recovery of cenospheres from fly ash and their implementation in a recovery unit," Int. J. Miner. Process., 98 (1) 15-23 (2011) doi:10.1016/j.minpro.2010.09.002
119) S.C. Wijayanti, F. Anggara, and H.T.B.M. Petrus, "Effect of Fly Ash (FA) Characteristic on Geopolymer Product Quality BT - Recent Research on Sedimentology, Stratigraphy, Paleontology, Geochemistry, Volcanology, Tectonics, and Petroleum Geology," in: A. Çiner, S. Naitza, A.E. Radwan, Z. Hamimi, F. Lucci, J. Knight, C. Cucciniello, S. Banerjee, H. Chennaoui, D.M. Doronzo, C. Candeias, J. Rodrigo-Comino, R. Kalatehjari, A.A. Shah, M. Gentilucci, D. Panagoulia, H.I. Chaminé, M. Barbieri, Z.A. Ergüler (Eds.), Springer Nature Switzerland, Cham, 2024: pp. 95-98 doi:10.1007/978-3-031-48758-3_22
120) F. Anggara, K. Sasaki, and Y. Sugai, "Mineral dissolution/precipitation during CO2 injection into coal reservoir: a laboratory study," Energy Procedia, 37 6722-6729 (2013) doi:10.1016/j.egypro.2013.06.605
121) H. Poesposeotjipto, A.G. Harsono, and H. Nugroho, "Review and analysis of the global and diffuse solar radiations in Jakarta, Indonesia," Sol. Wind Technol., 1 (3) 135-152 (1984) doi:10.1016/0741-983X(84)90001-8
122) B. Wardono, and R. Nelson, "Simulation of a double-effect libr/h{sub 2}o absorption cooling system," 38 (1996) doi:10.1016/j.applthermaleng.2009.01.006
123) E.J. Amir, K. Grandegger, A. Esper, M. Sumarsono, C. Djaya, and W. Mühlbauer, "Development of a multi-purpose solar tunnel dryer for use in humid tropics," Renew. Energy, 1 (2) 167-176 (1991). doi: doi:10.1016/0960-1481(91)90072-W
124) M. Facta, Hermawan, N.A.K. Umiati, Z. Salam, and Z. Buntat, "Implementation of photovoltaic and simple resonant power converter for high frequency discharge application," ICITACEE 2015 - 2nd Int. Conf. Inf. Technol. Comput. Electr. Eng. Green Technol. Strength. Inf. Technol. Electr. Comput. Eng. Implementation, Proc., 193-196 (2016) doi:10.1109/ICITACEE.2015.7437797
125) M.S. Chye, J.A. Soo, Y.C. Tan, M. Aizuddin, S. Lee, M. Faddle, S.L. Ong, T. Sutikno, and J.H. Leong, "Single-phase multilevel inverter with simpler basic unit cells for photovoltaic power generation," Int. J. Power Electron. Drive Syst., 7 (4) 1233-1239 (2016) doi:10.11591/ijpeds.v7.i4.pp1233-1239
126) Z. Arifin, M.L. Baharuddin, W.E. Juwana, Suyitno, D.D.D.P. Tjahjana, M. Muqoffa, and S.D. Prasetyo, "The effect of adding heatsink cooling with concentrator on increasing photovoltaic performance," AIP Conf. Proc., 2674 (1) 30047 (2023) doi:10.1063/5.0114139
127) B. Bahtiar, M. Zohri, and A. Fudholi, "Experimental investigation of photovoltaic thermal solar air collector with exergy performance comparison," Indones. J. Electr. Eng. Comput. Sci., 19 (2) 652 (2020) doi:10.11591/ijeecs.v19.i2.pp652-658
128) F.D. Lestary, Syafaruddin, and I.S. Areni, "Deep learning implementation for snail trails detection in photovoltaic module," 2022 FORTEI-International Conf. Electr. Eng. FORTEI-ICEE 2022 - Proceeding, (December) 41-46 (2022) doi:10.1109/FORTEI-ICEE57243.2022.9972952
129) B. Pranoto, M.I. Al Irsyad, A.L.S.M. Sihombing, and V. Nurliyanti, "Hybrid floating photovoltaic-hydropower potential utilization in Indonesia," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2022: p. 12004 doi:10.1088/1755-1315/1105/1/012004
130) V. Nurliyanti, K. Ahadi, R. Muttaqin, B. Pranoto, G.P. Srikandi, and M.I. al Irsyad, "Fostering Rooftop Solar PV Investments Toward Smart Cities through e-SMART PV," in: 2021 5th Int. Conf. Smart Grid Smart Cities, IEEE, 2021: pp. 146-150 doi:10.1109/ICSGSC52434.2021.9490406
131) M.I. Al Irsyad, A. Halog, and R. Nepal, "Estimating the impacts of financing support policies towards photovoltaic market in Indonesia: a social-energy-economy-environment model simulation," J. Environ. Manage., 230 464-473 (2019) doi:10.1016/j.jenvman.2018.09.069
132) C.H.B. Apribowo, S.P. Hadi, and F.D. Wijaya, "Optimal sizing and siting of fresh and second-life battery energy storage systems based on linearized optimal power flow for high photovoltaic penetration: a comparative study," Evergreen, 11 (3) 14 (n.d.) doi:10.5109/7236864
133) V. Nurliyanti, M. Pandin, G.T. Setiadanu, H. Al Rasyid, D.G. Cendrawati, A. Halog, and M.I. Al Irsyad, "Exploring Alternative Policies to Reduce Electricity Subsidies in Indonesia," in: 6th Int. Conf. Sustain. Renew. Energy Eng., IEEE, 2021: pp. 1-6 doi:10.1051/e3sconf/202129402005
134) A. Rajani, D.M. Said, Z.A. Noorden, N. Ahmad, S.A. Ginting, and T.D. Atmaja, "U-turn shape effect on effective thermal conductivity of double pass photovoltaic thermal (pvt) systems configuration," CFD Lett., 17 (5) 12-25 (2024) doi:10.37934/cfdl.17.5.1225
135) A. Kristi, E. Susanto, A. Risdiyanto, A. Junaedi, R. Darussalam, N.A. Rachman, and A. Fudholi, "Energy analysis of active photovoltaic cooling system using water flow," Int. J. Electr. Comput. Eng., 15 (1) (2025) doi:10.11591/ijece.v15i1.pp1-14
136) Z. Arifin, M.F. Hakimi, S. Hadi, S.D. Prasetyo, and W.B. Bangun, "The impact of cuo nanofluid volume fraction on photovoltaic-thermal collector (pv/t) performance," Evergreen, 11 (3) 8 (n.d.) doi:10.5109/7236877
137) D.B. Seto, Z. Arifin, B. Kristiawan, and S.D. Prasetyo, "Nanoparticle-enhanced phase change materials (nepcm) in passive cooling systems to improve solar panel efficiency," Int. Rev. Mech. Eng., 18 (1) 20-27 (2024) doi:10.15866/ireme.v18i1.24149
138) M. Hijriawan, Z. Arifin, D.D.D.P. Tjahjana, and I.W. Kuncoro, "Performance analysis of flat winglet deflector on hybrid solar pv-wind turbine system: case study on twisted savonius turbine," J. Appl. Eng. Sci., 22 (1) 69-80 (2024) doi:10.5937/jaes0-44759
139) K. Miyazaki, I. Zulkarnain, J. Sopaheluwakan, and K. Wakita, "Pressure-temperature conditions and retrograde paths of eclogites, garnet-glaucophane rocks and schists from South Sulawesi, Indonesia," J. Metamorph. Geol., 14 (5) 549-563 (1996) doi:10.1046/j.1525-1314.1996.00381.x
140) D. Yunus, S. Sudarman, and K. Ushijima, "Imaging reservoir structure of the Sibayak geothermal field (Indonesia) based on magnetotelluric observations," Trans. - Geotherm. Resour. Counc., 419-423 (2002). doi:https://gbank.gsj.jp/ld/resource/geolis/200300091.html
141) H.B. Pratama, and N.M. Saptadji, "Numerical simulation for natural state of two-phase liquid dominated geothermal reservoir with steam cap underlying brine reservoir," IOP Conf. Ser. Earth Environ. Sci., 42 (1) 12006 (2016) doi:10.1088/1755-1315/42/1/012006
142) C.R.I. Ponggohong, Suryantini, and B.P. Angga, "3D geological and isothermal model of geothermal field based on the integration of geoscience and well data," IOP Conf. Ser. Earth Environ. Sci., 417 (1) (2020) doi:10.1088/1755-1315/417/1/012001
143) H. Soekarno, B. Pranoto, A.F. Azzahra, S. Emo, N. Hudayat, and Widhiatmaka, "Application of gravity data ggmplus for identification of geological fault in the Bittuang geothermal prospect area, Tana Toraja," AIP Conf. Proc., 3069 (1) (2024) doi:10.1063/5.0207865
144) H. Soekarno, B. Pranoto, A. Restiana, A. Adi Martha, T. Azhar Prakoso Setiadi, N. Hudayat, A. Fachrudin Rais, Y. Suwarno, T. Turmudi, and B. Sutejo, "Identifying geological fault structures using GGMplus satellite data and derivative methods to characterize mount Endut geothermal systems via 3d-inversion gravity modeling," Geomatics Environ. Eng., 19 (3) 31-62 (2025) doi:10.7494/geom.2025.19.3.31
145) S.N.A. Jenie, A. Ghaisani, Y.P. Ningrum, A. Kristiani, F. Aulia, and H.T.M.B. Petrus, "Preparation of silica nanoparticles from geothermal sludge via sol-gel method," AIP Conf. Proc., 2026 (1) 20008 (2018) doi:10.1063/1.5064968
146) F. Pratama, N. Reyseliani, A. Syauqi, Y. Daud, W.W. Purwanto, P.P.D.K. Wulan, and A. Hidayatno, "Thermoeconomic assessment and optimization of wells to flash–binary cycle using pure r601 and zeotropic mixtures in the sibayak geothermal field," Geothermics, 85 (December 2019) 101778 (2020) doi:10.1016/j.geothermics.2019.101778
147) P.C.B.W. Mustika, W. Astuti, S. Sumardi, H.T.B.M. Petrus, and Sutijan, "Separation characteristic and selectivity of lithium from geothermal brine using forward osmosis," J. Sustain. Metall., 8 (4) 1769-1784 (2022) doi:10.1007/s40831-022-00602-z
148) A. Saepuloh, W.C. Dewi, A.B. Harto, and Agustan, "Occurrence of Geothermal Features Based on Surface Roughness and Geobotanical Analyses derived by ALOS-2 PALSAR-2 and Sentinel-2 Images," in: 2021 7th Asia-Pacific Conf. Synth. Aperture Radar, 2021: pp. 1-6 doi:10.1109/APSAR52370.2021.9688361
149) L. Putriyana, M. Nuriyadi, E. Djubaedah, Y. Gunawan, and N. Nasruddin, "Investigating techno-economic feasibility of geothermal polygeneration in Nusalaut island, central Maluku district, Maluku province," Evergreen, 10 (4) 12 (2023) doi:10.5109/7162007
150) M.I. Al Irsyad, A. Halog, and R. Nepal, "Renewable energy projections for climate change mitigation: an analysis of uncertainty and errors," Renew. Energy, 130 536-546 (2019) doi:10.1016/j.renene.2018.06.082
151) I.M.A.D. Susila, I. Negara, M.I. Al Irsyad, H. Al Rasyid, and A. Ladiba, "Model design of geothermal development plan in conservation forest: A case study in Mount Ciremai National Park," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2022: p. 12034 doi:10.1088/1755-1315/1108/1/012034
152) A.F. Ladiba, G.P. Srikandi, A.L. Sihombing, H.A. Rasyid, I. Susila, and M.I.A. Irsyad, "Economic value of carbon sequestration in conservation forests for geothermal power plant development areas," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2022: p. 12025 doi:10.1088/1755-1315/1108/1/012025
153) N.A. Pambudi, V.S. Pramudita, M.K. Biddinika, and S. Jalilinasrabady, "So close yet so far - how people in the vicinity of potential sites respond to geothermal energy power generation: an evidence from Indonesia," Evergreen, 9 (1) 1-9 (2022) doi:10.5109/4774210
154) R. Prasetio, J. Hutabarat, Y. Daud, and H. Hendarmawan, "Distribution of 222rn and co2 across faults and its origin in wayang windu geothermal area, West Java-Indonesia," Geothermics, 110 102691 (2023) doi:10.1016/j.geothermics.2023.102691
155) Y. Daud, W.A. Nuqramadha, A. Fitriastuti, D. Darmawan, F. Fahmi, M.A. Tifani, S. Tarmidi, C. Iskandar, and R.F. Ibrahim, "Investigation of deep-seated heat source through 3-d magnetotelluric inversion in arjuno-welirang volcanic complex (east java)," Geothermics, 113 102768 (2023) doi:10.1016/j.geothermics.2023.102768
156) H.B. Pratama, K. Koike, A.B. Pratama, B.A. Kusumasari, A. Ashat, and T.A.F. Soelaiman, "Numerical simulation–based optimization of an integrated framework for the efficient development and sustainable utilization of geothermal resources: application to the Bedugul geothermal field," Geothermics, 127 103208 (2025) doi:10.1016/j.geothermics.2024.103208
157) P.V. Tongkeles, Suryantini, and A.B. Pratama, "The Application of Electrical Resistivity Tomography using Wenner-Schlumberger Arrays Configuration to Identify the Geological Structure in Kancah Warm Spring, West Java Indonesia," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2022: p. 12015 doi:10.1088/1755-1315/1047/1/012015
158) N.D. Kobare, and I. Iskandar, "Geochemical investigation on the implications of fluid origin, subsurface processes and recharge on the tangkuban perahu geothermal conceptual model," Geothermics, 110 102685 (2023) doi:10.1016/j.geothermics.2023.102685
159) B.W. Jatmiko, M.H. Assiddiqy, P. Ediatmaja, R. Prabowo, H.B. Pratama, M.R. Hamdani, Sutopo, H.B. Pratama, and M.R. Hamdani, "Resource Assessment of Ungaran Geothermal Field Using Numerical model and Monte Carlo Simulation," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2022: p. 12021 doi:10.1088/1755-1315/1031/1/012021
160) R. Huwae, H. Sudibyo, R.A. Subekti, A. Susatyo, and D.S. Khaerudini, "A Review: Gravitational Water Vortex Power Plant," in: 2020 Int. Conf. Sustain. Energy Eng. Appl., 2020: pp. 1-7 doi:10.1109/ICSEEA50711.2020.9306140
161) R.A. Subekti, F. Mohd-Zawawi, K. Ismail, G. Pikra, A. Susatyo, H. Sudibyo, E. Riyanto, A. Fudholi, D.G. Subagio, A. Rajani, P. Irasari, T.D. Atmaja, Y. Radiansah, and S.K. Wijaya, "Analysis of vortex turbine performance improvement: a review," AIP Conf. Proc., 3069 (1) 20042 (2024) doi:10.1063/5.0207861
162) D.M. Prabowoputra, S. Hadi, D.D.D.P. Tjahjana, and A.C. Rizqulloh, "Computational fluid dynamics method for predicting savonius water turbine performance with fin-blade," Math. Model. Eng. Probl., 11 (6) 1649-1654 (2024) doi:10.18280/mmep.110627
163) B. Pranoto, E. Hartulistiyoso, M.N. Aidi, D. Sutrisno, H. Soekarno, L. Efiyanti, D.A. Indrawan, Y.I. Rahmila, M.A. Anwar, Y. Gunawan, and M. Yulianti, "Sustainability assessment of hydropower: a comprehensive systematic literature review of environmental, social, economic, and technical dimensions," J. Sustain. Sci. Manag., 20 (3) 575-612 (2025) doi:10.46754/jssm.2025.03.010
164) B. Pranoto, E. Hartulistiyoso, M.N. Aidi, D. Sutrisno, H. Soekarno, A.A. Martha, Q. Zahro, Y.I. Rahmila, and V. Nurliyanti, "Assessing the sustainability of small hydropower potential in the threats of natural disasters: an analytic hierarchy process-based approach," Evergreen, 11 (3) 8 (2024) doi:10.5109/7236910
165) B. Pranoto, H. Soekarno, E. Hartulistiyoso, M.N. Aidi, D. Sutrisno, D. Pohan, B. Sutejo, A.H. Kuncoro, and I. Nahib, "Integrating flood early warning system (FEWS) for optimizing small hydropower sites: a West Java case study," Evergreen, 11 (3) 2691-2699 (2024) doi:10.5109/7236908
166) B. Pranoto, H. Soekarno, D.G. Cendrawati, I.F. Akrom, M.I.A.A. Irsyad, N.W. Hesty, Aminuddin, I. Adilla, L. Putriyana, A.F. Ladiba, Widhiatmaka, R. Darmawan, S.R. Fithri, R. Isdiyanto, V.J. Wargadalam, M. Magdalena, and M. Aman, "Indonesian hydro energy potential map with run-off river system," IOP Conf. Ser. Earth Environ. Sci., 926 (1) 12003 (2021) doi:10.1088/1755-1315/926/1/012003
167) H. Sudibyo, R.A. Subekti, and A. Susatyo, "Feasibility study of energy conversion system of minihydro scale in Garut Regency, West Java," in: 2017 Int. Conf. Sustain. Energy Eng. Appl., 2017: pp. 98-105 doi:10.1109/ICSEEA.2017.8267693
168) Widhiatmaka, B. Pranoto, H. Soekarno, A. Nurrohim, and S. Emo, "Micro-hydro potential assessment in Kali Ombak, Maybrat regency, West Papua province," AIP Conf. Proc., 3069 (1) (2024) doi:10.1063/5.0205756
169) P. Irasari, M. Kasim, M. Hikmawan, and ..., "Optimization of modular stator construction to improve permanent magnet generator characteristics for very low head hydro power application," 2017 Int. …, (2017) doi:10.1109/ICSEEA.2017.8267702
170) Y. Susilowati, P. Irasari, Y. Kumoro, W.H. Nur, and Yunarto, "Watershed Management for Micro Hydropower Plant Sustainability: Malabar, Indonesia," in: 2020 Int. Conf. Sustain. Energy Eng. Appl., 2020: pp. 151-158 doi:10.1109/ICSEEA50711.2020.9306141
171) B. Pranoto, E. Hartulistiyoso, M. Nur, D. Sutrisno, and I. Nahib, "Assessing the sustainability of small hydropower sites in the citarum watershed , Indonesia employing ca-markov and SWAT models," 24 (9) 3253-3268 (2024) doi:10.2166/ws.2024.209
172) Y. Kumoro, Y. Susilowati, P. Irasari, W.H. Nur, and Yunart, "Geological aspect analysis for micro hydro power plant site selection based on remote sensing data," 12 (3) 2300-2312 (2022) doi:10.11591/ijece.v12i3.pp2300-2312
173) H. Prasetyo, E.P. Budiana, D. Tjahjana, and S. Hadi, "The simulation study of horizontal axis water turbine using flow simulation solidworks application," IOP Conf. Ser. Mater. Sci. Eng., 308 (1) 2-7 (2018) doi:10.1088/1757-899X/308/1/012022
174) I. Hamzah, A. Prasetyo, D.D.D.P. Tjahjana, and S. Hadi, "Effect of blades number to performance of savonius water turbine in water pipe," AIP Conf. Proc., 1931 (July) 1-6 (2018) doi:10.1063/1.5024105
175) R. Handoko, M.D. Septiyanto, D.D.D.P. Tjahjana, D.A. Himawanto, I. Yaningsih, and S. Hadi, "Performance testing and analysis of gravitational water vortex turbine: a modified experimental study on blade arc and inclination angle," J. Adv. Res. Fluid Mech. Therm. Sci., 109 (1) 147-161 (2023) doi:10.37934/arfmts.109.1.147161
176) A.S. Silitonga, A.E. Atabani, T.M.I. Mahlia, H.H. Masjuki, I.A. Badruddin, and S. Mekhilef, "A review on prospect of jatropha curcas for biodiesel in Indonesia," Renew. Sustain. Energy Rev., 15 (8) 3733-3756 (2011). doi: doi:10.1016/j.rser.2011.07.011
177) R.-J. Van Putten, J.C. Van Der Waal, E.D. De Jong, C.B. Rasrendra, H.J. Heeres, and J.G. de Vries, "Hydroxymethylfurfural, a versatile platform chemical made from renewable resources," Chem. Rev., 113 (3) 1499-1597 (2013) doi:10.1021/cr300182k
178) N.K. Supriatna, D. Suntoro, M.I. Al Irsyad, G.P. Srikandi, T. Khaldun, and R. Anggarani, "Performance and emission effects of biodiesel 30%(B30) usage in oil-fired power plants and gas engine power plants," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2021: p. 12056 doi:10.1088/1755-1315/749/1/012056
179) Y. Gunawan, A.I. Firmansyah, N.K. Supriatna, M.I. al Irsyad, D.G. Cendrawati, K. Ahadi, I. Adilla, and A.S. Silitonga, "Comprehensive assessment using preheat crude palm oil on endurance test engine diesel: technical and supply chain scheme," Ind. Crops Prod., 204 117286 (2023) doi:10.1016/j.indcrop.2023.117286
180) A. Soemanto, E. Mohi, M.I. al Irsyad, and Y. Gunawan, "The role of oil fuels on the energy transition toward net zero emissions in indonesia: a policy review," Evergr. Jt. J. Nov. Carbon Resour. Sci. Green Asia Strateg., 10 (04) 2074-2083 (2023) doi:10.5109/7160867
181) R. Rame, P. Purwanto, and S. Sudarno, "Sustainable energy harnessing: microalgae as a potential biofuel source and carbon sequestration solution," Renew. Energy Focus, 47 100498 (2023) doi:10.1016/j.ref.2023.100498
182) A.A. Almulqu, "Carbon Sequestration Dynamics of Tree Species in Dry Forest BT - Economics and Policy of Energy and Environmental Sustainability," in: N.N. Dalei, A. Gupta (Eds.), Springer Nature Singapore, Singapore, 2022: pp. 315-322 doi:10.1007/978-981-19-5061-2_17
183) S. Steven, N.T.U. Culsum, I.C. Sophiana, I. Febijanto, E. Syamsudin, N. Ghazali, N. Nadirah, E.S.A. Soekotjo, and I.M. Hidayatullah, "Potential of corn cob sustainable valorization to fuel-grade bioethanol: a simulation study using superpro designer®," Evergreen, 10 (4) 12 (n.d.) doi:10.5109/7160904
184) N. Dewayanto, K. Adhi, N.A.K. Negara, B.R. Sadewo, A.F. Nisya, O. Prakoso, Hariyadi, U. Sigit, E.A. Suyono, and A. Budiman, "Study of low cost of microalgae chlorella sp. harvesting using cationic starch flocculation technique for biodiesel production," IOP Conf. Ser. Earth Environ. Sci., 1151 (1) (2023) doi:10.1088/1755-1315/1151/1/012042
185) I.A.A. Suwandhi, Sajidan, A. Budiman, and M. Masykuri, "Enhancing biogas production of tofu wastewater by co-digestion," AIP Conf. Proc., 3074 (1) 20011 (2024) doi:10.1063/5.0211284
186) T. Erfianti, K.Q. Maghfiroh, R. Amelia, D. Kurnianto, B.R. Sadewo, S. Marno, I. Devi, N. Dewayanto, A. Budiman, and E.A. Suyono, "Nitrogen sources affect the growth of local strain euglena sp. isolated from Dieng peatland, Central Java, Indonesia, and their potential as bio-avtur," IOP Conf. Ser. Earth Environ. Sci., 1151 (1) (2023) doi:10.1088/1755-1315/1151/1/012059
187) A.A. Anugrah, R. Febrino, M.E. Toif, R. Ringgani, and A. Budiman, "Kinetic studies of levulinic acid production from acid-catalyzed hydrolysis of sugar cane bagasse," AIP Conf. Proc., 2751 (January 2023) (2023) doi:10.1063/5.0151957
188) D. Widayat, H.N. Aulia, D. Hadiyanto, and S.B. Sasongko, "Kinetic study on ultrasound assisted biodiesel production from waste cooking oil," J. Eng. Technol. Sci., 47 (4) 374-388 (2015) doi:10.5614/j.eng.technol.sci.2015.47.4.3
189) Widayat, H. Satriadi, P.W. Setyojati, D. Shihab, L. Buchori, H. Hadiyanto, and F.A. Nurushofa, "Preparation cao/mgo/fe3o4 magnetite catalyst and catalytic test for biodiesel production ," Results Eng. , 22 (2024). doi:10.1016/j.rineng.2024.102202
190) K. Kusmiyati, H. Hadiyanto, and A. Fudholi, "Treatment updates of microalgae biomass for bioethanol production: a comparative study," J. Clean. Prod., 383 135236 (2023) doi:10.1016/j.jclepro.2022.135236
191) H. Prasetiawan, D.S. Fardhyanti, W. Fatrisari, and H. Hadiyanto, "Preliminary study on the bio-oil production from multi feed-stock biomass waste via fast pyrolysis process," J Adv Res Fluid Mech Therm Sci, 103 (2) 216-227 (2023) doi:10.37934/arfmts.103.2.216227
192) Y. Wahyono, H. Hadiyanto, S.H. Gheewala, M.A. Budihardjo, J. Adiansyah, W. Widayat, and M. Christwardana, "Life cycle assessment for evaluating the energy balance of the multi-feedstock biodiesel production process in Indonesia," Int. J. Ambient Energy, 44 (1) 1255-1270 (2023) doi:10.1080/01430750.2023.2171485
193) P. Sharma, B.B. Sahoo, Z. Said, H. Hadiyanto, X.P. Nguyen, S. Nižetić, Z. Huang, A.T. Hoang, and C. Li, "Application of machine learning and box-behnken design in optimizing engine characteristics operated with a dual-fuel mode of algal biodiesel and waste-derived biogas," Int. J. Hydrogen Energy, 48 (18) 6738-6760 (2023) doi:10.1016/j.ijhydene.2022.04.152
194) F. Kusumo, T.M.I. Mahlia, A.H. Shamsuddin, A.R. Ahmad, A.S. Silitonga, S. Dharma, M. Mofijur, F. Ideris, H.C. Ong, R. Sebayang, J. Milano, M.H. Hassan, and M. Varman, "Optimisation of biodiesel production from mixed sterculia foetida and rice bran oil," Int. J. Ambient Energy, 43 (1) 4380-4390 (2022) doi:10.1080/01430750.2021.1888802
195) T.M. Riayatsyah, R. Thaib, A.S. Silitonga, J. Milano, A.H. Shamsuddin, A.H. Sebayang, Rahmawaty, J. Sutrisno, and T.M. Mahlia, "Biodiesel production from reutealis trisperma oil using conventional and ultrasonication through esterification and transesterification," Sustainability, 13 (6) (2021) doi:10.3390/su13063350
196) S. Thanikodi, J. Milano, A.H. Sebayang, A.H. Shamsuddin, S.M. Rangappa, S. Siengchin, A.S. Silitonga, A.H. Bahar, H. Ibrahim, and S.M. Benu, "Enhancing the engine performance using multi fruits peel (exocarp) ash with nanoparticles in biodiesel production," Energy Sources, Part A Recover. Util. Environ. Eff., 45 (1) 2122-2143 (2023) doi:10.1080/15567036.2023.2185317
197) M.M. Sari, T. Inoue, N.H. Putri, I.Y. Septiariva, R. Mulyana, W. Prayogo, N.N. Arifianingsih, and I.W.K. Suryawan, "Advancing towards greener healthcare: innovative solutions through single-use mask waste to refuse-derived fuel utilization," Clean. Responsible Consum., 13 100194 (2024) doi:10.1016/j.clrc.2024.100194
198) A.U. Farahdiba, Y. Franciscus, A. Yuniarto, and J. Hermana, "Food waste flows for energy recovery: a material flow analysis approach in urban cities of Indonesia (study case: surabaya city)," Evergreen, 11 (3) 13 (2024) doi:10.5109/7236912
199) N.L. Zahra, I. Rahmalia, F.D. Qonitan, I.W.K. Suryawan, and A. Sarwono, "Characterization and Potential Analysis of Paper Waste as Raw Material for Refuse Derived Fuel (RDF) Pellet Substitution BT - Proceedings of the International Conference on Emerging Smart Cities (ICESC2022)," in: B.S. Mohammed, T.H. Min, M.H. Sutanto, T.B. Joewono, S. As’ad (Eds.), Springer Nature Singapore, Singapore, 2024: pp. 165-180 doi:10.1007/978-981-99-1111-0_15
200) I.A. Marie, S. Herliana, E. Sari, R. Ruhiyat, and T.N.A.B. Raja Mamat, "Sustainable lean supply chain design in the refuse derived fuel production process at teaching factory Gunung Putri district," AIP Conf. Proc., 3215 (1) 90015 (2024) doi:10.1063/5.0235651
201) S.A. Aziz, N. Astrini, E. Rianawati, A. Halog, and M.I. Al Irsyad, "Challenges in Adopting Successful Waste-to-Energy Policies in EU Countries: Indonesia study case," in: 2022 IEEE Electr. Power Energy Conf., IEEE, 2022: pp. 278-283 doi:10.1109/EPEC56903.2022.10000255
202) A.A. Jumhur, Sirojuddin, Y.B. Garendi, and P. Chandra, "Design of a thermally resistant and safe door for a medical waste pyrolysis incinerator in a green environment," J. Phys. Conf. Ser., 2866 (1) (2024) doi:10.1088/1742-6596/2866/1/012091
203) I. Febijanto, S. Steven, N. Nadirah, H. Bahua, A. Shoiful, P.D. Dian, A.K. I P, A.H. Khalda, M. Yuliani, and M. Hanif, "Municipal solid waste (msw) reduction through incineration for electricity purposes and its environmental performance: a case study in Bantargebang, West Java, Indonesia," Evergreen, 11 (1) 13 (n.d.) doi:10.5109/7172186
204) F.M. Redfern, S.-L. Lin, L.-C. Wang, J.-L. Wu, and M.P. Endah Mutiara, "PBDE emissions during the start-up procedure of an industrial waste incinerator by the co-combustion of waste cooking oil and diesel fuel," Aerosol Air Qual. Res., 17 (4) 975-989 (2017) doi:10.4209/aaqr.2017.02.0066
205) M. Sarosa, R.I. Hapsari, S. Adhisuwignjo, D. Moentamaria, B. Irawan, R.I. Putri, and S. Wirayoga, "Internet of Things (IoT) Based Garbage Incinerator Monitoring System," in: 2022 Int. Conf. Electr. Inf. Technol., 2022: pp. 146-149 doi:10.1109/IEIT56384.2022.9967906
206) H. Hariana, H. Ghazidin, A. Darmawan, E. Hilmawan, and M. Aziz, "Effect of additives in increasing ash fusion temperature during co-firing of coal and palm oil waste biomass," Bioresour. Technol. Reports, 23 101531 (2023) doi:10.1016/j.biteb.2023.101531
207) H.P. Putra, F.M. Kuswa, H. Ghazidin, and A. Darmawan, "Slagging-fouling evaluation of empty fruit bunch and palm oil frond mixture with bituminous ash coal as co-firing fuel," Bioresour. Technol. Reports, 22 101489 (2023) doi:10.1016/j.biteb.2023.101489
208) H.P. Putra, E. Hilmawan, A. Darmawan, K. Mochida, and M. Aziz, "Theoretical and experimental investigation of ash-related problems during coal co-firing with different types of biomass in a pulverized coal-fired boiler," Energy, 269 126784 (2023) doi:10.1016/j.energy.2023.126784
209) A.M. Shiddiq Yunus, A. Abu-Siada, and M.A.S. Masoum, "Improving dynamic performance of wind energy conversion systems using fuzzy-based hysteresis current-controlled superconducting magnetic energy storage," IET Power Electron., 5 (8) 1305-1314 (2012) doi:10.1049/iet-pel.2012.0135
210) Sudarsono, Purwanto, and J. Wahyuadi, "Optimization design of airfoil propellers of modified naca 4415 using computational fluids dynamics," Adv. Mater. Res., 0 (March 2016) 403-407 (2013) doi:10.4028/www.scientific.net/amr.0.403
211) Syafii, and K.M. Nor, "Renewable distributed generation models in three-phase load flow analysis for smart grid," Telkomnika, 11 (4) 661-668 (2013) doi:10.12928/telkomnika.v11i4.1152
212) M. Hijriawan, I.W. Kuncoro, D.D.D.P. Tjahjana, and Z. Arifin, "Performance improvement on savonius helix wind turbine: an endplate effect in the configuration of hybrid solar PV-wind turbine system," AIP Conf. Proc., 3124 (1) 60006 (2024) doi:10.1063/5.0227758
213) L. Gumilar, A.A.B.A. Samat, M.A. Habibi, Sujito, and A.N. Afandi, "Power Quality Evaluation in Electrical Power System after Interconnection with Wind Farm," in: 2023 6th Int. Conf. Inf. Commun. Technol., 2023: pp. 23-28 doi:10.1109/ICOIACT59844.2023.10455948
214) Y.D. Herlambang, Supriyo, B. Prasetiyo, A.S. Alfauzi, T. Prasetyo, Marliyati, and F. Arifin, "Experimental and simulation investigation on savonius turbine: influence of inlet-outlet ratio using a modified blade shaped to improve performance," Evergreen, 9 (2) 7 (2022) doi:10.5109/4794172
215) N. Shobah, N. Suprapto, E. Hariyono, H.N. Hidaayatullaah, B.K. Prahani, F.C. Wibowo, and L.A. Sanjaya, "Development of generator windmills with dynamo torch as steam learning on energy conversion materials," AIP Conf. Proc., 3116 (1) 100013 (2024) doi:10.1063/5.0210457
216) N.W. Hesty, D.G. Cendrawati, R. Nepal, and M.I. Al Irsyad, "Wind energy potential assessment based-on wrf four-dimensional data assimilation system and cross-calibrated multi-platform dataset," IOP Conf. Ser. Earth Environ. Sci., 897 (1) 012004 (2021) doi:10.1088/1755-1315/897/1/012004
217) Aminuddin, N.W. Hesty, N.K. Supriatna, K. Akhmad, Arief Heru Kuncoro, V. Nurliyanti, M.B. Rahardja, S. Sudarto, W. Mulyadi, and P.A Utama, "Promoting wind energy by robust wind speed forecasting using machine learning algorithms optimization," Evergreen, 11 (1) 354-370 (2024) doi:10.5109/7172293
218) M.I. Al Irsyad, A. Halog, R. Nepal, and D.P. Koesrindartoto, "Economical and environmental impacts of decarbonisation of Indonesian power sector," J. Environ. Manage., 259 109669 (2020) doi:10.1016/j.jenvman.2019.109669
219) N.W. Hesty, N.K. Supriatna, D.G. Cendrawati, V. Nurliyanti, A. Nurrohim, S.R. Fithri, N. Niode, and M.I. Al Irsyad, "Unlocking development of green hydrogen production through techno-economic assessment of wind energy by considering wind resource variability: a case study," Int. J. Hydrogen Energy, (2024) doi:10.1016/j.ijhydene.2024.09.294
220) Soedibyo, A.L.S. Budi, M. Ashari, D.C. Riawan, and F.A. Pamuji, "Wind Turbine Penetration Power Stability on Standalone Photovoltaic Hybrid Storage System," in: 2022 2nd Int. Conf. Electron. Electr. Eng. Intell. Syst., 2022: pp. 89-93 doi:10.1109/ICE3IS56585.2022.10010190
221) Harmini, M. Ashari, and F.A. Pamuji, "A new Multi-Input DC-DC Converter integrated MPPT system for Hybrid Renewable Energy and Battery Storage," in: 2022 Int. Semin. Intell. Technol. Its Appl., 2022: pp. 434-439 doi:10.1109/ISITIA56226.2022.9855355
222) H. Suryoatmojo, T.B. Priambodo, Soedibyo, A.F. Rosyidi, Prabowo, and D.A. Asfani, "Power Management in PV-Wind Hybrid with Storage System Based on Multi-input DC-DC Converter," in: 2022 10th Int. Conf. Smart Grid Clean Energy Technol., 2022: pp. 20-25 doi:10.1109/ICSGCE55997.2022.9953593
223) R.I. Putri, M. Rifa’i, F. Ronilaya, I.N. Syamsiana, and S. Riskitasari, "Design of multi input sepic converter for wind/ pv hybrid energy system application," ARPN J. Eng. Appl. Sci., 18 (9) 1046-1051 (2023) doi:10.59018/0523136
224) B. Anggara, E.P. Budiana, C. Harsito, K. Enoki, K.-S. Kim, I. Yaningsih, and D.D.D.P. Tjahjana, "Performance improvement of h-darrieus wind turbine with high efficiency vortex structure attachment," Evergreen, 10 (1) 7 (2023) doi:10.5109/6782153
225) I. Yaningsih, D.D.D.P. Tjahjana, E.P. Budiana, M. Muqoffa, Z. Arifin, K. Enoki, and T. Miyazaki, "Numerical study on the effect of rectangular and triangular counter-rotating vortex generators on the h-rotor wind turbine performance," Evergreen, 10 (1) 11 (2023) doi:10.5109/6781073
226) L. Gumilar, A.A.B.A. Samat, D. Monika, S.N. Rumokoy, and D.E. Cahyani, "Study of current and voltage stability as a result of inertia settings in wind power plants," in: 2023 Int. Semin. Appl. Technol. Inf. Commun., 2023: pp. 75-79 doi:10.1109/iSemantic59612.2023.10295296
227) L. Gumilar, I.J. Permana, and S.N. Rumokoy, "Variation of wind power plant pitch angle setting to short circuit fault current variations level," in: 2023 10th Int. Conf. Inf. Technol. Comput. Electr. Eng., 2023: pp. 106-110 doi:10.1109/ICITACEE58587.2023.10277605
228) M.F. Hikmawan, and B. Azhari, "Magnets’ shape variation of flat linear permanent magnet generator for wave energy conversion," in: AIP Conf. Proc., AIP Publishing, 2024 doi:10.1063/5.0207990
229) K.T. Waskito, A. Geraldi, A.C. Ichi, G.P. Rahardjo, and I. Al Ghifari, "Design of hydraulic power take-off systems unit parameters for multi-point absorbers wave energy converter," Energy Reports, 11 115-127 (2024) doi:10.1016/j.egyr.2023.11.042
230) V.V.R. Repi, and A.T. Diputra, "Simulation and validation of floating-point absorber (FPA) wave energy converter (WEC) using open-source WEC-Sim simulation," in: AIP Conf. Proc., AIP Publishing, 2022 doi:10.1063/5.0108138
231) E.M. Suyanto, S.P. Fitri, D. Rahuna, and A. Kasharjanto, "Experimental Study of the Influence Wave Period on the Performance Darrieus Turbine with Modification of the Blade Angle," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2023: p. 12020 doi:10.1088/1755-1315/1166/1/012020
232) F.O. Setyawan, A. Sartimbul, M.A.Z.Z. Fuad, Q. Ussania, F. Hidayatullah, N.A. Haq, and D. Satrio, "Ocean wave energy potential in southern waters of Malang," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2024: p. 12009 doi:10.1088/1755-1315/1328/1/012009
233) A.W. Pertala, I.H. Suherman, A.H.P.P. Kesumajana, and H. Kurnio, "Assessing the optimal location for Sipora wave energy power generator site placement from a geological perspective," in: IOP Conf. Ser. Earth Environ. Sci., IOP Publishing, 2022: p. 12036 doi:10.1088/1755-1315/1047/1/012036
234) R. Hantoro, E. Septyaningrum, Y.R. Hudaya, and I. Utama, "Stability analysis for trimaran pontoon array in wave energy converter–pendulum system (wec-ps)," Brodogr. An Int. J. Nav. Archit. Ocean Eng. Res. Dev., 73 (3) 59-68 (2022) doi:10.21278/brod73304
235) M. Yusup, S. Dwijayanti, H. Hikmarika, Z. Husin, and B.Y. Suprapto, "Gyroscope control system in wave power plant using PID controller," in: 2021 Int. Conf. Converging Technol. Electr. Inf. Eng., IEEE, 2021: pp. 54-58 doi:10.1109/ICCTEIE54047.2021.9650656
236) H. Juliani, M. Azhar, K.C. Susila Wibawa, and A. Natalis, "Energizing Indonesia: enhancing national energy security through ocean wave power plant renewable energy policies," Pakistan J. Criminol., 15 (4) (2023). https://www.pjcriminology.com/publications/energizing-indonesia-enhancing-national-energy-security-through-ocean-wave-power-plant-renewable-energy-policies/
237) A. Nurfadhilah, "Design Optimization of Hybrid Generation System Using Solar Energy and Ocean Waves With Elephant Herding Optimization Method," in: 2023 Int. Conf. Comput. Sci. Inf. Technol. Eng., IEEE, 2023: pp. 546-550 doi:10.1109/ICCoSITE57641.2023.10127677
238) O. Candra, A. Putra, D.G. Priyambodo, R. Revina, and Elfizon, "Variability between wind and sea waves based on environmentally friendly as renewable energy in Pariaman city," J. Sustain. Sci. Manag., 19 (10) 39-47 (2024) doi:10.46754/jssm.2024.10.004
239) M. Satriawan, L. Liliasari, W. Setiawan, and A.G. Abdullah, "Low-cost ocean wave energy converter kit as a teaching tool of a new alternative energy source," Phys. Educ., 55 (5) 55019 (2020) doi:10.1088/1361-6552/ab9b35
240) A.I. Firmansyah, N.K. Supriatna, and B. Pranoto, "Design of ocean current blade turbine 100 kw using hydrodynamics simulation approach," J. Adv. Res. Fluid Mech. Therm. Sci., 101 174-185 (2023) doi:10.37934/arfmts.101.1.174185
241) S. Junianto, S.R. Kaswarie, W. Wardhana, W.N. Fadilah, N.R. Arini, and J. Prastilastiarso, "The effect of co-rotating twin turbines on mooring line tension in quad-spar tidal current power plant," in: 2024 Int. Electron. Symp., IEEE, 2024: pp. 77-82 doi:10.1109/IES63037.2024.10665844
242) R.W. Prastianto, S. Junianto, N.R. Arini, J. Pratilastiarso, and W.N. Fadilah, "Preliminary investigation of the mooring line tension of the quad-spar tidal current power plant prior to operation," in: 2022 IEEE Ocean Eng. Technol. Innov. Conf. Manag. Conserv. Sustain. Resilient Mar. Coast. Resour., IEEE, 2022: pp. 70-73 doi:10.1109/OETIC57156.2022.10176222
243) M. Madi, M. Mukhtasor, D. Satrio, T. Tuswan, A. Ismail, R. Rafi, P. Yunesti, S. Wira Buana, and J. Jarwinda, "Experimental study on the effect of foil guide vane on the performance of a straight-blade vertical axis ocean current turbine," NAŠE MORE Znan. Časopis Za More i Pomor., 71 (1) 1-11 (2024) doi:10.17818/NM/2024/1.1
244) H. Mutsuda, S. Rahmawati, N. Taniguchi, T. Nakashima, and Y. Doi, "Harvesting ocean energy with a small-scale tidal-current turbine and fish aggregating device in the Indonesian archipelagos," Sustain. Energy Technol. Assessments, 35 160-171 (2019) doi:10.1016/j.seta.2019.07.001
245) D. Satrio, and I.K.A.P. Utama, "Experimental investigation into the improvement of self-starting capability of vertical-axis tidal current turbine," Energy Reports, 7 4587-4594 (2021) doi:10.1016/j.egyr.2021.07.027
246) E.E. Ambarita, R. Azhari, and R. Irwansyah, "Experimental study on the optimum design of diffuser-augmented horizontal-axis tidal turbine," Clean Energy, 6 (5) 776-786 (2022) doi:10.1093/ce/zkac039
247) E.E. Ambarita, I.R. Harinaldi, and Nasruddin, "Computational study on multi-objective optimization of the diffuser augmented horizontal axis tidal turbine," J. Mar. Sci. Technol., 26 1237-1250 (2021) doi:10.1007/s00773-021-00812-2
248) M. Ari, Y.S. Hadiwidodo, and M. Mukhtasor, "Evaluating mechanical strength in vertical-axis tidal turbines: a comparative study of internal blade structure and material selection through CFD simulation," in: E3S Web Conf., EDP Sciences, 2024: p. 3004 doi:10.1051/e3sconf/202447303004
249) D. Satrio, I.K.A.P. Utama, and Mukhtasor, "Numerical investigation of contra rotating vertical-axis tidal-current turbine," J. Mar. Sci. Appl., 17 (2) 208-215 (2018) doi:10.1007/s11804-018-0017-5
250) E. Erwandi, A. Kasharjanto, D. Satrio, D. Rahuna, E.M. Suyanto, C.S.J. Mintarso, Z. Irawanto, and M.A. Ramadhani, "Numerical analysis of resistance and motions on trimaran floating platform for tidal current power plant," Int. Rev. Model. Simulations (IREMOS); Vol 17, No 1, (2024) doi:10.15866/iremos.v17i1.24366
251) D. Satrio, F.Y. Muhammad, Mukhtasor, S. Rahmawati, S. Junianto, and S. Musabikha, "Numerical simulation of cross-flow savonius turbine for locations with low current velocity in Indonesia," J. Brazilian Soc. Mech. Sci. Eng., 44 (8) 315 (2022) doi:10.1007/s40430-022-03620-w
252) M. Madi, Mukhtasor, S. Rahmawati, D. Satrio, T. Tuswan, and A. Ismail, "Experimental study on the effect of single flow disturber on the performance of the straight-bladed hydrokinetic turbine at low current speed," Pomorstvo, 38 (1) 43-54 (2024) doi:10.31217/p.38.1.4
253) A.M. Rizal, and N.S. Ningsih, "Description and variation of ocean wave energy in indonesian seas and adjacent waters," Ocean Eng., 251 111086 (2022) doi:10.1016/j.oceaneng.2022.111086
254) A.I. Putri, B. Leksono, E. Windyarini, and T.M. Hasnah, "Tissue culture sterilization of callophylum inophyllum: renewable energy resources," AIP Conf. Proc., 2120 (July) (2019) doi:10.1063/1.5115608
255) T. Martini, M. Anda, N.A. Sasongko, A. Octavian, and T. Mumpuni, "Circular economy for sustainable management of plastic waste to produce liquid fuel and the environmental impact of the whole life cycle (case study in Banjarnegara, Central Java, Indonesia)," SSRN, 19 (2023) doi:10.2139/ssrn.4631180
256) E.R. Dyartanti, T. Paramitha, A. Jumari, A. Purwanto, A. Nur, A.W. Budiman, S.S. Nisa, and R. Dinastuti, "Tuning of nickel content in high-layered lini_xmn_yco_zo_2 (nmc) from spent catalyst," Evergreen, 11 (3) 7 (2024) doi:10.5109/7236869
257) M. Diantoro, R. Suryana, A.S.N. Hidayah, N.C. Nurmayanti, and W. Meevasana, "Addition of al_2o_3 to the al_2o_3/ac//si electrode to enhance the performance of supercapattery," Evergreen, 11 (3) 9 (2024) doi:10.5109/7236853
258) H. Wahyudi, U. Ciptawaty, and A. Ratih, "Planning and policy direction for utilization of renewable energy in sustainable development in Indonesia," WSEAS Trans. Bus. Econ., 21 (May) 1083-1094 (2024) doi:10.37394/23207.2024.21.90
259) A. Respitawulan, and A.Y.S. Rahayu, "The role of renewable energy to reduce climate change: perspective of policy content and context," IOP Conf. Ser. Earth Environ. Sci., 328 (1) 12005 (2019) doi:10.1088/1755-1315/328/1/012005
260) L. Nurhidayah, S. Alam, N.A. Utomo, and A. Suntoro, "Indonesia’s just energy transition: the societal implications of policy and legislation on renewable energy," Clim. Law, 14 (1) 36-66 (2024) doi:10.1163/18786561-bja10047
261) A. Hanun, Sarjiya, L.M. Putranto, Tumiran, I. Savitri, and D. Farel, "Impact of coal supply constraint and renewable energy mixed target on a power system planning a case study of Southern Sulawesi System," in: 2023 15th Int. Conf. Inf. Technol. Electr. Eng., 2023: pp. 87-92 doi:10.1109/ICITEE59582.2023.10317640
262) Tumiran, L.M. Putranto, R. Irnawan, Sarjiya, A. Priyanto, S. Isnandar, and I. Savitri, "Transmission expansion planning for the optimization of renewable energy integration in the Sulawesi electricity system," Sustainability, 13 (18) 10477 (2021) doi:10.3390/su131810477
263) Sarjiya, L.M. Putranto, R.F.S. Budi, D. Novitasari, Deendarlianto, and Tumiran, "Role of the energy-carbon-economy nexus and CO2 abatement cost in supporting energy policy analysis: a multi-scenario analysis of the Java-Bali system," Renew. Sustain. Energy Rev., 187 113708 (2023) doi:10.1016/j.rser.2023.113708
264) Tumiran, L.M. Putranto, Sarjiya, and E.Y. Pramono, "Maximum penetration determination of variable renewable energy generation: a case in Java–Bali power systems," Renew. Energy, 163 561-570 (2021) doi:10.1016/j.renene.2020.08.048
265) Y.S. Wijoyo, S.P. Hadi, and Sarjiya, "Applied power wheeling concept considering site-specific and variability of VRE under contingency events," Sustainability, 15 (18) (2023) doi:10.3390/su151813285
266) D. Novitasari, Sarjiya, S.P. Hadi, and R. Budiarto, "Generation expansion planning by considering climate-land use-energy-water (CLEW) nexus," in: 2021 Int. Conf. Technol. Policy Energy Electr. Power, IEEE, 2021: pp. 424-429 doi:10.1109/ICT-PEP53949.2021.9600910
267) M. Sultana, and M.A. Esquivias, "Interactions among the primary causes of carbon dioxide emissions in selected south Asian countries: does renewable energy mitigate carbon dioxide emissions?," Humanit. Soc. Sci. Lett., 12 (4) 913-927 (2024). doi:DOI:
268) M.H. Rahman, L.C. Voumik, M.J. Islam, M.A. Halim, and M.A. Esquivias, "Economic growth, energy mix, and tourism-induced EKC hypothesis: evidence from top ten tourist destinations," Sustainability, 14 (24) (2022) doi:10.3390/su142416328
269) A.N. Afandi, I. Fadlika, and L. Gumilar, "Partial model development of power grid structures considering sectionalizing scenarios for the controlling electric system expansion," Int. J. Innov. Comput. Inf. Control, 15 (1) 129-142 (2019) doi:10.24507/ijicic.15.01.129
270) K.E. Peters, T.H. Fraser, W. Amris, B. Rustanto, and E. Hermanto, "Geochemistry of crude oils from eastern Indonesia," Am. Assoc. Pet. Geol. Bull., 83 (12) 1927-1942 (1999) doi:10.1306/E4FD4643-1732-11D7-8645000102C1865D
271) M. Khalil, B.M. Jan, C.W. Tong, and M.A. Berawi, "Advanced nanomaterials in oil and gas industry: design, application and challenges," Appl. Energy, 191 287-310 (2017) doi:10.1016/j.apenergy.2017.01.074
272) N. Wibowo, L. Setyadhi, D. Wibowo, J. Setiawan, and S. Ismadji, "Adsorption of benzene and toluene from aqueous solutions onto activated carbon and its acid and heat treated forms: influence of surface chemistry on adsorption," J. Hazard. Mater., 146 (1) 237-242 (2007) doi:10.1016/j.jhazmat.2006.12.011
273) J.H. Purba, J. Lu, G. Zhang, and W. Pedrycz, "A fuzzy reliability assessment of basic events of fault trees through qualitative data processing," Fuzzy Sets Syst., 243 50-69 (2014) doi:10.1016/j.fss.2013.06.009
274) V. Gonzalez-Pedro, E.J. Juarez-Perez, W.-S. Arsyad, E.M. Barea, F. Fabregat-Santiago, I. Mora-Sero, and J. Bisquert, "General working principles of ch3nh3pbx3 perovskite solar cells," Nano Lett., 14 (2) 888-893 (2014) doi:10.1021/nl404252e
275) N.R. Herdianita, P.R.L. Browne, K.A. Rodgers, and K.A. Campbell, "Mineralogical and textural changes accompanying ageing of silica sinter," Miner. Depos., 35 48-62 (2000) doi:10.1007/s001260050005
276) M.H. Hasan, T.M.I. Mahlia, and H. Nur, "A review on energy scenario and sustainable energy in Indonesia," Renew. Sustain. Energy Rev., 16 (4) 2316-2328 (2012) doi:10.1016/j.rser.2011.12.007
277) A.S. Nizami, M. Rehan, M. Waqas, M. Naqvi, O.K.M. Ouda, K. Shahzad, R. Miandad, M.Z. Khan, M. Syamsiro, I.M.I. Ismail, and D. Pant, "Waste biorefineries: enabling circular economies in developing countries," Bioresour. Technol., 241 1101-1117 (2017) doi:10.1016/j.biortech.2017.05.097
278) W. Tjiu, T. Marnoto, S. Mat, M.H. Ruslan, and K. Sopian, "Darrieus vertical axis wind turbine for power generation i: assessment of Darrieus VAWT configurations," Renew. Energy, 75 50-67 (2015) doi:10.1016/j.renene.2014.09.038
279) J. Sprintall, S. Wijffels, R. Molcard, and I. Jaya, "Direct evidence of the south java current system in Ombai strait," Dyn. Atmos. Ocean., 50 (2) 140-156 (2010) doi:10.1016/j.dynatmoce.2010.02.006
280) Erdiwansyah, Mahidin, H. Husin, Nasaruddin, M. Zaki, and Muhibbuddin, "A critical review of the integration of renewable energy sources with various technologies," Prot. Control Mod. Power Syst., 6 (1) 3 (2021) doi:10.1186/s41601-021-00181-3
281) M. Silaen, R. Taylor, S. Bößner, A. Anger-Kraavi, U. Chewpreecha, A. Badinotti, and T. Takama, "Lessons from Bali for small-scale biogas development in Indonesia," Environ. Innov. Soc. Transitions, 35 (September) 445-459 (2020) doi:10.1016/j.eist.2019.09.003
282) M. Diantoro, N.I. Muthi Aturroifah, J. Utomo, I. Luthfiyah, I. Hamidah, B. Yuliarto, A. Rusydi, W. Meevesana, S. Maensiri, and P.K. Singh, "Optimizing sponge-like activated carbon from manihot esculenta tubers for high-performance supercapacitors," Arab. J. Chem., 18 106068 (2024) doi:10.1016/j.arabjc.2024.106068
283) A. Syafiq, J.A. Awalin, M.S. Ali, M.A. Mohd Sarjidan, N.A. Rahim, and A.K. Panday, "Development of hydrophilic self-cleaning and ultraviolet-shielding coatings incorporating micro-titanium dioxide/nano-calcium carbonate (µ-tio2)/(nano-caco3)," J. Nano Res., 83 79-89 (2024) doi:10.4028/p-4HWb6k
284) I. Hamidah, R. Ramdhani, A. Wiyono, B. Mulyanti, R.E. Pawinanto, L. Hasanah, M. Diantoro, B. Yuliarto, J. Yunas, and A. Rusydi, "Biomass-based supercapacitors electrodes for electrical energy storage systems activated using chemical activation method: a literature review and bibliometric analysis," Indones. J. Sci. Technol., 8 (3) 439-468 (2023) doi:10.17509/ijost.v8i3.60688
285) B. Resosudarmo, J. Rezki, and Y. Effendi, "Prospects of energy transition in Indonesia," Bull. Indones. Econ. Stud., 59 (2) 149-177 (2023). https://econpapers.repec.org/RePEc:taf:bindes:v:59:y:2023:i:2:p:149-177
286) T. Sainati, G. Locatelli, and N. Smith, "Project financing in nuclear new build, why not? the legal and regulatory barriers," Energy Policy, 129 (June 2020) 111-119 (2019) doi:10.1016/j.enpol.2019.01.068
287) N.I. Kurniawan, M. Hasanah, and W.A. Pamungkas, "The challenges of nuclear power plant development in Indonesia: a case of thorium power plant in Bangka Island, Indonesia," IOP Conf. Ser. Earth Environ. Sci., 1199 (1) (2023) doi:10.1088/1755-1315/1199/1/012014
288) A. Kasharjanto, Erwandi, C.S. Jati Mintarso, E.M. Suyanto, and D. Rahuna, "Study of supply chain management of industrial plan manufacturing development of marine power turbine in Indonesia," IOP Conf. Ser. Earth Environ. Sci., 1166 (1) 12018 (2023) doi:10.1088/1755-1315/1166/1/012018
289) A. Ribal, A. V. Babanin, S. Zieger, and Q. Liu, "A high-resolution wave energy resource assessment of Indonesia," Renew. Energy, 160 1349-1363 (2020) doi:10.1016/j.renene.2020.06.017
290) S.W. Yudha, B. Tjahjono, and P. Longhurst, "Unearthing the dynamics of Indonesia’s geothermal energy development," Energies, 15 (14) (2022) doi:10.3390/en15145009
291) S. Mohammadzadeh Bina, S. Jalilinasrabady, H. Fujii, and N.A. Pambudi, "Classification of geothermal resources in Indonesia by applying exergy concept," Renew. Sustain. Energy Rev., 93 (C) 499-506 (2018). doi: doi:10.1016/j.rser.2018.05.018
292) Y. Pan, M.H. Hui, W. Narr, G. King, T.H. Tankersley, S.D. Jenkins, E.A. Flodin, P.W. Bateman, C. Laidlaw, and H.X. Vo, "Integration of pressure-transient data in modeling Tengiz field, Kazakhstan-a new way to characterize fractured reservoirs," SPE Reserv. Eval. Eng., 19 (1) 5-17 (2016) doi:10.2118/165322-pa
293) A. Adiarso, E. Hermawan, A. Nelly, D.E.P. Wicaksana, R.A. Wijono, A.L. Ferabianie, H. Setiawan, S. Setiadi, E.D. Setiyadi, Lenggogeni, Sunartono, A. Marsudi, Y.R. Dewi, Saparudin, I.D. Handayani, and K. Kaseno, "Optimized utilization of spent bleaching earth to enhance economic performance of integrated biodiesel-cooking oil plants," Case Stud. Chem. Environ. Eng., 10 100784 (2024) doi:10.1016/j.cscee.2024.100784

Other Papers in This Issue

Cooling Techniques for Photovoltaic Systems: A Comprehensive Review of Phase Change Materials
S. Yadav, S. Singh, A. Chaudhary (2026)
Entropy-Heat Transfer Coupling in Vibrational Non-Newtonian Nanofluid Flow with two phase study
A. Tripure et al. (2026)
A Novel Machine Learning and Deep Learning Insight for Alzheimer's Diseases Using Neuroimaging Dataset Analysis
Mamta, S. Bansal (2026)
Enhancing Wear Resistance of EN-19 Steel with Physical Vapor Deposition (PVD) Coatings: Experimental and Statistical Analysis
A. Kaur, J. Dureja, J. Grewal (2026)
Dynamic Modeling and Simulation of Vehicle Structural Components Under Full Front Impact for Automotive Crashworthiness
S. Pratiwi et al. (2026)
Methods for Leakage Monitoring for Safety and Efficiency of ORC System: A Review
I. Supono et al. (2026)
Design Strategies for Off-Street Parking in High-Density Industrial Areas: A Case Study of Industrial Estates in Indonesia
T. Mardiana et al. (2026)
Optimization and Mechanical Performance of Resin–Talc Sandwich Core Composites for Ship Construction
P. Arianto et al. (2026)
Ozone Technology for Improving the Microbiological Quality of Milk from Medicated Dairy Cows
P. Anggraeni et al. (2026)
Predicting Occupational Accident Risk from Textual Data: A Systematic Review of Machine Learning Application
A. Rosyidiin, M. Singgih, A. Sudiarno (2026)