American Physical Society
APS SitesAPSJournalsPhysicsCentralPhysicsFocus
 
Become a Member | Contact Us
  • Publications
    • Journals of the American Physical Society
    • APS News
    • Physics
    • Physics Today
    • Physical Review Focus
    • Capitol Hill Quarterly
    • Other APS Publications
    • Reciprocal Society Newsletters
  • Meetings & Events
    • March Meeting
    • April Meeting
    • Meeting Calendar
    • Abstract Submission
    • Archives of the Bulletin of the American Physical Society
    • Policies & Guidelines
    • Archived Multimedia Presentations
  • Programs
    • Education
    • International Affairs
    • Physics for All
    • Women in Physics
    • Minorities in Physics
    • Prizes, Awards & Fellowships
  • Membership
    • Join APS
    • Renew Membership
    • Member Directory
    • My Member Profile
    • Member Services
    • APS Units
  • Policy & Advocacy
    • Issues
    • Reports & Studies
    • APS Statements
    • Advocacy Tools
    • Advocacy Resources
    • Fellowships & Fellows
    • Contact APS Public Affairs
  • Careers In Physics
    • Physics Job Opportunities
    • Physics Students
    • Tools for Educators
    • Career Guidance
  • About APS
    • Mission Statement
    • Society Governance
    • Society History
    • Support APS
    • APS Jobs
    • Contact Us
    • Visit Us
About APS
  • Mission Statement
  • Society Governance
  • Society History
  • Support APS
  • APS Jobs
  • Contact Us
  • Visit Us

 
Home   |   About APS   |   Images in Physics   |   Physics Images Archive   |   Spontaneous Separation of Sand Grains

Spontaneous Separation of Sand Grains

Email | Print

In 1867, Lord Kelvin described an experiment in which two streams of water droplets were connected so that each stream amplified the charge on the second stream [W. Thomson, Proc. R. Soc. London 16, 67 (1867).].

Amit Mehrotra, Fernando J. Muzzio, and Troy Shinbrot of the Department of Chemical & Biochemical Engineering, Rutgers University, present here a complementary effect in flowing grains that spontaneously separates similar and well-mixed grains into two charged streams of demixed grains.

The grains are positively charged. While they sit on a surface, the mutual repulsion of the grains can propel some of them as high as 2 meters into the air. This effect of spontaneous separation has important consequences for industrial and natural processes.

Read more in American Institute of Physics’ Physics News Update.

Abstract of the paper from: Phys. Rev. Lett. 99, 058001 (published 31July 2007)

Electrostatic interactions in sand

Image credit: Troy Shinbrot, , Keirnan LaMarche and Ben Glasser (all APS members) from a preceding, similar experiment in electrostatic interaction.

Home | APS Jobs | Media Center | Privacy | Site Map
    © 2009 American Physical Society