A theoretical investigation of the influence of gold nanosphere size on the decay and energy transfer rates and efficiencies of quantum emitters

Marocico, Cristian A.; Zhang, Xia; Bradley, A. Louise

doi:10.1063/1.4939206

Cited by 24 publications

(36 citation statements)

References 114 publications

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“…Research on colloidal plasmon-mediated ET systems has shown that plasmon coupling to the donor has a larger influence on the ET process, allowing for the acceptor to be placed further from the plasmonic component, thereby reducing the direct quenching of the acceptor [46,62]. Therefore the QW barrier thickness is another parameter that can be tuned to move from a regime of quenching to one of enhancement [57,65].…”

Section: Energy Transfer Using Ag Nanoparticle Arraysmentioning

confidence: 99%

“…An advantage of this colloidal system is that it utilizes simple processing techniques like spin coating that are easily scalable, however the placement of AgNPs is random which can influence the ET process and aggregation of the AgNPs needs to be overcome; having more isolated NPs could sharpen the LSP resonance giving an overall larger effect. In addition, having the AgNPs in an intermediate layer between the QDs and QW could provide even greater enhancement of the energy transfer efficiency [62,63].…”

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confidence: 99%

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Ag colloids and arrays for plasmonic non-radiative energy transfer from quantum dots to a quantum well

et al. 2017

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Section: Energy Transfer Using Ag Nanoparticle Arraysmentioning

confidence: 99%

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confidence: 99%

Ag colloids and arrays for plasmonic non-radiative energy transfer from quantum dots to a quantum well

et al. 2017

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“…8,16 These studies inform the design of the experimental system. The influence of an Au nanosphere on the nonradiateve energy transfer efficiency has been numerically investigated using a Green's tensor formalism.…”

Section: Plasmon-enhanced Non-radiative Energy Transfer In Quantum Domentioning

confidence: 99%

“…The influence of an Au nanosphere on the nonradiateve energy transfer efficiency has been numerically investigated using a Green's tensor formalism. 16 The donor quantum emitter emission and acceptor quantum emitter absorption are overlapped, and can vary from 400 nm to 700 nm. Fig.…”

Section: Plasmon-enhanced Non-radiative Energy Transfer In Quantum Domentioning

confidence: 99%

Enhancing Förster nonradiative energy transfer via plasmon interaction

et al. 2016

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Plasmon-enhanced nonradiative energy transfer is demonstrated in two inorganic semiconductor systems. The first is comprised of colloidal nanocrystal CdTe donor and acceptor quantum dots, while the second is a hybrid InGaN quantum well-CdSe/ZnS quantum dot donor-acceptor system. Both structures are in a planar geometry. In the first case a monolayer of Au nanospheres is sandwiched between donor and acceptor quantum dot monolayers. The largest energy transfer efficiency is seen when the donor is ~3 nm from the Au nanopshere. A plasmon-enhanced energy transfer efficiency of ~ 40% has been achieved for a separation of 3 nm between the Au nanopshere monolayer and the acceptor monolayer. Despite the increased energy transfer efficiency these conditions result in strong quenching of the acceptor QD emission. By tuning the Au nanosphere concentration and Au nanosphere-acceptor QD separation the acceptor QD emission can be increased by a factor of ~2.8. The plasmon-enhanced nonradiative energy transfer is observed to extend over larger distances than conventional Forster resonance energy transfer. Under the experimental conditions reported herein, it can be described by the same d dependence but with a larger characteristic distance. Using a Ag nanobox array plasmonic component plasmon-enhanced nonradiative energy transfer has also demonstrated from an InGaN quantum well to a ~80 nm thick layer of CdSe/ZnS colloidal quantum dots. An efficiency of ~27% is achieved, with an overall increase in the QD emission by ~70%.Keywords: Plasmonics, nonradiative energy transfer, Förster resonance energy transfer, FRET, plasmon-enhanced nonradiative energy transfer, localised surface plasmons, quantum dots and quantum wells

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“…Research has been done on optimization of FRET on DNA nanostructures that identifies labeling sites to achieve different levels of energy transfer [115,116], in super resolution microscopy [56,117], and plasmonics [118,119,120,121].…”

Section: Molecular Diagnosismentioning

confidence: 99%

Dynamic self-assembling DNA nanosystems: design and engineering

Mathur

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Words fail me in thanking my family, the Saraf, Mathur and Sangar clans, who let me choose a course of life for myself, and always provided me with unwavering support and love. I am especially grateful to the women in my life-my grandmother, mother, aunts and sisters-who were the best role models I could have asked for. I do not know of a stronger group of people. In some ways, this thesis is also dedicated to my father, who has been a constant support, in spirit, and in his favorite words on strength, courage and integrity. And finally, I would like to express my heartfelt gratitude to Nikhil Panicker, for his emotional support through every kind of obscenity the past six years of our lives have thrown at us, through the good times too, and for letting me learn ever so much from him. For bringing out the best in me. xii

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A theoretical investigation of the influence of gold nanosphere size on the decay and energy transfer rates and efficiencies of quantum emitters

Cited by 24 publications

References 114 publications

Ag colloids and arrays for plasmonic non-radiative energy transfer from quantum dots to a quantum well

Ag colloids and arrays for plasmonic non-radiative energy transfer from quantum dots to a quantum well

Enhancing Förster nonradiative energy transfer via plasmon interaction

Dynamic self-assembling DNA nanosystems: design and engineering

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