This study examines the use of water-based mud (WBM) in well drilling. It specifically focuses on enhancing the rheology of WBM that meets API 13A specifications by incorporating calcium carbonate (CaCO₃) at concentrations of 2.5% and 7.5%. The primary objective is to compare the original rheology of the WBM adhering to API 13A standards with the modifications following the addition of CaCO₃. The methodology employed includes laboratory tests to gather data, testing mixtures of the original mud with added CaCO₃, and evaluating the impact on mud properties such as viscosity and density. The results are expected to determine the optimal additive concentration to improve mud performance in drilling operations.

Agusman, A. R., 2022. Studi Pengaruh Kontaminasi Properti Rheology Water Based Mud di Lapangan Sunyu. Jurnal Bhara Petro Energi, 1(3), pp. 71-81.

Akeju, O. A., Akintola, S. A. & Akpabio, J. U., 2014. The Use of Crassostrea Virginica as Lost Circulation Material in Water-Based Drilling Mud. International Journal of Engineering and Technology, 4(2), pp. 109-117.

Alakbari, F., Elkatatny, S., Kamal, M. S. & Mahmoud, M., 2018. Optimizing the Gel Strength of Water-Based Drilling Fluid Using Clays for Drilling Horizontal and Multi-Lateral Wells. Dammna, Saudi Arabia, SPE Kingdom of Saudi Arabia Annual Technical Symposium and Exhibition.

Al-Jaff, L. S. & Shamikh, M. G., 2024. The Additives Impact the Gel Strength of the Water Based Drilling Mud. Journal of Al-Farabi for Engineering Sciences, 2(2), pp. 22-26.

Anon., 2019. Desain Lumpur Pemboran Menggunakan Additive Barite dan CMC Industri untuk Mengatasi Formasi Salinitas Tinggi, Pekanbaru: Universitas Islam Riau.

Buntoro, A., 2016. Lumpur Pemboran Perencanaan dan Solusi Masalah Secara Praktis, Balikpapan: Sekolah Tinggi Teknologi Migas. Skripsi.

Diningsih, C. & Rohmawati, L., 2022. Sysntesis of Calcium Carbonate (CaCO3) from Eggshell by Calcination Method. Indonesian Physical Review, 5(3), pp. 208-215.

Ezeakacha, C. P. & Salehi, S., 2019. A Holistic Approach to Characterize Mud Loss Using Dynamic Mud Filtration Data. J. Energy Resour. Technol., 141(7), p. 072903.

Jafarifar, I. & Najjarpour, M., 2022. Modeling Apparent Viscosity, Plastic Viscosity, and Yield Point in Water-Based Drilling Fluids: Comparison of Various Soft Computing Approaches, Developed Correlations and a Committee Machine Intelligent System. Arabian Journal for Science and Engineering, Volume 47, pp. 11553-11577.

Mahmoodzadeh, F. & Chidiac, S. E., 2013. Rheological Models for Predicting Plastic Viscosity and Yield Stress of Fresh Concrete. Cement and Concrete Research, Volume 49, pp. 1-9.

Pearlo, K. L., Satiyawira, B. & Husla, R., 2023. STUDI LABORATORIUM PENGARUH SISTEM BENTONITE PREHIDRASI TERHADAP MUD WEIGHT, VISKOSITAS, DAN PLASTIC VISCOSITY PADA TEMPERATUR 80° F, 250° F, DAN 300° F. PETRO: Jurnal Ilmiah Teknik Perminyakan, 2(1), pp. 12-26.

Rizaldi, L. O. M., 2019. Pengaruh Tekanan Terhadap Jumlah Cake pada Proses Filtrasi CaCO3 Menggunakan Alat Filtration Plate and Frame, Semarang: Departemen Teknologi Industri Sekolah Vokasi Universitas Diponegoro. Skripsi.

Sajjadian, M., Motlagh, E. E. & Daya, A. A., 2016. Laboratory Investigation to Use Lost Circulation Material in Water Base Drilling Fluid as Lost Circulation Pills. Ineternational Journal of Mining Science (IJMS), 2(1), pp. 33-38.

Veronika, A. O. & Rohmawati, L., 2022. Sintesis CaCO3 dari Dolomit Bangkalan dengan Metode Leaching. Sains dan Matematika, 7(1), pp. 39-42.

Zakky, Z., Satyawira, B. & Samsol, S., 2015. Studi Laboratorium Pemilihan Additif Penstabil Shale di Dalam Sistem Lumpur Kcl-polimer Pada Temperatur Tinggi. Jakarta, Universitas Trisakti. Skripsi.