Water is a natural resource that is very important for life in the world, especially for humans and other living things. There are few areas in Indonesia that have unsuitable water due to water pollution and limited fresh water source. Distillation is an effective way to produce clean water that is free from impurities in the form of small solids, germs and bacteria. One type of distillation systems is a solar distillation. However, the use of these still has low productivity. There are several ways to increase the productivity of solar distillation systems, one of them is by adding thermal energy storage material such as aluminum oxide (Al2O3) nanoparticles. This study based on  experimental method by comparing a solar distillation systems with the addition of Al2O3 nanoparticles on the absorber plate coating to the coating without the addition of Al2O3. The test results showed that the addition of Al2O3 nanoparticles increased the productivity of solar distillation. The results show the addition of mass concentration of Al2O3 (nano particles): 10%; 15% and 20% ,  increased distillate  production by: 44.73%; 88.98% and 134.85% compared without the addition of nanoparticles to the absorber plate coating.

Aprizki, E., Rokhmat, M., & Wibowo, E. (2018). Analisis Pengaruh Kemiringan Sudut Atap Kaca Dan Penambahan Cermin Pada Alas Basin Terhadap Laju Penguapan Air Garam Dalam Distilator Tenaga Surya. eProceedings of Engineering, 5(3).

Astawa, K., Sucipta, M., & Negara, I. P. G. A. (2011). Analisa Performansi Destilasi Air Laut Tenaga Surya Menggunakan Penyerap Radiasi Surya Tipe Bergelombang Berbahan Dasar Beton. J. Ilm. Tek. Mesin Cakra M, 5(1), 7-13.

Benoudina, B., Attia, M. E. H., Driss, Z., Afzal, A., Manokar, A. M., & Sathyamurthy, R. (2021). Enhancing the solar still output using micro/nanoparticles of aluminum oxide at different concentrations: an experimental study, energy, exergy and economic analysis. Sustainable Materials and Technologies, 29, e00291.

Caturwati Ni Ketut, Yusvardi Yusuf, Zaenal Arifin, (2020). Productivity of Solar Distillation in Indonesia using Sodium Thiosulfate Penta-hydrate as Thermal Energy Storage. Technium, 2(5), 1-10

Dewantara, I. G. Y., Suyitno, B. M., & Lesmana, I. G. E. (2018). Desalinasi air laut berbasis energi surya sebagai alternatif penyediaan air bersih. Jurnal Teknik Mesin (JTM), 7(1), 1-4.

Kabeel, A. E., Sathyamurthy, R., Sharshir, S. W., Muthumanokar, A., Panchal, H., Prakash, N., ... & El Kady, M. S. (2019). Effect of water depth on a novel absorber plate of pyramid solar still coated with TiO2 nano black paint. Journal of cleaner production, 213, 185-191.

Kii, O. A. (2015). Rancang Bangun Sistem Distilasi Air Laut Tenaga Surya Tipe Double Slope Dengan Penambahan Pelat Absorber Bentuk Gelombang Segitiga Dan Reflektor Internal (Doctoral dissertation, Institut Teknologi Sepuluh Nopember).

Ni ketut Caturwati, Yusvardi Yusuf, Imron Rosyadi, A.Fikri Almarwan, (2020). Comparison of The Effectivenes of 45˚ and 60˚ Cover Angle on The Production of Clean Water on Double Slope Solar Distilations (Perbandingan Efektivitas Sudut Penutup 450 dan 600 pada Double Slope Solar Destilasi Sebagai Penyedia Air Bersih). Journal of Renewable Energy & Mechanics (REM), 3(2), 59-70

Panchal, H., Nurdiyanto, H., Sadasivuni, K. K., Hishan, S. S., Essa, F. A., Khalid, M., ... & Shanmugan, S. (2021). Experimental investigation on the yield of solar still using manganese oxide nanoparticles coated absorber. Case Studies in Thermal Engineering, 25, 100905.

Pratama, A. W., Nurdiana, J., & Meicahayanti, I. (2017). Pengaruh perbedaan jenis plat penyerap kaca dan papan mika terhadap kualitas dan kuantitas air minum pada proses destilasi energi tenaga surya. In Prosiding Seminar Nasional Teknologi, Inovasi dan Aplikasi di Lingkungan Tropis (Vol. 1, No. 1, pp. 3540).

Pratama, F. X. R. K. (2015) Destilator Air Energi Termal Surya Jenis Konvensional Menggunakan Pendingin Air Dengan Kaca Ganda. Skripsi. Sarjana Universitas Sanata Dharma Yogyakarta.

Putra, R. A., Pauzi, G. A., & Surtono, A. (2018). Rancang Bangun Alat Destilasi Air Laut dengan Metode Ketinggian Permukaan Air Selalu Sama Menggunakan Energi Matahari. Jurnal Teori dan Aplikasi Fisika, 6(1), 101108.

Saputra, E. T., Caturwati, N. K., & Rosyadi, I. (2021). Pengaruh Massa PCM (Phase Change Material) Terhadap Produktivitas dan Efisiensi Alat Destilasi Tenaga Surya Menggunakan PCM Jenis Lauric Acid Sebagai Penyimpan Panas. Eksergi: Jurnal Teknik Energi, 17(3), 201-212.

Shalaby, S. M., El-Bialy, E., & El-Sebaii, A. A. (2016). An experimental investigation of a v-corrugated absorber single-basin solar still using PCM. Desalination, 398, 247-255.

Shoeibi, S., Kargarsharifabad, H., & Rahbar, N. (2021). Effects of nano-enhanced phase change material and nano-coated on the performance of solar stills. Journal of Energy Storage, 42, 103061.

Siregar, M. A., Damanik, W. S., & Lubis, S. (2021). Analisa Energi pada Alat Desalinasi Air Laut Tenaga Surya Model Lereng Tunggal. Rekayasa Mesin, 12(1), 193-201.

UDARA, B., & MARKUS, D. D. S. (2015). Membandingkan Unjuk Kerja Alat Destilasi Air Energi Surya Jenis Absorber Kain Menggunakan Kaca Tunggal Berpendingin Air Dengan Berpendingin Udara. Skripsi. Sarjana Universitas Sanata Dharma Yogyakarta.

Yudiyanto, E. (2018). DISTILASI AIR LAUT TENAGA SURYA DENGAN KONSENTRATOR LENSA FRESNEL. TURBULEN Jurnal Teknik Mesin, 1(2).