The Mechanics of Rocking Stones: Equilibria on Separated Scales

Rocking stones, balanced in counter-intuitive positions, have always intrigued geologists. In our paper, we explain this phenomenon based on high-precision scans of pebbles which exhibit similar behavior. We construct their convex hull and the heteroclinic graph carrying their equilibrium points. By systematic simplification of the arising Morse–Smale complex in a one-parameter process, we demonstrate that equilibria occur typically in highly localized groups (flocks), the number of the latter being reliably observed and determined by hand experiments. Both local and global (micro and macro) equilibria can be either stable or unstable. Most commonly, rocks and pebbles are balanced on stable local equilibria belonging to stable flocks. However, it is possible to balance a convex body on a stable local equilibrium belonging to an unstable flock and this is the intriguing mechanical scenario corresponding to rocking stones. Since outside observers can only reliably perceive flocks, the last described situation will appear counter-intuitive. A comparison between computer experiments and hand experiments reveals that the latter are consistent, that is, the flocks can be reliably counted and the pebble classification system proposed in our previous work is robustly applicable. We also find an interesting logarithmic relationship between the flatness of pebbles and the average number of global equilibrium points, indicating a close relationship between classical shape categories and the new classification system.

[1]  Bernd Hamann,et al.  Segmenting molecular surfaces , 2006, Comput. Aided Geom. Des..

[2]  G. Heritage,et al.  Towards a protocol for laser scanning in fluvial geomorphology , 2007 .

[3]  Valerio Pascucci,et al.  Morse-smale complexes for piecewise linear 3-manifolds , 2003, SCG '03.

[4]  V. Arnold,et al.  Ordinary Differential Equations , 1973 .

[5]  W. Illenberger,et al.  Pebble shape (and size , 1991 .

[6]  Wei Xiong,et al.  Use of a three‐dimensional laser scanner to digitally capture the topography of sand dunes in high spatial resolution , 2004 .

[7]  Andy Ruina,et al.  Static equilibria of planar, rigid bodies: is there anything new? , 1994 .

[8]  R. MacMillan,et al.  Automated analysis and classification of landforms using high-resolution digital elevation data: applications and issues , 2003 .

[9]  L. C. King,et al.  The Problem of Tors , 1955 .

[10]  R. Folk,et al.  Pebbles in the Lower Colorado River, Texas a Study in Particle Morphogenesis , 1958, The Journal of Geology.

[11]  James N. Brune,et al.  DATING PRECARIOUSLY BALANCED ROCKS IN SEISMICALLY ACTIVE PARTS OF CALIFORNIA AND NEVADA , 1998 .

[12]  Frédéric Chazal,et al.  Molecular shape analysis based upon the morse-smale complex and the connolly function , 2002, SCG '03.

[13]  Herbert Edelsbrunner,et al.  Hierarchical Morse—Smale Complexes for Piecewise Linear 2-Manifolds , 2003, Discret. Comput. Geom..

[14]  James N. Brune,et al.  Methodology for Obtaining Constraints on Ground Motion from Precariously Balanced Rocks , 2004 .

[15]  Herbert Edelsbrunner,et al.  Extreme Elevation on a 2-Manifold , 2006, Discret. Comput. Geom..

[16]  Zsolt Lángi,et al.  On the equilibria of finely discretized curves and surfaces , 2011, 1106.0626.

[17]  James N. Brune,et al.  Band of precariously balanced rocks between the Elsinore and San Jacinto, California, fault zones: Constraints on ground motion for large earthquakes , 2006 .

[18]  R. Forman Morse Theory for Cell Complexes , 1998 .

[19]  Bernd Hamann,et al.  A Multi-Resolution Data Structure for 2-Dimensional Morse Functions , 2003, IEEE Visualization.

[20]  G. Domokos,et al.  A new classification system for pebble and crystal shapes based on static equilibrium points , 2010 .

[21]  Theodor Zingg,et al.  Beitrag zur Schotteranalyse , 1935 .

[22]  B. Hamann,et al.  A multi-resolution data structure for two-dimensional Morse-Smale functions , 2003, IEEE Visualization, 2003. VIS 2003..

[23]  P. Hartman Ordinary Differential Equations , 1965 .

[24]  H. Viles,et al.  Innovative applications of laser scanning and rapid prototype printing to rock breakdown experiments , 2008 .

[25]  Nicholas G. Midgley,et al.  Graphical representation of particle shape using triangular diagrams: an Excel spreadsheet method , 2000 .

[26]  Péter L. Várkonyi,et al.  Pebbles, Shapes, and Equilibria , 2009 .

[27]  J. Jennings The Problem of Tors , 1956 .

[28]  R. A. Neilson,et al.  THE ORIGIN OF GRANITE TORS ON DARTMOOR, DEVONSHIRE , 1962 .