Electron energy distribution in Si/TiN and Si/Ru hybrid floating gates with hafnium oxide based insulators for charge trapping memory devices. Issue 2 (7th January 2016)

Record Type:: Journal Article
Title:: Electron energy distribution in Si/TiN and Si/Ru hybrid floating gates with hafnium oxide based insulators for charge trapping memory devices. Issue 2 (7th January 2016)
Main Title:: Electron energy distribution in Si/TiN and Si/Ru hybrid floating gates with hafnium oxide based insulators for charge trapping memory devices
Authors:: Cerbu, F.
Andreev, D. V.
Lisoni, J.
Breuil, L.
Afanas'ev, V. V.
Stesmans, A.
Houssa, M.
Abstract:: Abstract : Scaling the planar NAND flash cells to the 20 nm node and beyond mandates introduction of inter‐gate insulators with high dielectric constant ( κ ). However, because these insulators provide a smaller electron barrier at the interface with the poly‐Si floating gate, the program window and the retention properties of these scaled cells are jeopardized. To reduce the charge loss from the floating to the control gate, one may consider the introduction of a hybrid floating gate (HFG) structure comprised of poly‐Si and a high work function (WF) metal, e.g., TiN x ( x ∼ 1; WF ∼ 4.7 eV) or Ru (WF ∼ 5.3 eV). However, the very HFG concept is based on the assumption that electron trapping occurs inside the HFG stack rather than on traps present in the high‐ κ insulator. To examine this critical hypothesis, we analyzed the energy distribution of electrons trapped in flash cells with poly‐Si(2 nm)/TiN (6 nm)/Hf0.8 Al0.2 O x (19 nm, κ ∼ 15–19)/TiN x (10 nm) and Si(2 nm)/Ru (1 nm)/Hf0.8 Al0.2 O x (5 nm)/Al2 O3 (5 nm)/Hf0.8 Al0.2 O x (5 nm)/TiN x (10 nm) trapping gate stacks using the exhaustive photo‐depopulation spectroscopy. We found that trapped electron energy levels show a broad distribution (± 0.3 eV) centred at ∼3.2 eV below the oxide conduction band. The energy onset of electron de‐trapping at ∼2.8 eV matches the TiN x /HfO2 barrier height found from internal photoemission experiments, indicating that electrons are predominantly trapped inside the HFG.
Is Part Of:: Physica status solidi. Volume 213:Issue 2(2016:Feb.)
Journal:: Physica status solidi
Issue:: Volume 213:Issue 2(2016:Feb.)
Issue Display:: Volume 213, Issue 2 (2016)
Year:: 2016
Volume:: 213
Issue:: 2
Issue Sort Value:: 2016-0213-0002-0000
Page Start:: 265
Page End:: 269
Publication Date:: 2016-01-07
Subjects:: charge trapping -- energy barriers -- floating gates -- high‐k insulators -- photo‐depopulation spectroscopy -- Si/Ru -- Si/TiNX
Solid state physics -- Periodicals
Solids -- Industrial applications -- Periodicals
530.41
Journal URLs:: http://onlinelibrary.wiley.com/ ↗
DOI:: 10.1002/pssa.201532416 ↗
Languages:: English
ISSNs:: 1862-6300
Deposit Type:: Legaldeposit
View Content:: Available online (eLD content is only available in our Reading Rooms) ↗
Physical Locations:: British Library DSC - 6475.210000
British Library DSC - BLDSS-3PM
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Ingest File:: 876.xml