In　a　hypergravity　environment,　the　complex　stress　conditions　and　the　change　in　gravity　field　intensity　will　significantly　affect　the　interaction　force　inside　solid-　and　liquid-phase　materials.　In　particular,　the　driving　force　for　the　relative　motion　of　the　phase　material,　the　interphase　contact　interaction,　and　the　stress　gradient　are　enhanced,　which　creates　a　nonlinear　effect　on　the　movement　mode　of　the　phase　material,　resulting　in　a　change　in　the　material＇s　behavior.　These　changes　include　increased　stress　and　contact　interactions;　accelerated　phase　separation;　changes　in　stress　distribution;　shear　force　and　phase　interface　renewal;　enhanced　interphase　mass　transfer　and　molecular　mixing;　and　increased　volume　mass　transfer　and　heat　transfer　coefficients.　These　phenomena　have　significant　effects　on　the　synthesis,　structural　evolution,　and　properties　of　materials　in　different　phases.　In　this　paper,　the　basic　concepts　of　hypergravity　and　the　general　rules　of　the　effects　of　hypergravity　on　the　synthesis,　microstructure　evolution,　and　properties　of　materials　are　reviewed.　Based　on　the　development　of　hypergravity　equipment　and　characterization　methods,　this　review　is　expected　to　broaden　the　theoretical　framework　of　material　synthesis　and　mechanical　property　control　under　hypergravity.　It　provides　theoretical　reference　for　the　development　of　high-performance　materials　under　extreme　conditions,　as　well　as　new　insights　and　methods　for　research　and　application　in　related　fields.