This work is licensed under the Creative Commons Attribution 4.0 International License.
Min, D. (2019). Ultrasonic semi-solid soldering 6061 aluminum alloys joint with sn-9zn solder reinforced with nano/nano + micron al2o3 particles. Ultrasonics sonochemistry(52-), 52.Search in Google Scholar
Tang, Y., Takizawa, Y., Yumoto, M., Otagiri, Y., & Horita, Z. (2020). Achieving grain refinement of upsized al–3mg–0.2sc (mass%) round rods using multi-pass high-pressure sliding (mp-hps). MATERIALS TRANSACTIONS.Search in Google Scholar
Wang, Lei, Wei, Yanhong, Zhao, & Wenyong, et al. (2018). Effects of welding parameters on microstructures and mechanical properties of disk laser beam welded 2a14-t6 aluminum alloy joint. Journal of Manufacturing Processes.Search in Google Scholar
Ghiasvand, A., Yavari, M. M., Jacek Tomków, Guerrero, J. W. G., Kheradmandan, H., & Dorofeev, A., et al. (2021). Investigation of mechanical and microstructural properties of welded specimens of aa6061-t6 alloy with friction stir welding and parallel friction stir welding methods. Materials(20).Search in Google Scholar
Zhang, P., Zhao, S., Zhang, C., Chen, Z., Zhang, J., & Fei, L., et al. (2022). Microstructure and mechanical properties of probeless friction stir extrusion joined joints of 6061-t6 aluminum alloy to q235 steel. The International Journal of Advanced Manufacturing Technology, 119(5), 3029-3043.Search in Google Scholar
Li, Z., Yu, H., & Sun, D. (2021). The tribocorrosion mechanism of aluminum alloy 7075-t6 in the deep ocean. Corrosion Science, 183(3), 109306.Search in Google Scholar
Abdollahzadeh, A.Shokuhfar, A.Cabrera, J. M.Zhilyaev, A. P.Omidvar, H. (2019). In-situ nanocomposite in friction stir welding of 6061-t6 aluminum alloy to az31 magnesium alloy. Journal of Materials Processing Technology, 263.Search in Google Scholar
Wang, H. F., Zuo, D. W., Liu, S. R., Pu, J. F., & Song, W. W. (2020). Wear resistance analysis of a lightweight aluminum alloy sheet friction stir joint area. Strength of Materials, 52(4), 565-572.Search in Google Scholar
Bingjie, Z., Yuting, L., Yang, D., Liqiang, W., & Weijie, L. (2018). The grain refinement mechanisms of various phases in shot-peened nickel-aluminum bronze (nab) alloy. Materials Characterization, 144, 77-85.Search in Google Scholar
Lu, D., You, G., Luo, J., Ding, Y., & Tong, X. (2020). Effects of rotational speed on microstructure and mechanical properties of inertia friction-welded 7005–5083 aluminum alloy joints. Journal of Materials Science, 55(26).Search in Google Scholar
Ji, F., Wang, Z., Wu, L., Luo, K., & Lu, J. (2022). Strain rate dependence of tensile properties and strengthening mechanism of ti6al4v alloy undergoing different coverage layers of laser shock peening. Surface & Coatings Technology.Search in Google Scholar
Zhang, K., Hu, R., Li, J., Yang, J., & Gao, Z. (2020). Grain refinement of 1 at.% ta-containing cast tial-based alloy by cyclic air-cooling heat treatment. Materials Letters, 274, 127940.Search in Google Scholar
Li, Y., Wang, Y., Chen, J., Chae, L. Y., & Feng, Z. (2024). Surface grain refinement of casting a380 aluminum alloy by ultrasonic-assisted surface mechanical grinding treatment. Materials Letters(Jan.1), 354.Search in Google Scholar
Qiu, Y., Yang, X., Xu, J., Li, J., Xiang, S., & Chen, Z., et al. (2022). Enhanced mechanical property and corrosion resistance of alloy 5182 fsw joints by sc and zr alloying. Materials Characterization.Search in Google Scholar
Silva, R. P., Soares, R., Neto, R., Reis, A., Paiva, R., & Madureira, R., et al. (2022). Grain refinement of inconel 718 superalloy-the effect of rotating magnetic field. Materials (Basel, Switzerland), 15(6).Search in Google Scholar
Prasad, A., Mok, J., Lafortune, L., & Bichler, L. (2018). Grain refinement of b319 alloy using spark plasma sintered al–ti–c grain refiners. Transactions of the Indian Institute of Metals, 71(11), 2759-2763.Search in Google Scholar
C, W. W. A. B., B, S. Y. A., B, K. Q. A., B, K. W. A., B, S. Z. A., & B, P. P. A., et al. (2021). Microstructure and nanomechanical behavior of friction stir welded joint of 7055 aluminum alloy. Journal of Manufacturing Processes, 61, 311-321.Search in Google Scholar
Fu, L., Duan, H., Li, H., Lin, L., Wang, Q., & Yao, J., et al. (2020). Low-cycle fatigue behavior of 7075-t6 aluminum alloy at different strain amplitudes. Materials Express.Search in Google Scholar
Liao, Z., Polyakov, M., Diaz, O. G., Axinte, D., & Hardy, M. (2019). Grain refinement mechanism of nickel-based superalloy by severe plastic deformation - mechanical machining case. Acta Materialia, 180.Search in Google Scholar
Su, M. L., Qi, X. Y., Xu, L. Y., Feng, Q., Han, Y. D., & Zhao, L. (2022). Microstructural and mechanical analysis of 6063-t6 aluminum alloy joints bonded by friction stir welding. Journal of Materials Science, 57(31), 15078-15093.Search in Google Scholar
Li, J. Z. F. (2018). Effect of rotation speed on friction behavior of rotary friction welding of aa6061-t6 aluminum alloy. Journal of neurosurgical sciences, 62(5).Search in Google Scholar
Li, D., & Wang, X. (2021). The effect of plug rotation speed on micro-structure of nugget zone of friction plug repair welding joint for 6082 aluminum alloy. Materials (Basel, Switzerland), 14(18).Search in Google Scholar
Senwei, W., Kunming, Z., Sihui, O., Chengao, D., Xiong, W., & Aitao, T., et al. (2023). Grain refinement and mechanical properties of az31 alloy processed by pre-die forging extrusion at different temperatures. Journal of Materials Engineering and Performance(23), 32.Search in Google Scholar
Pu, J., Bondarev, S., Wang, H., Song, W., Liu, S., & Jiang, D. (2023). Analysis of microstructure and wear resistance of friction stir welded joints of 7075-t6 aluminum alloy. Ferroelectrics.Search in Google Scholar
Wang, H., An, H., & Yang, S. (2021). Grain refinement mechanism of rapidly solidified nickel alloys. International Journal of Materials Research (formerly Zeitschrift fuer Metallkunde).Search in Google Scholar
Ozan, S. (2020). Effect of friction stir welding on the microstructure and mechanical properties of aa 6063-t6 aluminum alloy. Materialwissenschaft und Werkstofftechnik, 51(8).Search in Google Scholar
