1. Quantum Size Effect Exponential Heat Capacity in 4 nm Natural Nickel Nanolattice
- Author
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Patel, Tarachand, Singh, Jaiveer, Samatham, Satya Sanmukharao, Venkateshwarlu, Dontula, Kaurav, Netram, Ganesan, Vedachalaiyer, and Okram, Gunadhor Singh
- Subjects
Condensed Matter - Mesoscale and Nanoscale Physics - Abstract
Quantum size effect-induced heat capacity of metal nanoparticles at low temperatures was predicted 79 years ago to be exponential. This, however, has not been reported until date. In defiance, we demonstrate here observation of exponentially decaying heat capacity, below 45.2 K, associated with quantum jumps, exceptionally in 4 nm naturally assembled hexagonal closed packed (hcp) lattice of nickel nanoparticles; high magnetic fields have negligible effect on these features. Magnetic susceptibilities in contrast reveal evolution of quantum size effects with decrease in particle size. They exhibit sharp rise below about 30 K and vestiges of saturations below 5 K. The former is explained by Curie-like characteristics of odd electrons while the latter tend towards the orthogonal even-like case. These characteristics, ascribed to the ensembles of Ni nanoparticles, will give a new direction in understanding this crucial thermodynamic phenome-non., Comment: 12 pages 9 figures
- Published
- 2016