High-performance　reinforcement　together　with　advanced　innovative　structure　design　has　been　attracting　much　attention　as　a　means　of　circumventing　the　conflict　between　toughness　and　hardness　or　strength　of　ceramic　matrix.　Herein,　we　developed　the　laminated　tungsten　carbide　(WC)　matrix　composite　reinforced　by　hybrid　one-dimensional　(1D)　carbon　nanotubes　(CNTs)　and　SiC　nanowire　(SiCnw)　as　well　as　two-dimensional　(2D)　graphene　(G),　with　a　striking　combination　of　high　hardness　(25.3　GPa),　high　fracture　toughness　(13.7　MPa　m1/2),　and　high　strength　(1,501.7　MPa),　exhibiting　superiority　in　mechanical　properties　compared　with　most　WC-based　materials,　such　as　WC-metal,　WC-intermetallic,　WC-carbide,　WC-oxide,　WC-nitride,　WC-whisker,　WC-CNT,　and　WC-graphene.　The　optimum　structure　was　determined　as　laminate　of　five　symmetrical　layers　with　thickness　ratio　of　golden　ratio　squared.　In　addition,　the　three-dimensional　(3D)　hybrid　G/CNT/SiCnw　demonstrated　a　strong　hierarchical　lamellar　interconnected　structure,　in　which　CNT　and　SiCnw　were　well　sandwiched　between　G　sheets,　synergistically　facilitating　the　enhancement　in　the　mechanical　properties　of　the　host　matrix.　This　present　investigation　shows　promising　future　in　achieving　state-of-the-art　multiscale　ceramic　composites　for　safety-critical　applications　as　in　the　transportation　and　aerospace.　©　2022　Elsevier　Ltd