Chu K.-CTsao H.-KSheng Y.-J.YU-JANE SHENG2022-03-222022-03-22202101677322https://www.scopus.com/inward/record.uri?eid=2-s2.0-85113183365&doi=10.1016%2fj.molliq.2021.117270&partnerID=40&md5=c1367662a5c2b0ab4a3e1eef38c5241ahttps://scholars.lib.ntu.edu.tw/handle/123456789/598292The wetting behavior of nanodroplets deposited on hydrophilic textured surfaces with discontinuous and continuous grooves was investigated by many-body dissipative particle dynamics. For surfaces with discontinuous grooves, the apparent contact angle (θa) can be described by the Wenzel model with an effective area ratio. However, for surfaces with continuous grooves, θa of nanodroplets depends on roughness topology, and spontaneous spreading of nanodroplets can take place even for partially wetting surfaces (θY > 0). That is, the partial-to-total wetting transition can occur on hydrophilic surfaces as surface textures change from discontinuous to continuous grooves. The dynamics of the spreading can be characterized by the apparent radius and groove radius (Rg). While the former is time-invariant at early stage, the latter follows the power law Rg ~ t1/4. This spreading of nanodroplets along continuous grooves can be explained from the synergy of spontaneous imbibition into continuous grooves, arrest by sharp edges, and capillary condensation for resuming the flow. ? 2021Capillary condensationImbibitionMany-body dissipative particle dynamicsSpontaneous spreadingTextured surfaceTotal wettingCondensationContact angleHydrophilicityTexturesWettingHydrophilicsMany bodyMany-body dissipative particle dynamicNano-dropletsWetting behaviorDynamics[SDGs]SDG6journal article10.1016/j.molliq.2021.1172702-s2.0-85113183365