Characteristic and Performance of Ni, Pt, and Pd Monometal and Ni-Pd Bimetal onto KOH Activated Carbon for Hydrotreatment of Castor Oil

https://doi.org/10.22146/ijc.84640

Wega Trisunaryanti(1*), Triyono Triyono(2), Iip Izul Falah(3), Dwi Bagus Wicaksono(4), Satriyo Dibyo Sumbogo(5)

(1) Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Gadjah Mada, Sekip Utara, Yogyakarta 55281, Indonesia
(2) Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Gadjah Mada, Sekip Utara, Yogyakarta 55281, Indonesia
(3) Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Gadjah Mada, Sekip Utara, Yogyakarta 55281, Indonesia
(4) Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Gadjah Mada, Sekip Utara, Yogyakarta 55281, Indonesia
(5) Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Gadjah Mada, Sekip Utara, Yogyakarta 55281, Indonesia
(*) Corresponding Author

Abstract


The preparation of highly efficient hydrotreating catalysts has presented a significant challenge in the field of catalysis. In this study, chemically activated carbon (AC) was prepared using potassium hydroxide (KOH) as an activator and Merbau wood as a lignocellulosic source for the AC. The AC was then impregnated with mono-metallic species (nickel, platinum, and palladium) as well as a bimetallic NiPd combination. The results revealed that the optimal KOH impregnation weight ratio was determined to be 2:1, resulting in a remarkably high iodine value of 751.94 mg/g. Subsequently, AC was employed as a support material for the hydrotreating of castor oil. Among the catalysts tested, the NiPd/AC catalyst demonstrated superior performance, yielding a liquid fraction comprising 88.80 wt.%. Within this fraction, C5-C12 hydrocarbons accounted for 15.16 wt.%, alcohol compounds constituted 71.69 wt.%, while the remaining 0.87 wt.% consisted of other components. Furthermore, the NiPd/AC catalyst exhibited remarkable stability, as its performance remained largely unchanged even after being used three times consecutively. This finding suggests that coking had minimal impact on the active sites of the mentioned catalyst, indicating its robustness and potential for prolonged application.

Keywords


biofuels; activated carbon; hydrotreating; castor oil

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References

[1] Pleyer, O., Kubičková, I., Vráblík, A., Maxa, D., Pospíšil, M., Zbuzek, M., Schlehöfer, D., and Straka, P., 2022, Hydrocracking of heavy vacuum gas oil with petroleum wax, Catalysts, 12 (4), 384.

[2] Ward, J.W., Michalek, J.J., Azevedo, I.L., Samaras, C., and Ferreira, P., 2019, Effects of on-demand ridesourcing on vehicle ownership, fuel consumption, vehicle miles traveled, and emissions per capita in US States, Transp. Res. Part C: Emerging Technol., 108, 289–301.

[3] Mathew, G.M., Raina, D., Narisetty, V., Kumar, V., Saran, S., Pugazhendi, A., Sindhu, R., Pandey, A., and Binod, P., 2021, Recent advances in biodiesel production: Challenges and solutions, Sci. Total Environ., 794, 148751.

[4] Jamil, F., Al-Haj, L., Al-Muhtaseb, A.H., Al-Hinai, M.A., Baawain, M., Rashid, U., and Ahmad, M.N.M., 2018, Current scenario of catalysts for biodiesel production: A critical review, Rev. Chem. Eng., 34 (2), 267–297.

[5] Hasanudin, H., Asri, W.R., Said, M., Hidayati, P.T., Purwaningrum, W., Novia, N., and Wijaya, K., 2022, Hydrocracking optimization of palm oil to bio-gasoline and bio-aviation fuels using molybdenum nitride-bentonite catalyst, RSC Adv., 12 (26), 16431–16443.

[6] Wijaya, K., Saputri, W.D., Aziz, I.T.A., Wangsa, W., Heraldy, E., Hakim, L., Suseno, A., and Utami, M., 2022, Mesoporous silica preparation using sodium bicarbonate as template and application of the silica for hydrocracking of used cooking oil into biofuel, Silicon, 14 (4), 1583–1591.

[7] Lin, M., Zhang, X., Zhan, L., Li, X., Song, X., and Wu, Y., 2022, Product distribution-tuned and excessive hydrocracking inhibiting in fatty acid deoxygenation over amorphous Co@SiO2 porous nanorattles, Fuel, 318, 123605.

[8] Salamah, S., Trisunaryanti, W., Kartini, I., and Purwono, S., 2022, Synthesis of mesoporous silica from beach sand by sol-gel method as a Ni supported catalyst for hydrocracking of waste cooking oil, Indones. J. Chem., 22 (3), 726–741.

[9] Roy, P., Jahromi, H., Rahman, T., Adhikari, S., Feyzbar-Khalkhali-Nejad, F., Hassan, E.B., and Oh, T.S., 2022, Understanding the effects of feedstock blending and catalyst support on hydrotreatment of algae HTL biocrude with non-edible vegetable oil, Energy Convers. Manage., 268, 115998.

[10] Alisha, G.D., Trisunaryanti, W., and Syoufian, A., 2022, Mesoporous silica from Parangtritis beach sand templated by CTAB as a support of Mo Metal as a catalyst for hydrocracking of waste palm cooking oil into biofuel, Waste Biomass Valorization, 13 (2), 1311–1321.

[11] Janampelli, S., and Darbha, S., 2019, Hydrodeoxygenation of vegetable oils and fatty acids over different group VIII metal catalysts for producing biofuels, Catal. Surv. Asia, 23 (2), 90–101.

[12] Di Vito Nolfi, G., Gallucci, K., and Rossi, L., 2021, Green diesel production by catalytic hydrodeoxygenation of vegetables oils, Int. J. Environ. Res. Public Health, 18 (24), 13041.

[13] Liu, S., Simonetti, T., Zheng, W., and Saha, B., 2018, Selective hydrodeoxygenation of vegetable oils and waste cooking oils to green diesel using a silica‐supported Ir–ReOx bimetallic catalyst, ChemSusChem, 11 (9), 1446–1454.

[14] Yeboah, A., Ying, S., Lu, J., Xie, Y., Amoanimaa-Dede, H., Boateng, K.G.A., Chen, M., and Yin, X., 2021, Castor oil (Ricinus communis): A review on the chemical composition and physicochemical properties, Food Sci. Technol., 41, 399–413.

[15] Liu, S., Zhu, Q., Guan, Q., He, L., and Li, W., 2015, Bio-aviation fuel production from hydroprocessing castor oil promoted by the nickel-based bifunctional catalysts, Bioresour. Technol., 183, 93–100.

[16] Trisunaryanti, W., Triyono, T., Purwono, S., Purwanti, A.S., and Sumbogo, S.D., 2022, Synthesis of mesoporous carbon from merbau sawdust as a nickel metal catalyst support for castor oil hydrocracking, Bull. Chem. React. Eng. Catal., 17 (1), 216–224.

[17] Alvarez-Galvan, M.C., Campos-Martin, J.M., and Fierro, J.L., 2019, Transition metal phosphides for the catalytic hydrodeoxygenation of waste oils into green diesel, Catalysts, 9 (3), 293.

[18] Zharova, P.A., Chistyakov, A.V., Shapovalov, S.S., Pasynskii, A.A., and Tsodikov, M.V., 2019, Original Pt-Sn/Al2O3 catalyst for selective hydrodeoxygenation of vegetable oils, Energy, 172, 18–25.

[19] Yurpalov, V.L., Neponiashchii, A.A., Drozdov, V.A., Antonicheva, N.V., Buluchevskiy, E.A., and Lavrenov, A.V., 2021, The deactivation of acidic sites of NiMo/B2O3–Al2O3 catalysts during vegetable oil hydrodeoxygenation studied by EPR spectroscopy, Magn. Reson. Chem., 59 (6), 600–607.

[20] Adams, B.D., and Chen, A., 2011, The role of palladium in a hydrogen economy, Mater. Today, 14 (6), 282–289

[21] Pal, N., Verma, V., Khan, A., Mishra, A., Anand, M., Venkata Pramod, C., Akhtar Farooqui, S., and Kumar Sinha, A., 2022, Hydrotreating and hydrodemetalation of raw jatropha oil using mesoporous Ni-Mo/γ-Al2O3 catalyst, Fuel, 326, 125108.

[22] Trisunaryanti, W., Sumbogo, S.D., Mukti, R.R., Kartika, I.A., Hartati, H., and Triyono, T., 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.

[23] Trisunaryanti, W., Suarsih, E., Triyono, T., and Falah, I.I., 2019, Well-dispersed nickel nanoparticles on the external and internal surfaces of SBA-15 for hydrocracking of pyrolyzed α-cellulose, RSC Adv., 9 (3), 1230–1237.

[24] Robinson, A.M., 2016, The Role of Oxophilic Metal Promoters in Bimetallic Hydrodeoxygenation Catalysts, Dissertation, University of Colorado at Boulder.

[25] Trisunaryanti, W., Sumbogo, S.D., Novianti, S.A., Fatmawati, D.A., Ulfa, M., and Nikmah, Y.L., 2021, ZnO-Activated Carbon Blended as a Catalyst for Oxidative Desulfurization of Dibenzothiophene, Bull. Chem. React. Eng. Catal., 16 (4), 881–887.

[26] Oginni, O., Singh, K., Oporto, G., Dawson-Andoh, B., McDonald, L., and Sabolsky, E., 2019, Effect of one-step and two-step H3PO4 activation on activated carbon characteristics, Bioresour. Technol. Rep., 8, 100307.

[27] Yang, W., and Liu, Y., 2021, Removal of Elemental Mercury using seaweed biomass-based porous carbons prepared from microwave activation and H2O2 modification, Energy Fuels, 35 (3), 2391–2401.

[28] Demir, M., and Doguscu, M., 2022, Preparation of porous carbons using NaOH, K2CO3, Na2CO3 and Na2S2O3 activating agents and their supercapacitor application: a comparative study, ChemistrySelect, 7 (4), e202104295.

[29] Bag, O., Tekin, K., and Karagoz, S., 2020, Microporous activated carbons from lignocellulosic biomass by KOH activation, Fullerenes, Nanotubes Carbon Nanostruct., 28 (12), 1030–1037.

[30] Chen, R., Li, L., Liu, Z., Lu, M., Wang, C., Li, H., Ma, W., and Wang, S., 2017, Preparation and characterization of activated carbons from tobacco stem by chemical activation, J. Air Waste Manage. Assoc., 67 (6), 713–724.

[31] Liang, Q., Liu, Y., Chen, M., Ma, L., Yang, B., Li, L., and Liu, Q., 2020, Optimized preparation of activated carbon from coconut shell and municipal sludge, Mater. Chem. Phys., 241, 122327.

[32] Saab, R., Polychronopoulou, K., Zheng, L., Kumar, S., and Schiffer, A., 2020, Synthesis and performance evaluation of hydrocracking catalysts: A review, J. Ind. Eng. Chem., 89, 83–103.

[33] Oginni, O., Singh, K., Oporto, G., Dawson-Andoh, B., McDonald, L., and Sabolsky, E., 2019, Influence of one-step and two-step KOH activation on activated carbon characteristics, Bioresour. Technol. Rep., 7, 100266.

[34] Djilani, C., Zaghdoudi, R., Djazi, F., Bouchekima, B., Lallam, A., Modarressi, A., and Rogalski, M., 2015, Adsorption of dyes on activated carbon prepared from apricot stones and commercial activated carbon, J. Taiwan Inst. Chem. Eng., 53, 112–121.



DOI: https://doi.org/10.22146/ijc.84640

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