Origami Inspired Self-assembly of Patterned and Reconfigurable Particles

There are numerous techniques such as photolithography, electron-beam lithography and soft-lithography that can be used to precisely pattern two dimensional (2D) structures. These technologies are mature, offer high precision and many of them can be implemented in a high-throughput manner. We leverage the advantages of planar lithography and combine them with self-folding methods1-20 wherein physical forces derived from surface tension or residual stress, are used to curve or fold planar structures into three dimensional (3D) structures. In doing so, we make it possible to mass produce precisely patterned static and reconfigurable particles that are challenging to synthesize. In this paper, we detail visualized experimental protocols to create patterned particles, notably, (a) permanently bonded, hollow, polyhedra that self-assemble and self-seal due to the minimization of surface energy of liquefied hinges21-23 and (b) grippers that self-fold due to residual stress powered hinges24,25. The specific protocol described can be used to create particles with overall sizes ranging from the micrometer to the centimeter length scales. Further, arbitrary patterns can be defined on the surfaces of the particles of importance in colloidal science, electronics, optics and medicine. More generally, the concept of self-assembling mechanically rigid particles with self-sealing hinges is applicable, with some process modifications, to the creation of particles at even smaller, 100 nm length scales22, 26 and with a range of materials including metals21, semiconductors9 and polymers27. With respect to residual stress powered actuation of reconfigurable grasping devices, our specific protocol utilizes chromium hinges of relevance to devices with sizes ranging from 100 μm to 2.5 mm. However, more generally, the concept of such tether-free residual stress powered actuation can be used with alternate high-stress materials such as heteroepitaxially deposited semiconductor films5,7 to possibly create even smaller nanoscale grasping devices.

[1]  D. Gracias,et al.  Surface tension-driven self-folding polyhedra. , 2007, Langmuir : the ACS journal of surfaces and colloids.

[2]  G. Stemme,et al.  New small radius joints based on thermal shrinkage of polyimide in V-grooves for robust self-assembly 3D microstructures , 1998 .

[3]  R. Syms Equilibrium of hinged and hingeless structures rotated using surface tension forces , 1995 .

[4]  Jeong-Hyun Cho,et al.  Self-assembly of lithographically patterned nanoparticles. , 2009, Nano letters.

[5]  D. Gracias,et al.  Photolithographically patterned smart hydrogel based bilayer actuators , 2010 .

[6]  M. Jamal,et al.  Self-folding immunoprotective cell encapsulation devices. , 2011, Nanomedicine : nanotechnology, biology, and medicine.

[7]  Evin Gultepe,et al.  Self-folding devices and materials for biomedical applications. , 2012, Trends in biotechnology.

[8]  E. Yeatman,et al.  Self-assembly of three-dimensional microstructures using rotation by surface tension forces , 1993 .

[9]  Yung-Cheng Lee,et al.  Modeling for solder self-assembled MEMS , 1998, Photonics West.

[10]  David H Gracias,et al.  Reversible Actuation of Microstructures by Surface‐Chemical Modification of Thin‐Film Bilayers , 2010, Advanced materials.

[11]  Paul R. Young,et al.  Fabrication, RF characteristics and mechanical stability of self-assembled 3D microwave inductors , 2002 .

[12]  G. Whitesides,et al.  Fabrication of Micrometer‐Scale, Patterned Polyhedra by Self‐Assembly , 2002 .

[13]  Henry I. Smith,et al.  Membrane folding to achieve three-dimensional nanostructures: Nanopatterned silicon nitride folded with stressed chromium hinges , 2006 .

[14]  David H Gracias,et al.  Algorithmic design of self-folding polyhedra , 2011, Proceedings of the National Academy of Sciences.

[15]  R. Syms Rotational self-assembly of complex microstructures by the surface tension of glass , 1998 .

[16]  David H Gracias,et al.  Thin film stress driven self-folding of microstructured containers. , 2008, Small.

[17]  David H Gracias,et al.  Three-dimensional fabrication at small size scales. , 2010, Small.

[18]  M. A. Putyato,et al.  Free-standing and overgrown InGaAs/GaAs nanotubes, nanohelices and their arrays , 2000 .

[19]  Victor M. Bright,et al.  Solder self-assembly for three-dimensional microelectromechanical systems , 1999 .

[20]  George M. Whitesides,et al.  Surface tension-powered self-assembly of microstructures - the state-of-the-art , 2003 .

[21]  V.M. Bright,et al.  Solder self-assembled micro axial flow fan driven by a scratch drive actuator rotary motor , 2001, Technical Digest. MEMS 2001. 14th IEEE International Conference on Micro Electro Mechanical Systems (Cat. No.01CH37090).

[22]  O. Schmidt,et al.  Nanotechnology: Thin solid films roll up into nanotubes , 2001, Nature.

[23]  David H Gracias,et al.  Three-dimensional chemical patterns for cellular self-organization. , 2011, Angewandte Chemie.

[24]  M. Jamal,et al.  Enzymatically triggered actuation of miniaturized tools. , 2010, Journal of the American Chemical Society.

[25]  M. Wu,et al.  A scanning micromirror with angular comb drive actuation , 2002, Technical Digest. MEMS 2002 IEEE International Conference. Fifteenth IEEE International Conference on Micro Electro Mechanical Systems (Cat. No.02CH37266).

[26]  Jeong-Hyun Cho,et al.  Three dimensional nanofabrication using surface forces. , 2010, Langmuir : the ACS journal of surfaces and colloids.

[27]  G. P. Nikishkov,et al.  Curvature estimation for multilayer hinged structures with initial strains , 2003 .

[28]  Samuel Sanchez,et al.  Fabrication and applications of large arrays of multifunctional rolled-up SiO/SiO2 microtubes , 2012 .

[29]  E. Smela,et al.  Controlled Folding of Micrometer-Size Structures , 1995, Science.

[30]  Valeriy Luchnikov,et al.  Self‐Rolled Polymer and Composite Polymer/Metal Micro‐ and Nanotubes with Patterned Inner Walls , 2005 .

[31]  Hongyan He,et al.  An oral delivery device based on self-folding hydrogels. , 2006, Journal of controlled release : official journal of the Controlled Release Society.

[32]  T. Aida,et al.  Self-Assembly of Microstage Using Micro-Origami Technique on GaAs , 2002 .

[33]  G. M. Whitesides,et al.  Templated Self‐Assembly: Formation of Folded Structures by Relaxation of Pre‐stressed, Planar Tapes , 2005 .

[34]  Kristofer S. J. Pister,et al.  Design, fabrication and test of self-assembled optical corner cube reflectors , 2005 .

[35]  David H. Gracias,et al.  Compactness Determines the Success of Cube and Octahedron Self-Assembly , 2009, PloS one.

[36]  David H Gracias,et al.  Tetherless thermobiochemically actuated microgrippers , 2009, Proceedings of the National Academy of Sciences.

[37]  M. Jamal,et al.  Differentially photo-crosslinked polymers enable self-assembling microfluidics. , 2011, Nature communications.

[38]  K. Kubota,et al.  Strain-driven self-positioning of micromachined structures , 2001 .

[39]  M. Jamal,et al.  Self-folding micropatterned polymeric containers , 2011, Biomedical microdevices.

[40]  Barjor Gimi,et al.  Self-Assembled Three Dimensional Radio Frequency (RF) Shielded Containers for Cell Encapsulation , 2005, Biomedical microdevices.

[41]  Babak Ziaie,et al.  A self-assembled 3D microelectrode array , 2010 .

[42]  Leonid Ionov,et al.  Soft microorigami: self-folding polymer films , 2011 .