Ultrafast Charge Carrier Dynamics and Transport Characteristics in HgTe Quantum Dots

Сергеева, К. А.; Fan, Kezhou; Sergeev, Alexander A.; Hu, Sile; Liu, Haochen; Chan, Christopher C. S.; Kershaw, Stephen V.; Wong, Kam Sing; Rogach, Andrey L.

doi:10.1021/acs.jpcc.2c05348

Cited by 12 publications

(17 citation statements)

References 50 publications

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“…[ 2 ] Its lack of bulk bandgap enables a unique tunability: from the visible for the strongly confined form of HgTe (i.e., the 2D nanoplatelets [ 3,4 ] ) to the THz range [ 5 ] for the largest particles with sizes above the Bohr radius (40 nm in HgTe [ 6 ] ). Furthermore, this spectral tunability is no longer limited to absorption, and luminescence can be obtained from 0.8 to 5 µm [ 7–11 ] and, more recently, has also been demonstrated in the THz range. [ 12 ]…”

Section: Introductionmentioning

confidence: 99%

Plasmon‐Assisted Directional Infrared Photoluminescence of HgTe Nanocrystals

Bossavit

Dang

et al. 2023

Advanced Optical Materials

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HgTe nanocrystals offer a unique spectral tunability with both absorption and emission covering the near and mid‐infrared as well as the THz window. Nevertheless, a very limited amount of work is dedicated to electroluminescence from this material. An efficient diode not only requires designing a structure that achieves a high electrical efficiency (i.e., efficient electron and hole injections), but also finding a way to efficiently extract the emitted photons. The shift from visible to infrared certainly demands revisiting the strategies proposed for shorter wavelengths (microlens arrays). Here, a metallic grating is used to enhance the photoluminscence signal up to a factor of 4 while enabling directionality in the emission, which is driven by the grating period.

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Section: Introductionmentioning

confidence: 99%

Plasmon‐Assisted Directional Infrared Photoluminescence of HgTe Nanocrystals

Bossavit

Dang

et al. 2023

Advanced Optical Materials

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“…This mobility value is lower than the numbers reported in refs 5, 12, and 47, yet it is several orders of magnitude higher than that of the HgTe quantum dots reported by our group previously. 6,48 The higher activation energies of HgTe NRs capped with S 2− and EDT (Figure S11b) are likely due to uncontrollable and fast liquid-or solid-state exchange procedures, respectively. One should notice that HgTe NRs capped with I − ions are colloidally less stable in solution, which has a significant impact on the film quality and lead to poorer performance of the resulting devices.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…HgTe nanocrystals have attracted a lot of interest among researchers in recent years, showing a great potential as active components in infrared (IR) optoelectronics, such as IR photodetectors − and light-emitting diodes. − In comparison to lead chalcogenides as the most widely studied near-IR emitting semiconductors on the nanoscale, HgTe offers a more convenient band-gap tunability from around 1.5 eV 10 to virtually zero owing to the semimetal nature of HgTe and its large Bohr radius (40 nm) . Additionally, films of HgTe quantum dots were reported to have high carrier mobilities (>1 cm 2 ·V –1 s –1 ) , and free carrier concentrations (>1 per nanocrystal owing to self-doping) .…”

Section: Introductionmentioning

confidence: 99%

Cation-Exchange-Derived Wurtzite HgTe Nanorods for Sensitive Photodetection in the Short-Wavelength Infrared Range

et al. 2023

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HgTe nanocrystals are one of the most promising candidates for optoelectronic applications in short-and middlerange infrared wavelength regions. Fabrication of one-dimensional anisotropic HgTe nanoparticles with a wurtzite structure has been a challenging task, so far. We introduce a two-step cation-exchange strategy to synthesize wurtzite-phase HgTe nanorods, starting from CdTe nanorods and proceeding through the formation of a Cu 2−x Te intermediate. We demonstrate a means to tune the residual Cu content in the final HgTe nanorods from tens to less than one at % by adjusting the oleylamine and N,Ndimethylethylenediamine concentrations used during the Cu-to-Hg cation-exchange step. The photoluminescence peak position of the HgTe nanorods is tunable in the broad spectral range from 1500 to 2500 nm with the decrease of the residual Cu content. Fieldeffect transistors based on fabricated HgTe nanorods show favorable transport characteristics, namely, hole mobilities up to 10 −2 cm 2 V −1 s −1 and on/off current ratio up to 10 3 . The responsivity of photodetectors based on HgTe nanorods at 1340 nm reaches 1 A/W, and the detectivity is up to 10 10 Jones for the devices with a simple planar geometry. Results presented here indicate wide prospects for exploring the electronic properties of wurtzite HgTe nanorods, as well as cation-doping and ligand surface passivation effects on device performance, which is of great importance for the field of modern optoelectronics.

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“…This leads to a reduced efficiency of the near‐field enhancement for the upper QD layers, an increasing mismatch between λ R and λ PL (Figure S4, Supporting Information), and a strengthening of the nonradiative decay channels arising from non‐resonant energy transfer between neighboring QDs. [ 13 ] Notably, the highest (up to 13‐fold) PL enhancement was observed for the largest NA of the collecting optics, suggesting a modification of the emission directivity from the QD layer capping the plasmonic metasurface. This inference is also reflected from a comparison of the results of the emission directivity modeling of dipolar emitters capping the plasmonic metasurface (Figure 2d).…”

Section: Resultsmentioning

confidence: 99%

Laser‐Printed Plasmonic Metasurface Supporting Bound States in the Continuum Enhances and Shapes Infrared Spontaneous Emission of Coupled HgTe Quantum Dots

Sergeeva,

Pavlov,

Seredin

et al. 2023

Adv Funct Materials

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In order to advance the development of quantum emitter‐based devices, it is essential to enhance light‐matter interactions through coupling between semiconductor quantum dots with high quality factor resonators. Here, efficient tuning of the emission properties of HgTe quantum dots in the infrared spectral region is demonstrated by coupling them to a plasmonic metasurface that supports bound states in the continuum. The plasmonic metasurface, composed of an array of gold nanobumps, is fabricated using single‐step direct laser printing, opening up new opportunities for creating exclusive 3D plasmonic nanostructures and advanced photonic devices in the infrared region. A 12‐fold enhancement of the photoluminescence in the 900–1700 nm range is observed under optimal coupling conditions. By tuning the geometry of the plasmonic arrays, controllable shaping of the emission spectra is achieved, selectively enhancing specific wavelength ranges across the emission spectrum. The observed enhancement and shaping of the emission are attributed to the Purcell effect, as corroborated by systematic measurements of radiative lifetimes and optical simulations based on the numerical solution of Maxwell's equations. Moreover, coupling of the HgTe photoluminescence to high quality factor modes of the metasurface improves emission directivity, concentrating output within an ≈20° angle.

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Ultrafast Charge Carrier Dynamics and Transport Characteristics in HgTe Quantum Dots

Cited by 12 publications

References 50 publications

Plasmon‐Assisted Directional Infrared Photoluminescence of HgTe Nanocrystals

Plasmon‐Assisted Directional Infrared Photoluminescence of HgTe Nanocrystals

Cation-Exchange-Derived Wurtzite HgTe Nanorods for Sensitive Photodetection in the Short-Wavelength Infrared Range

Laser‐Printed Plasmonic Metasurface Supporting Bound States in the Continuum Enhances and Shapes Infrared Spontaneous Emission of Coupled HgTe Quantum Dots

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