Towards colloidal spintronics through Rashba spin-orbit interaction in lead sulphide nanosheets

Moayed, Mohammad Mehdi Ramin; Bielewicz, Thomas; Zöllner, Martin Sebastian; Herrmann, Carmen; Klinke, Christian

doi:10.1038/ncomms15721

Cited by 30 publications

(27 citation statements)

References 43 publications

(131 reference statements)

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“…Early characterization of PbS nanosheets showed that they exhibit p‐type behavior when they are probed as field‐effect transistors . In order to effectively implement these nanosheets into applications like transistors, solar cells, photodetectors, and spintronic devices (based on the Rashba spin–orbit coupling), it is crucial to improve the p‐type behavior and also to develop the possibility to switch the behavior to n‐type . Doping colloidal nanomaterials, in contrast to conventional semiconductors, is complex since it depends on several parameters, such as the stoichiometry of the crystals, traps on the surface, passivating ligands and impurities .…”

Section: Introductionmentioning

confidence: 99%

High‐Performance n‐ and p‐Type Field‐Effect Transistors Based on Hybridly Surface‐Passivated Colloidal PbS Nanosheets

Moayed

Bielewicz

Noei

et al. 2018

Adv Funct Materials

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Colloidally synthesized nanomaterials are among the promising candidates for future electronic devices due to their simplicity and the inexpensiveness of their production. Specifically, colloidal nanosheets are of great interest since they are conveniently producible through the colloidal approach while having the advantages of two-dimensionality. In order to employ these materials, according transistor behavior should be adjustable and of high performance. It is shown that the transistor performance of colloidal lead sulfide nanosheets is tunable by altering the surface passivation, the contact metal, or by exposing them to air. It is found that adding halide ions to the synthesis leads to an improvement of the conductivity, the fieldeffect mobility, and the on/off ratio of these transistors by passivating their surface defects. Superior n-type behavior with a field-effect mobility of 248 cm 2 V −1 s −1 and an on/off ratio of 4 × 10 6 is achieved. The conductivity of these stripes can be changed from n-type to p-type by altering the contact metal and by adding oxygen to the working environment. As a possible solution for the post-Moore era, realizing new high-quality semiconductors such as colloidal materials is crucial. In this respect, the results can provide new insights which helps to accelerate their optimization for potential applications.

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Section: Introductionmentioning

confidence: 99%

High‐Performance n‐ and p‐Type Field‐Effect Transistors Based on Hybridly Surface‐Passivated Colloidal PbS Nanosheets

Moayed

Bielewicz

Noei

et al. 2018

Adv Funct Materials

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“…In the recent decades, it has been shown that the size reduction of different materials has led to the emergence of many novel properties due to the employment of quantum confinement. [ 1 ] For instance, the realization of spin‐dependent phenomena, [ 2,3 ] unconventional superconductivity regimes, [ 4 ] and topological surface states [ 5 ] attracted considerable attention. Nevertheless, there is still room to tune the shape and size of nanomaterials, which might further modify their properties or even fundamentally change their character.…”

Section: Introductionmentioning

confidence: 99%

“…[ 6,8 ] One example for the successful implementation of this approach is the synthesis of lead sulfide, which has been produced with a broad spectrum of shapes, sizes, and properties. [ 10–12 ] This material has been already used for many applications such as photodetectors, [ 13 ] field‐effect transistors, [ 14 ] spintronic components, [ 2 ] and solar cells. [ 15,16 ] Regarding all of these applications, a certain statement is valid: PbS exhibits semiconducting properties, which is not a surprising fact considering the electronic structure of this material.…”

Section: Introductionmentioning

confidence: 99%

“…[ 15,16 ] Regarding all of these applications, a certain statement is valid: PbS exhibits semiconducting properties, which is not a surprising fact considering the electronic structure of this material. [ 2,6,8,10–12,14–22 ] However, violating this statement could be of great scientific and practical importance, since it establishes new strategies to tune the properties of crystalline materials based on their target applications.…”

Section: Introductionmentioning

confidence: 99%

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Function Follows Form: From Semiconducting to Metallic toward Superconducting PbS Nanowires by Faceting the Crystal

Moayed

Kull

Rieckmann

et al. 2020

Adv Funct Materials

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In the realm of colloidal nanostructures, with their immense capacity for shape and dimensionality control, the form is undoubtedly a driving factor for the tunability of optical and electrical properties in semiconducting or metallic materials. However, influencing the fundamental properties is still challenging and requires sophisticated surface or dimensionality manipulation. Such a modification is presented for the example of colloidal leadsulfide nanowires. It is shown that the electrical properties of lead sulfide nanostructures can be altered from semiconducting to metallic with indications of superconductivity, by exploiting the flexibility of the colloidal synthesis to sculpt the crystal and to form different surface facets. A particular morphology of lead sulfide nanowires is prepared through the formation of {111} surface facets, which shows metallic and superconducting properties in contrast to other forms of this semiconducting crystal, which contain other surface facets ({100} and {110}). This effect, which is investigated with several experimental and theoretical approaches, is attributed to the presence of lead-rich {111} facets. The insights promote new strategies for tuning the properties of crystals and new applications for lead sulfide nanostructures.of materials with different properties. [6,8] One example for the successful implementation of this approach is the synthesis of lead sulfide, which has been produced with a broad spectrum of shapes, sizes, and properties. [10][11][12] This material has been already used for many applications such as photodetectors, [13] field-effect transistors, [14] spintronic components, [2] and solar cells. [15,16] Regarding all of these applications, a certain statement is valid: PbS exhibits semiconducting properties, which is not a surprising fact considering the electronic structure of this material. [2,6,8,[10][11][12][14][15][16][17][18][19][20][21][22] However, violating this statement could be of great scientific and practical importance, since it establishes new strategies to tune the properties of crystalline materials based on their target applications.Here, we introduce a method to change the electrical properties of colloidal lead sulfide nanowires from normal semiconducting to metallic with indications of superconductivity. This could be achieved by faceting the crystal, or in other words, by altering the surface facets of the crystal to the {111} ones, which are single element facets. This Pb-rich surface provides delocalized surface states at room temperature or presumably Cooper pairs at low temperatures, causing metallic and supposedly superconducting properties, in contrast to other forms of PbS nanocrystals, which are all semiconducting. Altering the surface facet is done by ligand-mediated growth in the presence of oleic acid (OA), lithium chloride, and trioctylphosphine, with expressed {111} facets giving a zigzag shape.Such zigzag wires are synthesized together with nanostripes, which have a flat shape, containing Pb and S atoms on their...

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“…39,40 Multi-exciton generation and tunable electrical features by halide ion doping were studied to improve nanosheet based devices as possible components in semiconductor industries. [41][42][43] Here, we present the synthesis of PbS nanoframes as intermediate nanostructures on the pathway to PbS nanorings. The synthesis starts with the formation of initial PbS nanosheets, which undergo a thermally induced ripening process in the presence of halide ions first forming nanoframes and later nanorings via additional halide ion etching.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of Single-Crystalline Lead Sulfide Nanoframes and Nanorings

et al. 2019

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We present a colloidal synthesis strategy to obtain single-crystalline PbS nanorings. By controlling the ripening process in the presence of halide ions, a transformation of initial PbS nanosheets to frame-like structures and finally to nanorings was achieved. We found that the competing ligands oleic acid, oleate and halide ions play an important role in the formation of these nanostructures. Therefore, we propose a formation mechanism based on a thermally induced ripening of crystal facets dependent on the surface passivation. With this method, it became possible to synthesize colloidal nanorings of cubic crystal phase galena PbS. The synthesis was followed via TEM and the products are characterized by XRD, AFM and STEM tomography. Control of the initial nanoframe morphology allows adjusting the later nanoring dimensions.

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Towards colloidal spintronics through Rashba spin-orbit interaction in lead sulphide nanosheets

Cited by 30 publications

References 43 publications

High‐Performance n‐ and p‐Type Field‐Effect Transistors Based on Hybridly Surface‐Passivated Colloidal PbS Nanosheets

High‐Performance n‐ and p‐Type Field‐Effect Transistors Based on Hybridly Surface‐Passivated Colloidal PbS Nanosheets

Function Follows Form: From Semiconducting to Metallic toward Superconducting PbS Nanowires by Faceting the Crystal

Synthesis of Single-Crystalline Lead Sulfide Nanoframes and Nanorings

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