The mechanism of electrical annihilation of conductive paths and charge trapping in silicon-rich oxides

Morales–Sánchez, A.; Barreto, Jorge; Domı́nguez, Carlos; Aceves, M.; Luna-López, J. A.

doi:10.1088/0957-4484/20/4/045201

Cited by 24 publications

(34 citation statements)

References 18 publications

(56 reference statements)

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“…This behavior was observed by our group before in SRO ilms with Ro =30, and it was related to the creation and annihilation of preferential conductive paths generated possibly by adjacent stable Si-nps and unstable silicon nanoclusters (Si-ncls) through structural changes and by the possible creation of defects (breaking of Si-Si bonds) [70,79,80]. Indeed, a clear correlation between current jumps/drops and EL dots appearing/ disappearing on the LEC surface was observed [70,79,80]. This RS behavior is independent on the thermal annealing temperature [46].…”

Section: Silicon-rich Oxide (Sro)-lecssupporting

confidence: 54%

Luminescent Devices Based on Silicon-Rich Dielectric Materials

Cabañas-Tay¹,

Palacios-Huerta²,

Aceves-Mijares³

et al. 2016

Luminescence - An Outlook on the Phenomena and Their Applications

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Luminescent silicon-rich dielectric materials have been under intensive research due to their potential applications in optoelectronic devices. Silicon-rich nitride (SRN) and silicon-rich oxide (SRO) ilms have been mostly studied because of their high luminescence and compatibility with the silicon-based technology. In this chapter, the luminescent characteristics of SRN and SRO ilms deposited by low-pressure chemical vapor deposition are reviewed and discussed. SRN and SRO ilms, which exhibit the strongest photoluminescence (PL), were chosen to analyze their electrical and electroluminescent (EL) properties, including SRN/SRO bilayers. Light emiting capacitors (LECs) were fabricated with the SRN, SRO, and SRN/SRO ilms as the dielectric layer. SRN-LECs emit broad EL spectra where the maximum emission peak blueshifts when the polarity is changed. On the other hand, SRO-LECs with low silicon content (~39 at.%) exhibit a resistive switching (RS) behavior from a high conduction state to a low conduction state, which produce a long spectrum blueshift (~227 nm) between the EL and PL emission. When the silicon content increases, red emission is observed at both EL and PL spectra. The RS behavior is also observed in all SRN/SRO-LECs enhancing an intense ultraviolet EL. The carrier transport in all LECs is analyzed to understand their EL mechanism.

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Section: Silicon-rich Oxide (Sro)-lecssupporting

confidence: 54%

Luminescent Devices Based on Silicon-Rich Dielectric Materials

Cabañas-Tay¹,

Palacios-Huerta²,

Aceves-Mijares³

et al. 2016

Luminescence - An Outlook on the Phenomena and Their Applications

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“…At some point during the electrical stress, the current drops to a low leakage situation [16]. At the same time the luminescent dots disappear [17].…”

Section: Resultsmentioning

confidence: 98%

“…The LPCVD sample presents both kinds of leakage: as obtained devices show high leakage, which turns into low leakage after the application of an electrical stress. This behavior has been attributed to the annihilation of the preferential conductive paths [16].…”

Section: Discussionmentioning

confidence: 99%

Analysis of the electrical behavior of silicon rich silicon oxides

et al. 2012

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“…The high conduction states at low voltages have been related to the presence of conductive paths in the SiO x films, which connect the FTO gate to the Si substrate. The current drop can be explained as a result of the annihilation of such conductive paths [21]. As for RB applied, the current has a typical I-V behaviour, which is also present at a current lesser than that for FB.…”

Section: Discussionmentioning

confidence: 96%

“…Likewise, for virgin 2, current fluctuations are observed; the highest current is measured in a particular voltage V = 15 V due to a high conduction mechanism not well identified which is active at this particular voltage. Immediately after this voltage is exceeded, the current drops drastically to an intermediate conduction state, and then finally drops into a low conduction mechanism; for voltages above 22 V the current starts to increase again by Fowler-Nordheim tunnelling [21]. The high conduction states at low voltages have been related to the presence of conductive paths in the SiO x films, which connect the FTO gate to the Si substrate.…”

Section: Discussionmentioning

confidence: 99%