Mesoporous silica (MS) supported by nickel was synthesized from Parangtritis beach sand and assessed for its activity and selectivity as catalysts in hydrocracking waste cooking oil into biofuel. The synthesis of MS was done by the sol-gel method. Ni/MS catalysts using Ni weight variations of 1, 5, and 10 wt.% were denoted as Ni/MS1, Ni/MS5, and Ni/MS10 and were compared to standard mesoporous silica (Ni/SBA-15). The catalysts were characterized using FTIR, XRD analysis, N₂ gas sorption analysis, SEM-EDX, and TEM. Catalyst Ni/MS1, Ni/MS5, Ni/MS10, and Ni/SBA-15 have specific surface areas of 130.5, 195.9, 203.9, and 381.2 m²/g and the average pores of 12.30, 9.80, 11.12, and 8.70 nm, respectively. The hydrocracking was run four times to evaluate the catalyst reusability. The hydrocracking WCO has 95.8, 82.4, and 85.2%, respectively. While Liquid fractions produced were 38.8, 43.2, and 50.2 wt.%, each of which contains gasoline of 37.09, 39.76, and 44.27 wt.%, Ni/MS10 has the highest liquid products of 50.2 wt.% and was selective to gasoline fractions up to 44.27%. Therefore, the catalyst synthesized from Parangtritis beach sand is selective for gasoline-fraction hydrocarbon and has hydrocracking activity up to 4 runnings.

[1] Trisunaryanti, W., Larasati, S., Triyono, T., Santoso, N.R., and Paramesti, C., 2020, Selective production of green hydrocarbons from the hydrotreatment of waste cooking oil over Ni- and NiMo- supported on amine-functionalized mesoporous silica, Bull. Chem. React. Eng. Catal., 15 (2), 415–431.

[2] Nanda, S., Rana, R., Hunter, H.N., Fang, Z., Dalai, A.K., and Kozinski, J.A., 2020, Hydrothermal catalytic processing of waste cooking oil for hydrogen-rich syngas production, Chem. Eng. Sci., 195, 935–945.

[3] Yıldız, A., Goldfarb, J.L., and Ceylan, S., 2019, Sustainable hydrocarbon fuels via “one-pot” catalytic deoxygenation of waste cooking oil using inexpensive, unsupported metal oxide catalysts, Fuel, 263, 116750.

[4] Nuntang, S., Yousatit, S., Yokoi, T., and Ngamcharussrivichai, C., 2019, Tunable mesoporosity and hydrophobicity of natural rubber/hexagonal mesoporous silica nanocomposites, Microporous Mesoporous Mater., 275, 235–243.

[5] Irzon, R., 2018, Komposisi kimia pasir pantai di selatan Kulon Progo dan implikasi terhadap provenance, JGSM, 19 (1), 31–46.

[6] Salamah, S., Trisunaryanti, W., Kartini I., and Purwono, S., 2021, Synthesis and characterization of mesoporous silica from beach sand as silica source, IOP Conf. Ser.: Mater. Sci. Eng., 1053, 012027.

[7] Thahir, R., Wahab, A.W., Nafie, N.L., and Raya, I., 2019, Synthesis of mesoporous silica SBA-15 through surfactant set-up and hydrothermal process, Rayasan J. Chem., 12 (3), 1117–1126.

[8] Salamah, S., Trisunaryanti, W., Kartini, I., and Purwono, S., 2021, Hydrocracking of waste cooking oil into biofuel using mesoporous silica from Parangtritis Beach sand synthesis by sonochemistry, Silicon, 14, 3583–3590.

[9] Miyao, T., Sakurabayashi, S., Shen, W., Higashiyama, K., and Watanabe, M., 2015, Preparation and catalytic activity of mesoporous Silica-coated Ni-Alumina base catalyst for selective CO methanation, Catal. Commun., 58, 93–96.

[10] Wijaya, K., Kurniawan, A.H., Saputri D., Trisunaryanti, W., Mirzan, M., Harjani, P.L., and Tjkoalu A.D., 2021, Synthesis of nickel catalyst supported on ZrO₂/SO₄ pillared bentonite and its application for conversion of coconut oil into gasoline via hydrocracking process, J. Environ. Chem. Eng., 9 (4), 105399.

[11] Levenspiel, O., 1999, “Chemical Reaction Engineering,” in Chemical Reaction Engineering, 3^rd Ed., John Wiley & Sons, New York, US, 90–119.

[12] Trisunaryanti, W., Sumbogo, S.D., Mukti, R.R., Kartika, I.A., Hartati, and Triyono, 2021, Performance of low‑content Pd and high‑content Co, Ni supported on hierarchical activated carbon for the hydrotreatment of Calophyllum inophyllum oil (CIO), React. Kinet., Mech. Catal., 134 (1), 259–272.

[13] Wijaya, K., Saputri, W.D., Aziz, I.T.A., Wangsa, Heraldy, E., Hakim, L., Suseno, A., and Utami, M., 2021, Mesoporous silica preparation using sodium bicarbonate as template and application of the silica for hydrocracking of used waste cooking oil into biofuel, Silicon, 14 (4), 1583–1591.

[14] Qiu, S., Zhang, Q., Lv, W., Wang, T., Zhang, Q., and Ma, L., 2017, Simply packaging Ni nanoparticles inside SBA-15 channels by co-impregnation for dry reforming of methane, RSC Adv., 7, 24551–24560.

[15] Komaruzzaman, M.F., Taufik-Yap, Y.H., and Derawi D., 2020, Green diesel production from palm fatty acid distillate over SBA-15 supported nickel/cobalt catalyst, Biomass Bioenergy, 134, 105476.

[16] Sudhasree, S., Banu, A.S., Brinda, P., and Kurian, G.A, 2014, Synthesis of nickel nanoparticles by chemical and green route and their comparison in respect to biological effect and toxicity, Toxicol. Environ. Chem., 96 (5), 743–754.

[17] Lin, H.Y., and Chen, Y.W., 2005, Preparation of spherical hexagonal mesoporous silica, J. Porous Mater., 12 (2), 95–105.

[18] Lin S., Shi, L., Ribeiro Carrott, M.M.L., Carrott, P.J.M., Rocha, J., Li, M.R., and Zou, X.D., 2011, Direct synthesis without addition of acid of Al-SBA-15 with controllable porosity and high hydrothermal stability, Microporous Mesoporous Mater., 142 (2–3), 526–534.

[19] Wang, N., Yu, X., Shen, K., Chu, W., and Qian, W., 2013, Synthesis, characterization and catalytic performance of MgO-coated Ni/SBA-15 catalysts for methane dry reforming to syngas and hydrogen, Int. J. Hydrogen Energy, 38 (23), 9718–9731.

[20] Amin, A.K., Wijaya, K., and Trisunaryanti, W., 2020, Physico-chemical properties of nickel promoted sulfated zirconia powder prepared using different procedures, Asian J. Chem., 32 (3), 555–560.

[21] Pauly, T.R., Liu, Y., Pinnavaia, T.J., Billinge, S.J.L., and Rieker, T.P., 1999, Textural mesoporosity and the catalytic activity of mesoporous molecular sieves with wormhole framework structures, J. Am. Chem. Soc., 121 (38), 8835–8842.

[22] Sotomayor, F.J., Cychosz, K.A., and Thommes, M., 2018, Characterization of micro/mesoporous materials by physisorption: Concepts and case studies, Acc. Mater. Surf. Res., 3 (2), 34–50.

[23] Coasne, B., 2016, Multiscale adsorption and transport in hierarchical porous materials, New J. Chem., 40 (5), 4078–4094.

[24] Kusumastuti, H., Trisunaryanti, W., Falah, I.I., and Marsuki, M.F., 2018, Synthesis of mesoporous silica-alumina from Lapindo mud as support of Ni and Mo metals catalysts for hydrocracking of pyrolyzed α-cellulose, Rasayan J. Chem., 11 (2), 522–530.

[25] Nugraha, A., and Nandiyanto, A.B.D., 2021, How to read and Interpret GC/MS spectra, IJOMR, 1 (2), 171–206.

[26] Li, L., Ding, Z., Li, K., Xu, J., Liu, F., Liu, S., Yu, S., Xie, C., and Ge, X., 2016, Liquid hydrocarbon fuels from catalytic cracking of waste cooking oils using ultrastable zeolite USY as catalyst, J. Anal. Appl. Pyrolysis, 117, 268–272.

[27] Trisunaryanti, W., Larasati, S., Bahri, S., Ni’mah, Y.L., Efiyanti, L., Amri, K., Nuryanto, R., and Sumbogo, S.D., 2020, Performance comparison of Ni-Fe loaded on NH₂-functionalized mesoporous silica and beach sand in the hydrotreatment of waste palm cooking oil, J. Environ. Chem. Eng., 8 (6), 104477.

[28] Rodiansono, and Trisunaryanti, W., 2005, Activity test and regeneration of NiMo/Z catalyst for hydrocracking of waste plastic fraction to gasoline fraction, Indones. J. Chem., 5 (3), 261–268.

[29] Chen, R.X., and Wang, W.C., 2019, The production of renewable aviation fuel from waste cooking oil. Part I: Bio-alkane conversion through hydro-processing of oil, Renewable Energy, 135, 819–835.