TY - JOUR
T1 - Unconventional localization prior to wrinkles and controllable surface patterns of film/substrate bilayers through patterned cavities
AU - LIAO, Xiangbiao
AU - CHEN, Youlong
AU - NAGAKURA, Takumi
AU - ZHU, Liangliang
AU - LI, Mingjia
AU - SHI, Xiaoyang
AU - YONEZU, Akio
AU - XIAO, Hang
AU - CHEN, Xi
N1 - X.C. acknowledges the support from the National Natural Science Foundation of China (11172231 and 11372241), ARPA-E, United States (DE-AR0000396) and AFOSR, United States (FA9550-12-1-0159); the work is supported by Yonghong Zhang Family Center for Advanced Materials for Energy and Environment, China; X.L., L.Z. and H.X. acknowledge the China Scholarship Council for the financial support.
PY - 2018/11
Y1 - 2018/11
N2 - Wrinkle formation followed by sharp strain localization is commonly observed in compressed stiff film/soft substrate systems. However, cavities or defects beneath the film may directly trigger the formation of local ridges and then folding configurations at a relatively small compressive strain, and a mixture of wrinkles and folds upon further compression. The morphological transition is different than those of defect-free substrates. Numerical simulations of continuously compressed bilayer with pre-patterned cavities are carried out to elucidate the transition mechanism of surface patterns. Parallel experiments of cavities-patterned bilayer prototypes by 3D-printing are also performed to validate the findings in simulations. A rich diversity of periodic surface topologies, including overall spreading waves, localizations, saw-like and co-existing features of folds and wrinkles can be obtained by varying the diameter, depth and spacing of cavities, which provides a potential approach to engineer various surface patterns for applications. © 2018 Elsevier Ltd
AB - Wrinkle formation followed by sharp strain localization is commonly observed in compressed stiff film/soft substrate systems. However, cavities or defects beneath the film may directly trigger the formation of local ridges and then folding configurations at a relatively small compressive strain, and a mixture of wrinkles and folds upon further compression. The morphological transition is different than those of defect-free substrates. Numerical simulations of continuously compressed bilayer with pre-patterned cavities are carried out to elucidate the transition mechanism of surface patterns. Parallel experiments of cavities-patterned bilayer prototypes by 3D-printing are also performed to validate the findings in simulations. A rich diversity of periodic surface topologies, including overall spreading waves, localizations, saw-like and co-existing features of folds and wrinkles can be obtained by varying the diameter, depth and spacing of cavities, which provides a potential approach to engineer various surface patterns for applications. © 2018 Elsevier Ltd
UR - http://www.scopus.com/inward/record.url?scp=85056559423&partnerID=8YFLogxK
U2 - 10.1016/j.eml.2018.10.009
DO - 10.1016/j.eml.2018.10.009
M3 - Journal Article (refereed)
SN - 2352-4316
VL - 25
SP - 66
EP - 70
JO - Extreme Mechanics Letters
JF - Extreme Mechanics Letters
ER -