Cosserat curve model for superelasticity of helices

Superelasticity behavior of helices has been the focus of recent research in micro-/nano-engineering, while the traditional Kirchhoff rod model restricts itself in the bending and torsion conditions. With the aid of the concept of a Cosserat curve, a novel theoretical basis has been established for statics and dynamics of helices with essential extension and shear, which is able to quantitatively analyze the superelastic mechanical properties. Except for a good agreement with the experimental observation, numerical solutions have shown that we cannot only predict two important properties of the superelasticity characteristics: the breaking force and the stretch of the coil wire under the axial loading, but also precisely describe and explain the Hooke's constant and torque in the entire stretching and breaking processes. The present work has provided useful information for the future experimental investigation on superelasticity as well as its application in meta-/quantum devices.

[1]  A. B. Whitman,et al.  An exact solution in a nonlinear theory of rods , 1974 .

[2]  J. Rogers,et al.  Structural forms of single crystal semiconductor nanoribbons for high-performance stretchable electronics , 2007 .

[3]  G. M.,et al.  A Treatise on the Mathematical Theory of Elasticity , 1906, Nature.

[4]  Guigen Zhang,et al.  Mechanical characteristics of nanoscale springs , 2004 .

[5]  T Schlick,et al.  Modeling superhelical DNA: recent analytical and dynamic approaches. , 1995, Current opinion in structural biology.

[6]  Langer,et al.  Nonlinear dynamics of stiff polymers. , 1995, Physical review letters.

[7]  M. Tabor,et al.  Spontaneous Helix Hand Reversal and Tendril Perversion in Climbing Plants , 1998 .

[8]  Yong Ding,et al.  Conversion of Zinc Oxide Nanobelts into Superlattice-Structured Nanohelices , 2005, Science.

[9]  Brian A. Korgel,et al.  Nanosprings Take Shape , 2005, Science.

[10]  P. Lai,et al.  Elasticity and stability of a helical filament. , 2005, Physical review. E, Statistical, nonlinear, and soft matter physics.

[11]  W. A. Fate High‐temperature elastic moduli of polycrystalline silicon nitride , 1975 .

[12]  W. Olson,et al.  Simulating DNA at low resolution. , 1996, Current opinion in structural biology.

[13]  Yajie Xu,et al.  Superelastic and Spring Properties of Si3N4 Microcoils , 2008 .

[14]  A. Love A treatise on the mathematical theory of elasticity , 1892 .

[15]  Alain Goriely,et al.  Tendril Perversion in Intrinsically Curved Rods , 2002, J. Nonlinear Sci..

[16]  Rodney S. Ruoff,et al.  Mechanics of a Carbon Nanocoil , 2003 .

[17]  E. Cosserat,et al.  Théorie des Corps déformables , 1909, Nature.

[18]  Wenjie Mai,et al.  Superelasticity and nanofracture mechanics of ZnO nanohelices. , 2006, Nano letters.

[19]  J. R. Hutchinson Shear coefficients for Timoshenko beam theory , 2001 .

[20]  D. Galvão,et al.  Mechanical properties of nanosprings. , 2004, Physical review letters.