• Home
  • Browse News By Category
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?cat=Architecture
      Architecture
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?cat=Arts_and_Humanities
      Arts & Humanities
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?cat=Engineering
      Engineering
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?cat=Events
      Events
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?cat=Faculty_News
      Faculty News
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?cat=Health_and_Medicine
      Health & Medicine
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?cat=Research
      Research
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?cat=Science
      Science
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?cat=Social_Sciences
      Social Sciences
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?cat=Student_News
      Student News
  • Browse News By Year
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?year=2013
      2013
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?year=2012
      2012
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?year=2011
      2011
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?year=2010
      2010
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?year=2009
      2009
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?year=2008
      2008
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?year=2007
      2007
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?year=2006
      2006
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/index.cfm?year=2005
      2005
  • Calendar of Events
  • CCNY In The News
  • Spotlight on Faculty
  • Student Success
  • Webcasts
  • Additional Resources
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/mediacontacts.cfm
      Information for Journalists
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/factsheet.cfm
      Fact Sheet
    • /news/PHYSICISTS-AT-CCNY-DETERMINE-DENSITY-LIMIT-FOR-RANDOMLY-PACKED-SPHERICAL-MATERIALS.cfm /news/publications.cfm
      Publications and Media
  • Communications and Marketing
Share This
June 2, 2008

PHYSICISTS AT CCNY DETERMINE DENSITY LIMIT FOR RANDOMLY PACKED SPHERICAL MATERIALS

NEW YORK, June 2, 2008 – The problem of how many identical-sized spheres can be randomly packed into a container has challenged mathematicians for centuries.  A team of physicists at The City College of New York (CCNY) has come up with a solution that could have implications for everything from processing granular materials to shipping fruit.

Writing in the May 29 edition of “Nature,” they demonstrate that random packing of hard, i.e. non-crushable, spheres in three dimensions cannot exceed a density limit of 63.4 percent of the volume.  This upper limit is a consequence of a completely “jammed” state that occurs when the materials are at their lowest energy levels, i.e. as close to inert as possible.

“Theoretically, the jammed state would be achieved by lowering the temperature of the spheres to approach absolute zero, since this would cause them to contract,” explained Dr. Hernán Makse, CCNY Associate Professor of Physics and principal investigator.  “In real life, however, it is attained by shaking the materials.”

The findings have potential applications for the manufacture of pharmaceuticals and cosmetics, where powders have to be mixed to a homogenous consistency, he said.  Currently, manufacturers must rely on empirical data, i.e. trial and error, to establish their formulas.  Professor Makse said his goal is to develop a theory of powders that could enable manufacturers to more efficiently develop new products. 

Two of Professor Makse’s Ph.D. students, Chaoming Song and Ping Wang, collaborated with him on the investigation.  Mr. Song completed his degree requirements in 2007.

About The City College of New York

For more than 160 years, The City College of New York has provided low-cost, high-quality education for New Yorkers in a wide variety of disciplines.  Over 14,000 students pursue undergraduate and graduate degrees in the College of Liberal Arts and Sciences; The School of Architecture, Urban Design and Landscape Architecture (SAUDLA); The School of Education; The Grove School of Engineering, and The Sophie Davis School of Biomedical Education.  For additional information, visit www.ccny.cuny.edu.

« BACK TO NEWS