Direct observation of crystal nucleation and growth in a quasi-two-dimensional nonvibrating granular system
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We study a quasi-two-dimensional macroscopic system of magnetic spherical particles settled on a shallow concave dish under a temporally oscillating magnetic field. The system reaches a stationary state where the energy losses from collisions and friction with the concave dish surface are compensated by the continuous energy input coming from the oscillating magnetic field. Random particle motions show some similarities with the motions of atoms and molecules in a glass or a crystal-forming fluid. Because of the curvature of the surface, particles experience an additional force toward the center of the concave dish. When decreasing the magnetic field, the effective temperature is decreased and diffusive particle motion slows. For slow cooling rates we observe crystallization, where the particles organize into a hexagonal lattice. We study the birth of the crystalline nucleus and the subsequent growth of the crystal. Our observations support nonclassical theories of crystal formation. Initially a dense amorphous aggregate of particles forms, and then in a second stage this aggregate rearranges internally to form the crystalline nucleus. As the aggregate grows, the crystal grows in its interior. After a certain size, all the aggregated particles are part of the crystal and after that crystal growth follows the classical theory for crystal growth. ©2021 American Physical Society
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Crystal growth; Crystals; Energy dissipation; Magnetic fields; Crystal nucleation and growths; Crystalline nuclei; Direct observations; Granular system; Macroscopic systems; Oscillating magnetic fields; Particle motions; Spherical particle; Stationary state; Two-dimensional; Aggregates; article; cooling; crystallization; friction; hexagonal crystal; magnetic field; motion
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