Near-field scanning optical microscopic transient lens for carrier dynamics study in InGaN∕GaN

Okamoto, Koichi; Scherer, Axel; Kawakami, Yoichi

doi:10.1063/1.2105999

Cited by 39 publications

(20 citation statements)

References 24 publications

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“…Electroluminescence and photoluminescence ͑PL͒ SNOM studies of c-plane InGaN QWs have identified carrier localization and nonradiative recombination centers, [7][8][9] and revealed potential barriers around the extended defects. Scanning near field optical microscopy ͑SNOM͒, which provides subwavelength spatial resolution, is a more powerful technique for characterizing the carrier localization.…”

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confidence: 99%

Carrier localization in m-plane InGaN/GaN quantum wells probed by scanning near field optical spectroscopy

et al. 2010

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Articles you may be interested inDiscrimination of local radiative and nonradiative recombination processes in an InGaN/GaN single-quantumwell structure by a time-resolved multimode scanning near-field optical microscopy Scanning near field optical microscopy ͑SNOM͒ was applied to study the carrier localization in single InGaN/GaN quantum well structures grown on nonpolar m-plane GaN substrates. Dual localization potential consisting of hundreds of nanometers-to micrometer-size areas as well as smaller localization centers were identified from the SNOM scans and near field photoluminescence spectral widths. The localization areas were found to align along the ͓0001͔ direction, which was attributed to partial strain relaxation at the monolayer steps.

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confidence: 99%

Carrier localization in m-plane InGaN/GaN quantum wells probed by scanning near field optical spectroscopy

et al. 2010

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“…The lateral sizes of In-rich area are reported in a wide range from a few nm to hundreds of nm and they form a sort of Inrich quantum disks (Q-disks) or quantum dots (Q-dots) [13,14]. The volume of Q-disks (or Q-dots) are much smaller than the physical volume of a QW, namely V eff << V a .…”

Section: Carier Density N [Cmmentioning

confidence: 98%

“…Lots of experimental evidences have suggested the existence of In-rich areas in the active layer of the InGaN-based blue LED, which can act as localization centers of carriers and behave more like quantum disks (Q-disks) or quantum dots (Q-dots) with reduced density of states [13][14]. The existence of In-rich areas implies that the effective active volume is smaller than the nominal volume of QWs.…”

Section: Introductionmentioning

confidence: 99%

An efficiency droop model of the saturated radiative recombination rate and its verification by radiative and nonradiative carrier lifetime measurements in InGaN-based light emitting diodes

et al. 2011

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We have proposed an efficiency droop model which can comprehensively explain experimental IQE droop phenomena occurring at different temperatures, materials, and active structures. In our model, carriers are located and recombined both radiatively and nonradiatively inside randomly distributed In-rich areas of InGaN-based QWs and the IQE droop originates from the saturated radiative recombination rate and the monotonically increasing nonradiative recombination rate there. Due to small effective active volume and small density of states of In-rich areas, carrier density is rapidly increased even at low current density and the radiative recombination rate is easily saturated by different distributions of electrons and holes in the momentum k-space. A measurement method that can separately estimate the radiative and nonradiative carrier lifetimes just at room temperature is theoretically developed by analyzing the time-resolved photoluminescence (TRPL) response. The method is applied to a blue InGaN/GaN QW LED. The experimental results show that the radiative carrier lifetime increases and the nonradiative carrier lifetime saturates with increasing TRPL laser power, which is one of direct evidences validating our IQE droop model.

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“…NSOM is not only used to optically study the surface morphology, but has been successfully integrated with different spectroscopy techniques such as Raman (TERS) [3,4], photoluminescence [5], time resolved measurements [6], etc. It has been used to study a variety of materials, such as solid state quantum nanostructures [7,8], single molecules [9] or soft biological tissues [10,11].…”

Section: Introductionmentioning

confidence: 99%

Fabrication of a plasmonic nanocone on top of an AFM cantilever

Tanirah

Kern

Fleischer

2015

Microelectronic Engineering

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Near-field scanning optical microscopic transient lens for carrier dynamics study in InGaN∕GaN

Cited by 39 publications

References 24 publications

Carrier localization in m-plane InGaN/GaN quantum wells probed by scanning near field optical spectroscopy

Carrier localization in m-plane InGaN/GaN quantum wells probed by scanning near field optical spectroscopy

An efficiency droop model of the saturated radiative recombination rate and its verification by radiative and nonradiative carrier lifetime measurements in InGaN-based light emitting diodes

Fabrication of a plasmonic nanocone on top of an AFM cantilever

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