This paper reports the effects of polypropylene-graft-maleic anhydride (PP-g-MA) and graphene nanoplatelet (GNP on tensile stress of various PLA/PP weight ratio. The PLA/PP blends prepared with the ratio 70/30, 80/20, and 90/10 with the addition of PP-g-MA (1 to 5 phr) and GNP (1 to 3 phr) by using an injection molding machine. The tensile stress (MPa) was analyzed based on 11 runs of full factorial design. The results showed that the tensile stress of PLA/PP blends gradually increased after the addition of PP-g-MA and GNP. There is a relationship between PP-g-MA and GNP which causes a positive impact on the mechanical properties of PLA/PP blends. The optimum tensile stress of 50.06 MPa achieved at the ratio of 90/10 blends with 5 phr of PP-g-MA and 3 phr of GNP.

[1] Sui, G., Jing, M., Zhao, J., Wang, K., Zhang, Q., and Fu, Q., 2018, A comparison study of high shear force and compatibilizer on the phase morphologies and properties of polypropylene/polylactide (PP/PLA) blends, Polymer, 154, 119–127.

[2] Rajan, K.P., Thomas, S.P., Gopanna, A., Al-Ghamdi, A., and Chavali, M., 2018, Rheology, mechanical properties and thermal degradation kinetics of polypropylene (PP) and polylactic acid (PLA) blends, Mater. Res. Express, 5 (8), 085304.

[3] Deng, Y., Yu, C., Wongwiwattana, P., and Thomas, N.L., 2018, Optimising ductility of poly(lactic acid)/poly(butylene adipate-co-terephthalate) blends through co-continuous phase morphology, J. Polym. Environ., 26 (9), 3802–3816.

[4] Bijarimi, M., Amirul, M., Norazmi, M., Ramli, A., Desa, M.S.Z., Anuar Desa, M.D., and Abu Samah, M.A., 2019, Preparation and characterization of poly (lactic acid) (PLA)/polyamide 6 (PA6)/graphene nanoplatelet (GNP) blends bio-based nanocomposites, Mater. Res. Express, 6 (5), 055044.

[5] Anstey, A., Codou, A., Misra, M., and Mohanty, A.K., 2018, Novel compatibilized nylon-based ternary blends with polypropylene and poly(lactic acid): Fractionated crystallization phenomena and mechanical performance, ACS Omega, 3 (3), 2845–2854.

[6] Zhang, K., Nagarajan, V., Misra, M., and Mohanty, A.K., 2014, Supertoughened renewable PLA reactive multiphase blends system: Phase morphology and performance, ACS Appl. Mater. Interfaces, 6 (15), 12436–12448.

[7] Tengsuthiwat, J., Asawapirom, U., Siengchin, S., and Karger-Kocsis, J., 2018, Mechanical, thermal, and water absorption properties of melamine–formaldehyde-treated sisal fiber containing poly(lactic acid) composites, J. Appl. Polym. Sci., 135 (2), 45681.

[8] Nehra, R., Maiti, S.N., and Jacob, J., 2018, Analytical interpretations of static and dynamic mechanical properties of thermoplastic elastomer toughened PLA blends, J. Appl. Polym. Sci., 135 (1), 45644.

[9] Pivsa-Art, S., Kord-Sa-Ard, J., Pivsa-Art, W., Wongpajan, R., O-Charoen, N., Pavasupree, S., and Hamada, H., 2016, Effect of compatibilizer on PLA/PP blend for injection molding, Energy Procedia, 89, 353–360.

[10] Lee, T.W., and Jeong, Y.G., 2014, Enhanced electrical conductivity, mechanical modulus, and thermal stability of immiscible polylactide/polypropylene blends by the selective localization of multi-walled carbon nanotubes, Compos. Sci. Technol., 103, 78–84.

[11] Choudhary, P., Mohanty, S., Nayak, S.K., and Unnikrishnan, L., 2011, Poly(L-lactide)/polypropylene blends: Evaluation of mechanical, thermal, and morphological characteristics, J. Appl. Polym. Sci., 121 (6), 3223–3237.

[12] Chen, R., Zou, W., Zhang, H., Zhang, G., Yang, Z., and Qu, J., 2015, Poly(lactic acid)/polypropylene and compatibilized poly(lactic acid)/polypropylene blends prepared by a vane extruder: Analysis of the mechanical properties, morphology and thermal behavior, J. Polym. Eng., 35 (8), 753–764.

[13] Ebadi-Dehaghani, H., Khonakdar, H.A., Barikani, M., Jafari, S.H., Wagenknecht, U., and Heinrich, G., 2016, An investigation on compatibilization threshold in the interface of polypropylene/polylactic acid blends using rheological studies, J. Vinyl Addit. Technol., 22 (1), 19–28.

[14] Yoo, T.W., Yoon, H.G., Choi, S.J., Kim, M.S., Kim, Y.H., and Kim, W.N., 2010, Effects of compatibilizers on the mechanical properties and interfacial tension of polypropylene and poly(lactic acid) blends, Macromol. Res., 18 (6), 583–588.

[15] Lee, H.S., and Kim, J.D., 2012, Effect of a hybrid compatibilizer on the mechanical properties and interfacial tension of a ternary blend with polypropylene, poly(lactic acid), and a toughening modifier, Polym. Compos., 33 (7), 1154–1161.

[16] He, Q., Yuan, T., Zhang, X., Luo, Z., Haldolaarachchige, N., Sun, L., Young, D.P., Wei, S., and Guo, Z., 2013, Magnetically soft and hard polypropylene/cobalt nanocomposites: Role of maleic anhydride grafted polypropylene, Macromolecules, 46 (6), 2357–2386.

[17] Ploypetchara, N., Suppakul, P., Atong, D., and Pechyen, C., 2014, Blend of polypropylene/poly(lactic acid) for medical packaging application: Physicochemical, thermal, mechanical, and barrier properties, Energy Procedia, 56, 201–210.

[18] Zawawi, E.Z.E., Romli, A.Z., Suli, S.F.M., and Isnin, M.A., 2018, The effect of MAPP compatibilizing agent on the mechanical and thermal properties of polypropylene/PLA blends, IJET, 7 (4.14), 361–364.

[19] Wang, X., Liu, W., Li, H., Du, Z., and Zhang, C., 2016, Role of maleic- anhydride-grafted- polypropylene in supercritical CO 2 foaming of poly (lactic acid) and its effect on cellular morphology, J. Cell. Plast., 52 (1), 37–56.

[20] Nofar, M., Salehiyan, R., Ciftci, U., Jalali, A., and Durmuş, A., 2020, Ductility improvements of PLA-based binary and ternary blends with controlled morphology using PBAT, PBSA, and nanoclay, Composites, Part B, 182, 107661.

[21] Bijarimi, M., Shahadah, N., Ramli, A., Nurdin, S., Alhadadi, W., Muzakkar, M.Z., and Jaafar, J., 2020, Poly(lactic acid) (PLA)/acrylonitrile butadiene styrene (ABS) with graphene nanoplatelet (GNP) nanocomposites, Indones. J. Chem., 20 (2), 276–281.

[22] Alhadadi, W., Almaqtari, A., Hafidzah, A., Bijarimi, M., Desa, M.S.Z., Merzah, H., Normaya, E., and Norazmi, M., 2019, Thermal stability of melt-blended poly (lactic acid) (PLA)/polyamide 66 (PA66)/graphene nanoplatelets (GnP), IOP Conf. Ser.: Mater. Sci. Eng., 702 (1), 012037.

[23] Ebadi-Dehaghani, H., Khonakdar, H.A., Barikani, M., and Jafari, S.H., 2015, Experimental and theoretical analyses of mechanical properties of PP/PLA/clay nanocomposites, Composites, Part B, 69, 133–144.

[24] Mandal, D.K., Bhunia, H., and Bajpai, P.K., 2019, Thermal degradation kinetics of PP/PLA nanocomposite blends, J. Thermoplast. Compos. Mater., 32 (12), 1714–1730.

[25] Azizi, S., Azizi, M., and Sabetzadeh, M., 2019, The role of multiwalled carbon nanotubes in the mechanical, thermal, rheological, and electrical properties of PP/PLA/MWCNTs nanocomposites, J. Compos. Sci., 3 (3), 64.

[26] Nuñez, K., Rosales, C., Perera, R., Villarreal, N., and Pastor, J.M., 2011, Nanocomposites of PLA/PP blends based on sepiolite, Polym. Bull., 67 (9), 1991–2016.

[27] Shrivastava, N.K., Wooi, O.S., Hassan, A., and Inuwa, I.M., 2018, Mechanical and flammability properties of poly(lactic acid)/poly(butylene adipate-co-terephthalate) blends and nanocomposites: Effects of compatibilizer and graphene, Malays. J. Fundam. Appl. Sci., 14 (4), 425–431.

[28] Kashi, S., Gupta, R.K., Kao, N., Hadigheh, S.A., and Bhattacharya, S.N., 2018, Influence of graphene nanoplatelet incorporation and dispersion state on thermal, mechanical and electrical properties of biodegradable matrices, J. Mater. Sci. Technol., 34 (6), 1026–1034.

[29] Kausar, A., and Ur Rahman, A., 2016, Effect of graphene nanoplatelet addition on properties of thermo-responsive shape memory polyurethane-based nanocomposite, Fullerenes Nanotubes Carbon Nanostruct., 24 (4), 235–242.

[30] Tu, C., Nagata, K., and Yan, S., 2017, Influence of melt-mixing processing sequence on electrical conductivity of polyethylene/polypropylene blends filled with graphene, Polym. Bull., 74 (4), 1237–1252.

[31] Ajorloo, M., Fasihi, M., Ohshima, M., and Taki, K., 2019, How are the thermal properties of polypropylene/graphene nanoplatelet composites affected by polymer chain configuration and size of nanofiller?, Mater. Des., 181, 108068.

[32] Ahmad, S.R., Xue, C., and Young, R.J., 2017, The mechanisms of reinforcement of polypropylene by graphene nanoplatelets, Mater. Sci. Eng., B, 216, 2–9.

[33] Vadori, R., Misra, M., and Mohanty, A.K., 2017, Statistical optimization of compatibilized blends of poly(lactic acid) and acrylonitrile butadiene styrene, J. Appl. Polym. Sci., 134 (9), 44516.

[34] Brandenburg, R.F., Lepienski, C.M., Becker, D., and Coelho, L.A.F., 2017, Influence of mixing methods on the properties of high density polyethylene nanocomposites with different carbon nanoparticles, Matéria, 22 (4), e-11888.

[35] Ghasemi, F.A., Daneshpayeh, S., and Ghasemi, I., 2017, Multi-response optimization of impact strength and elongation at break of nanocomposites based on polypropylene/polyethylene binary polymer matrix in the presence of titanium dioxide nanofiller, J. Elastomers Plast., 49 (8), 633–649.

[36] Dzul-Cervantes, M., Herrera-Franco, P.J., Tábi, T., and Valadez-Gonzalez, A., 2017, Using factorial design methodology to assess PLA-g-Ma and henequen microfibrillated cellulose content on the mechanical properties of poly(lactic acid) composites, Int. J. Polym. Sci., 2017, 4046862.

[37] Codou, A., Anstey, A., Misra, M., and Mohanty, A.K., 2018, Novel compatibilized nylon-based ternary blends with polypropylene and poly(lactic acid): Morphology evolution and rheological behaviour, RSC Adv., 8 (28), 15709–15724.

[38] Jariyakulsith, P., and Puajindanetr, S., 2018, Relationship between compatibilizer and yield strength of PLA/PP Blend, IOP Conf. Ser.: Mater. Sci. Eng., 303, 012004.

[39] Inuwa, I.M., Hassan, A., and Shamsudin, S.A., 2014, Thermal properties, structure and morphology of graphene reinforced polyethylene terephthalate/polypropylene nanocomposites, Malays. J. Anal. Sci., 18 (2), 466–477.

[40] Al-Saleh, M.A., Yussuf, A.A., Al-Enezi, S., Kazemi, R., Wahit, M.U., Al-Shammari, T., and Al-Banna, A., 2019, Polypropylene/graphene nanocomposites: Effects of GNP loading and compatibilizers on the mechanical and thermal properties, Materials, 12 (23), 3924.