2010
DOI: 10.1021/nl101490z
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Comparing Multiple Exciton Generation in Quantum Dots To Impact Ionization in Bulk Semiconductors: Implications for Enhancement of Solar Energy Conversion

Abstract: Multiple exciton generation (MEG) in quantum dots (QDs) and impact ionization (II) in bulk semiconductors are processes that describe producing more than one electron-hole pair per absorbed photon. We derive expressions for the proper way to compare MEG in QDs with II in bulk semiconductors and argue that there are important differences in the photophysics between bulk semiconductors and QDs. Our analysis demonstrates that the fundamental unit of energy required to produce each electron-hole pair in a given QD… Show more

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Cited by 338 publications
(429 citation statements)
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“…Interestingly, in QDs, recent spectroscopic findings are indicative of MEG thresholds MEG th ( ) E being closer to the energy conservation limit (2E g ) than in the parental bulk material [30,31,45,46]. In these reports, the authors also find a close correlation between MEG th E and the MEG efficiency (η MEG ).…”
Section: Enhancing CM In Qdsmentioning
confidence: 86%
See 1 more Smart Citation
“…Interestingly, in QDs, recent spectroscopic findings are indicative of MEG thresholds MEG th ( ) E being closer to the energy conservation limit (2E g ) than in the parental bulk material [30,31,45,46]. In these reports, the authors also find a close correlation between MEG th E and the MEG efficiency (η MEG ).…”
Section: Enhancing CM In Qdsmentioning
confidence: 86%
“…For MEG in particular, recent spectroscopic findings suggest a combination of high MEG threshold energies and photon energy-dependent MEG efficiency (i.e. MEG efficiency increases slowly after the threshold energy rather than as a step function) as the predominant reasons for the modest contribution to PV power conversion [29,30].…”
Section: Introductionmentioning
confidence: 99%
“…15 In addition, confinement leads to the absence of conservation of momentum, modified carriercooling rates, and reduced dielectric screening, all of which account for enhanced MEG in QDs. 15,16 Besides this basic understanding, a detailed microscopic description of MEG in QDs is needed for an efficient design and optimization of QD solar cells. Since the first demonstration of efficient MEG in PbSe QDs by Schaller and Klimov in 2004, 5 significant attention has been paid to the study of QD based systems for efficient MEG.…”
Section: Introductionmentioning
confidence: 99%
“…Several groups have been studying MEG efficiency in colloidal semiconductor QDs where they showed a production of multiple electron hole pairs upon absorption of a single photon. 12,[16][17][18] Lead chalcogenide QDs (PbS and PbSe), cadmium chalcogenide QDs, indium based QDs (InAs and InP) and silicon QDs are some of the intensively studied QD systems for exploring the efficiency of MEG. 2,[19][20][21][22][23][24] MEG is commonly measured by ultrafast transient absorption spectroscopy, 25 which allows one to capture the rapid processes of bi-exciton formation and Auger recombinations on the ps time scale.…”
Section: Introductionmentioning
confidence: 99%
“…This leads to an increase in both single-and bi-exciton densities of states, with the latter increasing at a faster rate, though, causing a decrease in the energy E 0 at which the two curves cross (which is closely related to the energy position of the CM onset). This effect is important as a lowering of the CM onset is associated with increased CM efficiency 12,13 and enhanced solar energy conversion 14,15 . In 0D confined structures, CM is typically described in terms of impact ionisation (II) 1,3,[16][17][18] , a term originally used to describe this process in bulk materials: the photon energy in excess of the bandgap, rather than being lost to the lattice in the form of phonons, can be transferred by one of the two photogenerated carriers to an electron in the valence band, exciting it to the conduction band, and creating a further exciton (for a total of two excitons generated per absorbed photon, see Fig.…”
Section: Introductionmentioning
confidence: 99%