Disordered Mott–Hubbard Physics in Nanoparticle Solids: Transitions Driven by Disorder, Interactions, and Their Interplay

Unruh, Davis; Camjayi, Alberto; Hansen, Chase; Bobadilla, Joel; Rozenberg, Marcelo; Zimányi, Gergely T.

doi:10.1021/acs.nanolett.0c03141

Cited by 4 publications

(5 citation statements)

References 58 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Mobility simulations were performed utilizing the Hierarchical Nanoparticle Transport Simulator (HiNTS) kinetic Monte Carlo code, developed by some of us previously. 41,42 HiNTS simulates transport by developing several modeling layers and then integrating them into a hierarchical scheme. Aer the energetics of the individual QDs is computed by ab initio methods, the QD-to-QD transitions of the charges are described by the following two mechanisms:…”

Section: Mobility Simulationmentioning

confidence: 99%

See 1 more Smart Citation

Structural characterization of a polycrystalline epitaxially-fused colloidal quantum dot superlattice by electron tomography

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

Section: Mobility Simulationmentioning

confidence: 99%

“…Based on our previous work, we chose the electron density to be 0.5 electrons per QD, remaining far from commensuration to avoid Coulomb blockade effects. 41 A small voltage of 1 mV was then applied across electrical contacts on opposite sides of each sample to induce electron transport. Periodic boundary conditions were used.…”

Section: Mobility Simulationmentioning

confidence: 99%

Structural characterization of a polycrystalline epitaxially-fused colloidal quantum dot superlattice by electron tomography

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…We expect that the cations produce a corrugated potential at the crystal/ionic liquid interface that may be disordered, or ordered, depending on the accumulated interfacial charge . This potential energy landscape will be pronounced for the smaller DEME and N4441 cations, and it seems reasonable that this potential, combined with the Hubbard electron–electron interaction, causes the strongly insulating state near 1 e/C 60 . , …”

Section: Resultsmentioning

confidence: 98%

“…44 This potential energy landscape will be pronounced for the smaller DEME and N4441 cations, and it seems reasonable that this potential, combined with the Hubbard electron−electron interaction, causes the strongly insulating state near 1 e/C 60 . 61,62 When the cation radius increases in the case of N8881-based EDLTs, the physical situation changes markedly. The mobility data indicate accumulated electrons are delocalized, and we suggest that this implies that the corrugation potential from the cations is now greatly diminished.…”

Section: Resultsmentioning

confidence: 99%

Sub-Band Filling, Mott-like Transitions, and Ion Size Effects in C₆₀ Single Crystal Electric Double Layer Transistors

Frisbie

2022

ACS Nano

View full text Add to dashboard Cite

Electric double layer transistors (EDLTs) based on C 60 single crystals and ionic liquid gates display pronounced peaks in sheet conductance versus gate-induced charge. Sheet conductance is maximized at electron densities near 0.5 e/C 60 and is suppressed near 1 e/C 60 . The conductance suppression depends markedly on the choice of ionic liquid cation, with small cations favoring activated transport and essentially a complete shutdown of conductance at ∼1 e/C 60 and larger cations favoring band-like transport, higher overall conductances at all charge densities up to 1.7 e/C 60 , and weaker suppression at 1 e/C 60 . Displacement current measurements on C 60 EDLTs with small cations show clear evidence of sub-band filling at 1 e/C 60 , which correlates very well with the minimum in the C 60 sheet conductance. Overall, the data suggest a significant Mott-Hubbard-like energy gap opens up in the surface density of states for C 60 crystals gated with small cations. The causes of this energy gap may include both electron− electron repulsion and electron-cation attraction at the crystal/ionic liquid interface. The energy gap suppresses the insulatorto-metal transition in C 60 EDLTs, but it can be manipulated by choice of electrolyte.

show abstract

“…38, see also 39 Very recently, we demonstrated that NC solids are an excellent platform to study Mott-Hubbard phenomena, as they exhibit transport transitions driven by interactions, by disorder, and by their interplay. 40 In this paper, we adapt and apply our hierarchical transport simulator HINTS 35,38 to study charge transport in binary nanocrystal solids (BNSs) consisting of PbSe NCs of two different sizes. Our simulation results are motivated by early stage efforts to measure the transport of such binary NC films fabricated with layerby-layer dip coating of colloidal mixtures.…”

Section: Introductionmentioning

confidence: 99%

Percolative charge transport in binary nanocrystal solids

Unruh

Zimányi

2021

Phys. Rev. B

Self Cite

View full text Add to dashboard Cite

We simulated electron transport across a binary nanocrystal solid (BNS) of PbSe NCs with diameters of 6.5nm and 5.1nm. We used our Hierarchical Nanoparticle Transport Simulator HINTS to model the transport in these BNSs. The mobility exhibits a minimum at a Large-NC-fraction fLNC=0.25. The mobility minimum is deep at T=80K and partially smoothed at T=300K. We explain this minimum as follows. As the LNC fraction fLNC starts growing from zero, the few LNCs act as traps for the electrons traversing the BNS because their relevant energy level is lower. Therefore, increasing the fLNC concentration of these traps decreases the mobility. As increasing fLNC reaches the percolation threshold fLNC=fp, the LNCs form sample-spanning networks that enable electrons to traverse the entire BNS via these percolating LNC networks. Transport through the growing percolating LNC networks drives the rapid growth of the mobility as fLNC grows past fp. Therefore, the electron mobility exhibits a pronounced minimum as a function of fLNC, centered at fLNC=fp. The position of the mobility minimum shifts to larger LNC fractions as the electron density increases. We have studied the trends of this mobility minimum with temperature, electron density, charging energy, ligand length, and disorder. We account for the trends by a "renormalized trap model", in which capturing an electron renormalizes a deep LNC trap into a shallow trap or a kinetic obstacle, depending on the charging energy. We verified this physical picture by constructing and analyzing heat maps of the mobile electrons in the BNS.

show abstract

Disordered Mott–Hubbard Physics in Nanoparticle Solids: Transitions Driven by Disorder, Interactions, and Their Interplay

Cited by 4 publications

References 58 publications

Structural characterization of a polycrystalline epitaxially-fused colloidal quantum dot superlattice by electron tomography

Structural characterization of a polycrystalline epitaxially-fused colloidal quantum dot superlattice by electron tomography

Sub-Band Filling, Mott-like Transitions, and Ion Size Effects in C₆₀ Single Crystal Electric Double Layer Transistors

Percolative charge transport in binary nanocrystal solids

Contact Info

Product

Resources

About

Disordered Mott–Hubbard Physics in Nanoparticle Solids: Transitions Driven by Disorder, Interactions, and Their Interplay

Cited by 4 publications

References 58 publications

Structural characterization of a polycrystalline epitaxially-fused colloidal quantum dot superlattice by electron tomography

Structural characterization of a polycrystalline epitaxially-fused colloidal quantum dot superlattice by electron tomography

Sub-Band Filling, Mott-like Transitions, and Ion Size Effects in C60 Single Crystal Electric Double Layer Transistors

Percolative charge transport in binary nanocrystal solids

Contact Info

Product

Resources

About

Sub-Band Filling, Mott-like Transitions, and Ion Size Effects in C₆₀ Single Crystal Electric Double Layer Transistors