Ferrofluid

Ferrofluid on glass, with a neodymium magnet underneath
Steve Papell invented ferrofluid for NASA in 1963

Ferrofluid is a liquid that is attracted to the poles of a magnet. It is a colloidal liquid made of nanoscale ferromagnetic or ferrimagnetic particles suspended in a carrier fluid (usually an organic solvent or water).[1] Each magnetic particle is thoroughly coated with a surfactant to inhibit clumping. Large ferromagnetic particles can be ripped out of the homogeneous colloidal mixture, forming a separate clump of magnetic dust when exposed to strong magnetic fields. The magnetic attraction of tiny nanoparticles is weak enough that the surfactant's Van der Waals force is sufficient to prevent magnetic clumping or agglomeration. Ferrofluids usually do not retain magnetization in the absence of an externally applied field and thus are often classified as "superparamagnets" rather than ferromagnets.[2]

In contrast to ferrofluids, magnetorheological fluids (MR fluids) are magnetic fluids with larger particles. That is, a ferrofluid contains primarily nanoparticles, while an MR fluid contains primarily micrometre-scale particles. The particles in a ferrofluid are suspended by Brownian motion and generally will not settle under normal conditions, while particles in an MR fluid are too heavy to be suspended by Brownian motion. Particles in an MR fluid will therefore settle over time because of the inherent density difference between the particles and their carrier fluid. As a result, ferrofluids and MR fluids have very different applications.

A process for making a ferrofluid was invented in 1963 by NASA's Steve Papell to create liquid rocket fuel that could be drawn toward a fuel pump in a weightless environment by applying a magnetic field.[3] The name ferrofluid was introduced, the process improved, more highly magnetic liquids synthesized, additional carrier liquids discovered, and the physical chemistry elucidated by R. E. Rosensweig and colleagues. In addition Rosensweig evolved a new branch of fluid mechanics termed ferrohydrodynamics which sparked further theoretical research on intriguing physical phenomena in ferrofluids.[4][5][6][7] In 2019, researchers at the University of Massachusetts and Beijing University of Chemical Technology succeeded in creating a permanently magnetic ferrofluid which retains its magnetism when the external magnetic field is removed. The researchers also found that the droplet's magnetic properties were preserved even if the shape was physically changed or it was divided.[8]

  1. ^ "Ferrofluid Product". Ferrofluid.com. Retrieved 2023-10-29.
  2. ^ Voit, W.; Kim, D. K.; Zapka, W.; Muhammed, M.; Rao, K. V. (21 March 2011). "Magnetic behavior of coated superparamagnetic iron oxide nanoparticles in ferrofluids". MRS Proceedings. 676. doi:10.1557/PROC-676-Y7.8.
  3. ^ US Patent 3215572 
  4. ^ Rosensweig, R.E. (1997), Ferrohydrodynamics, Dover Books on Physics, Courier Corporation, ISBN 9780486678344
  5. ^ Shliomis, Mark I. (2001), "Ferrohydrodynamics: Testing a third magnetization equation", Physical Review, 64 (6): 060501, arXiv:cond-mat/0106415, Bibcode:2001PhRvE..64f0501S, doi:10.1103/PhysRevE.64.060501, PMID 11736163, S2CID 37161240
  6. ^ Gollwitzer, Christian; Krekhova, Marina; Lattermann, Günter; Rehberg, Ingo; Richter, Reinhard (2009), "Surface instabilities and magnetic soft matter", Soft Matter, 5 (10): 2093, arXiv:0811.1526, Bibcode:2009SMat....5.2093G, doi:10.1039/b820090d, S2CID 17537054
  7. ^ Singh, Chamkor; Das, Arup K.; Das, Prasanta K. (2016), "Flow restrictive and shear reducing effect of magnetization relaxation in ferrofluid cavity flow", Physics of Fluids, 28 (8): 087103, Bibcode:2016PhFl...28h7103S, doi:10.1063/1.4960085
  8. ^ Lawrence Berkeley National Laboratory (July 18, 2019). "New laws of attraction: Scientists print magnetic liquid droplets". phys.org. Retrieved 2019-07-19.

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