Effect of embedded metal nanocrystals on the resistive switching characteristics in NiN-based resistive random access memory cells

The metal nanocrystals (NCs) embedded-NiN-based resistive random access memory cells are demonstrated using several metal NCs (i.e., Pt, Ni, and Ti) with different physical parameters in order to investigate the metal NC's dependence on resistive switching (RS) characteristics. First, depending...

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Veröffentlicht in:	Journal of applied physics 2014-03, Vol.115 (9)
Hauptverfasser:	Yun, Min Ju, Kim, Hee-Dong, Man Hong, Seok, Hyun Park, Ju, Su Jeon, Dong, Geun Kim, Tae
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied physics Computer memory CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY CORRELATIONS Dependence ELECTRIC CURRENTS ELECTRIC FIELDS ELECTRIC POTENTIAL ELECTRONEGATIVITY Nanocrystals NANOSCIENCE AND NANOTECHNOLOGY NANOSTRUCTURES NICKEL NICKEL NITRIDES Order parameters Physical properties PLATINUM POTENTIALS Random access memory Switching TITANIUM WORK FUNCTIONS
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creator	Yun, Min Ju Kim, Hee-Dong Man Hong, Seok Hyun Park, Ju Su Jeon, Dong Geun Kim, Tae
description	The metal nanocrystals (NCs) embedded-NiN-based resistive random access memory cells are demonstrated using several metal NCs (i.e., Pt, Ni, and Ti) with different physical parameters in order to investigate the metal NC's dependence on resistive switching (RS) characteristics. First, depending on the electronegativity of metal, the size of metal NCs is determined and this affects the operating current of memory cells. If metal NCs with high electronegativity are incorporated, the size of the NCs is reduced; hence, the operating current is reduced owing to the reduced density of the electric field around the metal NCs. Second, the potential wells are formed by the difference of work function between the metal NCs and active layer, and the barrier height of the potential wells affects the level of operating voltage as well as the conduction mechanism of metal NCs embedded memory cells. Therefore, by understanding these correlations between the active layer and embedded metal NCs, we can optimize the RS properties of metal NCs embedded memory cells as well as predict their conduction mechanisms.
doi_str_mv	10.1063/1.4867639
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First, depending on the electronegativity of metal, the size of metal NCs is determined and this affects the operating current of memory cells. If metal NCs with high electronegativity are incorporated, the size of the NCs is reduced; hence, the operating current is reduced owing to the reduced density of the electric field around the metal NCs. Second, the potential wells are formed by the difference of work function between the metal NCs and active layer, and the barrier height of the potential wells affects the level of operating voltage as well as the conduction mechanism of metal NCs embedded memory cells. Therefore, by understanding these correlations between the active layer and embedded metal NCs, we can optimize the RS properties of metal NCs embedded memory cells as well as predict their conduction mechanisms.</abstract><cop>Melville</cop><pub>American Institute of Physics</pub><doi>10.1063/1.4867639</doi></addata></record>
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subjects	Applied physics Computer memory CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY CORRELATIONS Dependence ELECTRIC CURRENTS ELECTRIC FIELDS ELECTRIC POTENTIAL ELECTRONEGATIVITY Nanocrystals NANOSCIENCE AND NANOTECHNOLOGY NANOSTRUCTURES NICKEL NICKEL NITRIDES Order parameters Physical properties PLATINUM POTENTIALS Random access memory Switching TITANIUM WORK FUNCTIONS
title	Effect of embedded metal nanocrystals on the resistive switching characteristics in NiN-based resistive random access memory cells
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