參考文獻(xiàn)/References:

\[1\]劉世鋒, 宋璽, 薛彤, 等. 航空材料學(xué)報(bào)\[J\], 2020, 36: 77-94. LIU S F, SONG X, XUE T, et al. Journal of Aeronautical Materials\[J\], 2020, 36: 77-94. \[2\]WEI S L, HUANG L J, LI X T, et al. Journal of Alloys and Compounds\[J\], 2018, 752: 164-178. \[3\]ZHANG J L, SONG B, CAI C, et al. Advanced Powder Materials\[J\], 2022, 1(2): 100010. \[4\]TJONG S C, MAI Y W. Composites Science and Technology\[J\], 2008, 68(3/4): 583-601. \[5\]黃陸軍, 耿林, 彭華新. 中國(guó)材料進(jìn)展\[J\], 2019, 38(3): 214-250. HUANG L J, GENG L, PENG H X. Materials China\[J\], 2019, 38(3): 214-250. \[6\]耿林, 梁淑華, 鄭開(kāi)宏, 等. 金屬基復(fù)合材料\[M\]. 北京: 中國(guó)鐵道出版社, 2020: 121-125. GENG L, LIANG S H, ZHENG K H, et al. Metal Matrix Composites\[M\], Beijing: China Railway Publishing House, 2020: 121-125. \[7\]MUNIR K S, LI Y C, LIN J X, et al. Materialia\[J\], 2018, 3: 122-138. \[8\]SU Y S, LI Z, YU Y, et al. Science China Materials\[J\], 2018, 61(1): 112-124. \[9\]CHU K, WANG F, LI Y B, et al. Composites Part A: Applied Science and Manufacturing\[J\], 2018, 109: 267-279. \[10\]KONDOH K, THRERUJIRAPAPONG T, IMAI H, et al. Composites Science and Technology\[J\], 2009, 69(7/8): 1077-1081. \[11\]QIU C H, SU Y S, YANG J Y, et al. Composites Part C: Open Access\[J\], 2021, 4: 100120. \[12\]SONG Y, CHNE Y, LIU W W, et al. Materials & Design\[J\], 2016, 109: 256-263. \[13\]HU Z R, TONG G Q, NIAN Q, et al. Composites Part B: Engineering\[J\], 2016, 93: 352-359. \[14\]MUNIR K S, WEN C, LI Y C. Advanced Biosystems\[J\], 2019, 3(3): 1800212. \[15\]LAVISH K S, ALOK B, AKASH O, et al. Diamond & Related Materials\[J\], 2019, 91: 144-155. \[16\]CAO Z, WANG X D, LI J L, et al. Journal of Alloys and Compounds\[J\], 2017, 696: 498-502. \[17\]TANG C Y, WONG C T, ZHANG L N, et al. Journal of Alloys and Compounds\[J\], 2013, 557: 67-72. \[18\]TANG M K, ZHANG L C, ZHANG N. Materials Science and Engineering: A\[J\], 2021, 814: 141187. \[19\]LIU K Y, LI J S, WAN J, et al. Carbon\[J\], 2022, 197: 412-424. \[20\]TIAN N, DONG L L, WANG H L, et al. Journal of Alloys and Compounds\[J\], 2021, 867: 159093. \[21\]DONG L L, XIAO B, LIU Y, et al. Ceramics International\[J\], 2018, 44: 17835-17844. \[22\]ZHOU Y, DONG L L, WANG Q H, et al. Advanced Engineering Materials\[J\], 2021, 23: 2001411. \[23\]DONG L L, LU J W, FU Y Q, et al. Carbon\[J\], 2020, 164: 272-286. \[24\]YANG Y J, LIU M B, ZHOU S Q, et al. Journal of Alloys and Compounds\[J\], 2021, 871: 159535. \[25\]MU X N, CAI H N, ZHANG H M, et al. Composites Part A: Applied Science and Manufacturing\[J\], 2019, 123: 86-96. \[26\]LIU L, ZHANG H M, CHENG X W, et al. Ceramics International\[J\], 2022, 48: 37470-37475. \[27\]ZHANG W, ZHOU S Q, REN W J, et al. Journal of Alloys and Compounds\[J\], 2021, 888: 161527. \[28\]YIN H B, LI P. International Journal of Fatigue\[J\], 2023, 167: 107352. \[29\]XIONG Y F, ZHANG F M, DAI T, et al. Materials Characterization\[J\], 2022, 194: 112455. \[30\]LIN K J, FANG Y M, GU D D, et al. Advanced Powder Technology\[J\], 2021, 32: 1426-1437. \[31\]YAN Q, CHEN B, LI J S. Carbon\[J\], 2021, 174: 451-462. \[32\]LIU Y, LI S F, MISRA R D K, et al. Scripta Materialia\[J\], 2020, 183: 6-11. \[33\]ATTAR H, HAGHIGHI S E, KENT D, et al. International Journal of Machine Tools and Manufacture\[J\], 2018, 133: 85-102. \[34\]覃信茂, 謝卓成, 謝泉. 電子元件與材料\[J\], 2014, 33(3): 1-4. QIN X M , XIE Z C , XIE O. Electronic Components and Materials\[J\], 2014, 33(3): 1-4. \[35\]YANG H, SHAN C, LI F, et al. Chemical Communications\[J\], 2009, 14(26): 3880-3882. \[36\]唐秀之. 氧化石墨烯表面功能化修飾\[D\]. 北京：北京化工大學(xué), 2012. TANG X Z. Surface Functionalization Modification of Graphene Oxide\[D\]. Beijing: Beijing University of Chemical Technology, 2012. \[37\]董龍龍, 李響, 常國(guó), 等.通過(guò)含氧石墨烯改性分散提高鈦基復(fù)合材料性能的方法: CN115074566B\[P\]. 2023-04-08. DONG L L, LI X, CHANG G, et al. The Method of Improving the Properties of Titanium Matrix Composites by Modified Dispersion of Oxygen�睠ontaining Graphene: CN115074566B\[P\]. 2023-04-08. \[38\]薛航.石墨烯改性分散及鈦基復(fù)合材料制備與性能研究\[D\]. 西安: 西安科技大學(xué), 2022. XUE H. Preparation and Properties of Graphene Modified Dispersion and Titanium Matrix Composites\[D\], Xi�餫n: Xi�餫n University of Science and Technology, 2022. \[39\]YANG L Z, HAN T L, ZHANG X, et al. Materials Research Letters\[J\], 2022, 10(9): 567-574. \[40\]PU B W, SHA J W, LUN E Z, et al. Materials Science and Engineering: A\[J\], 2019, 742: 201-210. \[41\]XUE Y L, CHEN W G, WANG J J, et al. Materials\[J\], 2018, 11(11): 2071. \[42\]GE Y X, ZHANG H M, CHENG X W, et al. Journal of Alloys and Compounds\[J\], 2022, 893: 162240. \[43\]SI X, LI M, CHEN F, et al. Materials Science and Engineering: A\[J\], 2017, 708: 311-318. \[44\]ZHANG X, LI S F, PAN D, et al. Composites Part A: Applied Science and Manufacturing\[J\], 2018, 105: 87-96. \[45\]VELMURUGAN V, MOHAN B. Materials Research Express\[J\], 2023, 10: 036504. \[46\]SHUAI C, WANG B, BIN S, et al. Materials & Design\[J\], 2020, 191: 108612. \[47\]ZHANG W L, CHOI H J, LEONG Y K. Materials Chemistry and Physics\[J\], 2014, 145(1/2): 151-155. \[48\]FAN Y, JIANG W, KAWASAKI A. Advanced Functional Materials\[J\], 2012, 22(18): 3882-3889. \[49\]XUE H, ZHU M, DONG L L, et al. Journal of Alloys and Compounds\[J\], 2022, 905: 164198. \[50\]CHEN B, SHEN J H, YE W T, et al. Carbon\[J\], 2017, 114: 198-208. \[51\]MU X N, CAI H N, ZHANG H M, et al. Materials & Design\[J\], 2018, 140: 431-441. \[52\]MU X N, CAI H N, ZHANG H M, et al. Materials Science and Engineering: A\[J\], 2018. 725: 541-548. \[53\]SHANG C Y, ZHANG F M, WANG J, et al. Composites Part A: Applied Science and Manufacturing\[J\], 2022, 158: 106981. \[54\]張冬冬.內(nèi)生TiCx顆粒形貌、尺寸控制及其對(duì)Cu基復(fù)合材料組織和性能的影響\[D\]. 長(zhǎng)春: 吉林大學(xué), 2018. ZHANG D D. Morphology Modification of in�瞫itu TiCx Particles and the Effects on Microstructure and Mechanical Properties of Cu Matrix Composite\[D\]. Changchun: Jilin University, 2018. \[55\]于敬宇, 李玉龍, 周宏霞, 等. 復(fù)合材料學(xué)報(bào)\[J\], 2005, 22(5): 31-38. YU J Y, LI Y L, ZHOU H X, et al. Journal of Composite Materials\[J\], 2005, 22(5): 31-38. \[56\]傅鑄杰. 納米金剛石原位自生制備TiC/Ti復(fù)合材料及其性能研究\[D\]. 北京: 北京理工大學(xué), 2016. FU Z J. Microstructure and Mechanical Properties of in�瞫itu TiC Reinforced Titanium Matrix Composites Prepared by Spark Plasma Sintering of Ti�睳anodiamond System\[D\]. Beijing: Beijing Institute of Technology, 2016. \[57\]HUANG L J, GENG L, LI A B, et al. Scripta Materialia\[J\], 2009, 60(11): 996-999. \[58\]WONG J C, PARAMSONTHY M, GUPTA M, et al. Composites Science and Technology\[J\], 2009, 69(3/4): 438-444. \[59\]ZHANG X, WU K, NI Y, et al. Nature Communications\[J\], 2022, 13: 7719. \[60\]LIU L, LI Y K, ZHANG H M, et al. Composites Part A: Applied Science and Manufacturing\[J\], 2022, 156: 106892. \[61\]WANG H, ZHANG H M, CHENG X W, et al. Materials Science and Engineering: A\[J\], 2022, 854: 143536. \[62\]歐陽(yáng)文博, 任利娜, 黃先明, 等. 鈦工業(yè)進(jìn)展\[J\], 2022, 39(4): 25-29. OUYANG W B, REN L N, HUANG X M, et al. Titanium Industry Progress\[J\], 2022, 39(4): 25-29. \[63\]GUAN R, WANG Y, ZHENG S, et al. Materials Science and Engineering: A\[J\], 2019, 754: 437-446. \[64\]GE Y X, ZHANG H M, CHEN X W, et al. Journal of Alloys and Compounds\[J\], 2021, 893: 162240. \[65\]MU X N, CAI H N, ZHANG H M, et al. Carbon\[J\], 2018, 137: 146-155. \[66\]DONG L L, ZHANG W, FU Y Q, et al. Carbon\[J\], 2021, 184: 583-595. \[67\]DONG L L, ZHANG W, FU Y Q, et al. ACS Applied Materials & Interfaces\[J\], 2021, 13: 43197-43208. \[68\]YAN Q, CHEN B, YE W T, et al. ACS Applied Materials & Interfaces\[J\], 2022, 14: 27118-27129. \[69\]MU X N, ZHANG H M, CAI H N, et al. Materials Science and Engineering: A\[J\], 2017,687: 164-174. \[70\]ZHANG F M, WANG J, LIU T F, et al. Materials & Design\[J\], 2020, 186: 108330. \[71\]YAN Q, CHEN B, CAO L, et al. Journal of Materials Science & Technology\[J\], 2022, 96: 85-93. \[72\]REN W J, LIU M B, ZHANG W, et al. Journal of Alloys and Compounds\[J\], 2022, 897: 163210. \[73\]WANG Y M, ZHU M, DONG L L, et al. Journal of Alloys and Compounds\[J\], 2023, 947: 169557. \[74\]徐嘉. 碳/TC11基復(fù)合材料的組織與力學(xué)性能研究\[D\]. 西安: 西安石油大學(xué), 2022. XU J. Microstructure and Mechanical Properties of Carbon/TC11 Matrix Composites\[D\]. Xi�餫n: Xi�餫n Shiyou University, 2022. \[75\]SHI W D, YAN Q, SHEN J H, et al. Materials Science and Engineering: A\[J\], 2022, 852: 143723. \[76\]LU J W, DONG L L, LIU Y, et al. Composites Part A: Applied Science and Manufacturing\[J\], 2020, 136: 105971. \[77\]SHI W D, LU S Y, SHEN J H, et al. Materials Science and Engineering: A\[J\], 2022, 830: 142321. \[78\]LABUSCH R. Physica Status Solidi(B)\[J\], 1970, 41: 659-669. \[79\]XIONG N, BAO R, YI J H, et al. Journal of Alloys and Compounds\[J\], 2019, 770: 204-213. \[80\]DONG L L, XIAO B, JIN L H, et al. Ceramics International\[J\], 2019, 45: 19370-19379. \[81\]DONG L L, FU Y Q, LIU Y, et al. Carbon\[J\], 2021, 173: 41-53. \[82\]ZHANG Z, CHEN D. Scripta Materialia\[J\], 2006, 54: 1321-1326. \[83\]NARDONE V C, PREWO K M. Scripta Materialia\[J\], 1986, 20(1): 43-48. \[84\]WANG M, ZHAO Y, WANG L D, et al. Carbon\[J\], 2018, 139: 954-963. \[85\]HUANG S R, WU H, ZHU H G, et al. Intermetallics\[J\], 2022, 148: 107639. \[86\]SHI W D, YAN Q, SHEN J H, et al. Composites Part A: Applied Science and Manufacturing\[J\], 2022, 160: 107055. \[87\]CHU K, WANG F, LI Y B, et al. Carbon\[J\], 2018, 133: 127-139. \[88\]ARSENAULT R J, SHI N. MaterIals Science and Engineering\[J\], 1989, 81: 175-187.