Gold nanoparticles (G-NPs) were successfully synthesized using Gracilaria sp seaweed extract. Visually, color changes from purple-blue to ruby red and then finally to pink. UV-Vis spectrophotometer showed the optimum condition of G-NPs at 531 nm wavelength with an absorbance value of 1.1. The fourier transform infrared (FTIR) spectroscopy shows the absorption peak of functional groups at the Gracilaria sp seaweed extract like hydroxyl group (-OH), aromatic (C=C), alkane (C-H), and amine (C-N) at the wavenumbers of 3356, 1613, 1456, and 1182 cm^-1, respectively. The X-ray diffraction (XRD) shows the crystallinity peaks of G-NPs at 2θ: 38.3^o, 44.1^o, 64.8^o, and 77.8^o with miller indices of (111), (200), (220), and (311). The Particle size analyzer (PSA) shows the distribution and particle size average of G-NPs was 11.8 nm. Analysis of particle zeta charge (PZC) confirms the total charge of inter-particles was -24.7 mV. The transmission electron microscopy (TEM) images shows the G-NPs was spherical shape with a particle size was 20 nm. The hand soap@G-NPs have a pH of 6.0 and foam height stability of 4.1 cm for 10 min.

[1] Aljabali, A. A., Akkam, Y., Al Zoubi, M. S., Al-Batayneh, K. M., Al-Trad, B., Abo Alrob, O., Alkilany, A. M., Benamara, M and Evans, D. J, Nanomater, 2018, 8 (3), 174.

[2] Islam, N. U., Jalil, K., Shahid, M., Rauf, A., Muhammad, N., Khan, A., Shah, M. R and Khan, A, Arab. J. Chem, 2019, 12 (8), 2914-2925.

[3] Islam, N. U., Jalil, K., Shahid, M., Muhammad, N and Rauf, A, Arab. J. Chem, 2019, 12 (8) 2310-2319.

[4] Yu, J., Xu, D., Guan, H. N., Wang, C and Huang, L. K, Mater. Lett, 2016, 166, 110-112.

[5] Abbasi, T., Anuradha, J., Ganaie, S. U and Abbasi, S. A, J. King Saud Univ. Sci, 2015, 27 (1), 15-22.

[6] Ahmed, E., Kalathil, S., Shi, L., Alharbi, O and Wang, P, J. Saudi Chem. Soc, 2018, 22 (8), 919-929.

[7] Borse, V and Konwar, A. N, Sensors. Int, 2020, 1, 100051

[8] Sengani, M., Grumezescu, A. M and Rajeswari, V. D, OpenNano, 2017, 2, 37-46.

[9] Syed, B, Prasad, N. M and Satish, S, J. Microsc. Ultrastruct, 2016, 4 (3), 162-166.

[10] Bindhu, M. R and Umadevi, Mater. Lett, 2014, 120, 122-125.

[11] Santos, N. M., Gomes, A. S., Cavalcante, D. G., Santos, L. F., Teixeira, S. R., Cabrera, F. C and Job, A. E, IET Nanobiotechnol, 2019, 13(3), 307-315.

[12] Li, H., Wang, W., Ang, B., Xiong, J., Zhang, F., Chen, W and Du, J, Micro Nano Lett, 2019, 14 (10), 1069-1074.

[13] Liang, M., Zhang, G., Li, R., Feng, Y., Wang, J and Hou, P, Micro Nano Let, 2019, 14 (8) 865-867.

[14] Foo, Y. Y., Periasamy, V., Kiew, L. V., Kumar, G. G and Malek, S. N. A, Nanomater, 2017, 7 (6), 123.

[15] Arya, S. S., Sharma, M. M., Das, R. K., Rookes, J., Cahill, D and Lenka, S. K, Heliyon, 2019, 5 (7), e02021.

[16] Majoumouo, M. S., Sharma, J. R., Sibuyi, N. R., Tincho, M. B., Boyom, F.F and Meyer, M, Molecules, 2020, 25 (19), 4469.

[17] Mukundan, D., Mohankumar, R and Vasanthakumari, R, Bull Mater Sci, 2017,40 (2), 335-344.

[18] Asariha, M., Chahardoli, A., Karimi, N., Gholamhosseinpour, M., Khoshroo, A., Nemati, H., Shokoohinia, Y and Fattahi, A., Bull Mater Sci, 2020, 43 (1), 1-10.

[19] Clarance, P., Luvankar, B., Sales, J., Khusro, A., Agastian, P., Tack, J. C., Al Khulaifi, M. M., Al-Shwaiman, H. A., Elgorban, A. M., Syed, A and Kim, H. J, J. Biol. Sci, 2020, 27 (2), 706-712..

[20] Vijayakumar, S, J. Saudi Chem. Soc, 2019, 23 (6), 753-761.

[21] Guo, Y., Jiang, N., Zhang, L and Yin, M, Arab. J. Chem, 2020, 13 (4), 5096-5106.

[22] Purwaningsih, S and Deskawati, E, JPHPI, 2020, 23 (2), 503-512.

[23] Kaul, S., Gulati, N., Verma, D., Mukherjee, S and Nagaich, U, J. Pharm, 2018, ID Article 3420204, 1-19.

[24] Rahmi, D., Yunilawati, R., Setiawati, I., Irwinanita, I., Jati, B. N., Riyanto, A., Yemirta, Y and Aidha, N. N, Jurnal Sains Materi Indonesia, 2021, 23 (1), 24-30.

[25] Rahmi, D., Yunilawati, R., Jati, B. N., Setiawati, I., Riyanto, A., Batubara, I and Astuti, R. I, Cosmetics, 2021, 8 (94).

[26] Témoin‐Fardini, S., Servant, J and Sellam, S, Int. J. Cosmet. Sci, 2017, 39 (5), 476-485.

[27] Missler, S. R., Vredeveld, D. J., Westrate, E. D., Sliva, P. G and Brouwer, S. J, J. Surfactants. Deterg, 2013, 17 (5), 839-847.

[28] Kim, E., Kim, S., Nam, G. W., Lee, H., Moon, S and Chang, I, Int. J. Cosmet. Sci, 2009, 31 (4), 263-269.

[29] Bratovcic, A and Nazdrajic, S, J. Surfactants. Deterg, 2020, 23 (6), 1135-1143.

[30] Li, F., Tang, X., Chen, M and Zhang, W, J. Surfactants. Deterg, 2017, 20 (6),1337-1349.

[31] Yu, G., Long, S. A., Karinshak, K. A., Grady, B. P., Harwell, J. H and Arhancet, G. B, J. Surfactants. Deterg, 2015, 18 (5), 895-903.

[32] George, A. L and White, G. F, Environ. Toxicol. Chem, 2009, 18 (10), 2232-2236.

[33] Du, Y., Gao, J., Liu, X and Yang, J, J. Vinyl Addit. Technol, 2014, 20 (4), 243-249.

[34] Kurrey, R., Deb, M. K and Shrivas, K, J. Surfactants. Deterg, 2018, 21 (2), 197-208.

[35] Riaz, S., Rana, N. F., Hussain, I., Tanweer, T., Nawaz, A., Menaa, F., Janjua, H. A., Alam, T., Batool, A., Naeem, A., Hameed, M and Ali, S. M, Nanomater, 2020, 10 (1769), 1-14.

[36] Inagaki, C. S., Oliveira, M. M and Zarbin, A. J. G, J. Colloid Interface Sci, 2018, 516, 498-510.

[37] Babu, P. J., Sharma, P., Saranya, S and Bora, U, Mater. Lett, 2013, 93, 431-434.

[38] Rajan, A., Rajan, A. R and Philip, D, Opennano, 2017, 2, 1-8.

[39] Mukherjee, P., Roy, M., Mandal, B. P., Choudhury, S., Tewari, R., Tyagi, A. K and Kale, S. P, J. Colloid Interface Sci, 2012, 367, 148-152.

[40] Kanchi, S., Kumar, G., Lo, A. Y., Tseng, C. M., Chen, S. K., Lin, C. Y and Chin, T. S, Arab. J. Chem, 2018, 11, 247-255.

[41] Al-Radadi, N. S, Arab. J. Chem. 2021, 14 (102956).

[42] Zhang, Y., Wang, P., Mao, H., Zhang, Y., Zheng, L., Yu, P., Guo, Z., Li, L and Jiang, Q, Mater. Des 2021, 197 (109231), 1-10.

[43] Alp, E., İmamoğlu, R., Savaci, U., Turan, S., Kazmanlı, M. K and Genç, A, J. Alloys Compd, 2021, 852, (157021).