Titanium trisulfide (TiS3): a 2D semiconductor with quasi-1D optical and electronic properties

Island, Joshua O.; Biele, Robert; Barawi, Mariam; Clamagirand, José M.; Ares, J.R.; Sánchez, Carlos; Zant, Herre S. J. van der; Ferrer, Isabel J.; D’Agosta, Roberto; Castellanos-Gómez, Andrés

doi:10.1038/srep22214

Cited by 113 publications

(138 citation statements)

References 44 publications

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“…Compared to BP and group IV monochalcogenides GeS and GeSe, the quasi‐one‐dimensional structure of the group IVB trichalcogenide TiS 3 has a much larger anisotropic absorption ratio. As shown in Figure F, the transmittance of the RGB channels is clearly strong polarization dependent, and the transmission ratio between b‐axis ( y ‐direction) and a‐axis ( x ‐direction) can up to 30 . Besides, the optical contrast under polarized light is also anisotropic, which can be approved by the optical images in Figure F.…”

Section: In‐plane Anisotropic Physical Propertiesmentioning

confidence: 71%

Section: In‐plane Anisotropic Physical Propertiesmentioning

confidence: 99%

Section: In‐plane Anisotropic Physical Propertiesmentioning

confidence: 99%

“…The anisotropic optical absorption of triclinic ReS 2 and ReSe 2 has also been studied . Typical polarization‐resolved reflection spectra for 3 L ReS 2 is presented in Figure H, three exciton peaks 1, 2, and 3 are indicated by arrows, showing clear anisotropy, in which excitons 1 and 2 exhibit maximum values at an angle of ∼15 and ∼50° between light polarized direction and b‐axis, respectively . This is different from BP, GeS, and GeSe that show maximum absorptions along the principal axes.…”

Section: In‐plane Anisotropic Physical Propertiesmentioning

confidence: 99%

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Emerging in‐plane anisotropic two‐dimensional materials

Han

et al. 2019

InfoMat

281

236

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Black phosphorus (BP) is a rapidly up and coming star in two‐dimensional (2D) materials. The unique characteristic of BP is its in‐plane anisotropy. This characteristic of BP ignites a new type of 2D materials that have low‐symmetry structures and in‐plane anisotropic properties. On this basis, they offer richer and more unique low‐dimensional physics compared to isotropic 2D materials, thus providing a fertile ground for novel applications including electronics, optoelectronics, molecular detection, thermoelectric, piezoelectric, and ferroelectric with respect to in‐plane anisotropy. This article reviews the recent advance in characterization and applications of in‐plane anisotropic 2D materials.

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Section: In‐plane Anisotropic Physical Propertiesmentioning

confidence: 71%

Section: In‐plane Anisotropic Physical Propertiesmentioning

confidence: 99%

Section: In‐plane Anisotropic Physical Propertiesmentioning

confidence: 99%

Section: In‐plane Anisotropic Physical Propertiesmentioning

confidence: 99%

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Emerging in‐plane anisotropic two‐dimensional materials

Han

et al. 2019

InfoMat

281

236

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“…We emphasize that such advantages basically originate from the unique in-plane crystal anisotropy of group VII TMDs, which is absent in group VI 2D TMDs (for example, MoS 2 , MoSe 2 , WS 2 and WSe 2 ). Of course, group VII TMDs are not the only material family exhibiting anisotropic property of excitons; there are several systems possessing anisotropic excitonic properties (such as carbon nanotubes (CNTs) and black phosphorus (BP))12303132. However, both of them lack polarization-dependent exciton selectivity so that energy-selective optical Stark effect cannot be expected.…”

Section: Discussionmentioning

confidence: 99%

Selectively tunable optical Stark effect of anisotropic excitons in atomically thin ReS2

et al. 2016

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The optical Stark effect is a coherent light–matter interaction describing the modification of quantum states by non-resonant light illumination in atoms, solids and nanostructures. Researchers have strived to utilize this effect to control exciton states, aiming to realize ultra-high-speed optical switches and modulators. However, most studies have focused on the optical Stark effect of only the lowest exciton state due to lack of energy selectivity, resulting in low degree-of-freedom devices. Here, by applying a linearly polarized laser pulse to few-layer ReS2, where reduced symmetry leads to strong in-plane anisotropy of excitons, we control the optical Stark shift of two energetically separated exciton states. Especially, we selectively tune the Stark effect of an individual state with varying light polarization. This is possible because each state has a completely distinct dependence on light polarization due to different excitonic transition dipole moments. Our finding provides a methodology for energy-selective control of exciton states.

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High Current Density Electrical Breakdown of TiS₃ Nanoribbon‐Based Field‐Effect Transistors

Molina‐Mendoza

Island

Paz

et al. 2017

Adv Funct Materials

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The high field transport characteristics of nanostructured transistors based on layered materials are not only important from a device physics perspective but also for possible applications in next generation electronics. With the growing promise of layered materials as replacements to conventional silicon technology, the high current density properties of the layered material titanium trisulfide (TiS 3 ) are studied here. The high breakdown current densities of up to 1.7 × 10 6 A cm −2 are observed in TiS 3 nanoribbon-based field-effect transistors, which are among the highest found in semiconducting nanomaterials. Investigating the mechanisms responsible for current breakdown, a thermogravimetric analysis of bulk TiS 3 is performed and the results with density functional theory and kinetic Monte Carlo calculations are compared. In conclusion, the oxidation of TiS 3 and subsequent desorption of sulfur atoms play an important role in the electrical breakdown of the material in ambient conditions. The results show that TiS 3 is an attractive material for high power applications and lend insight into the thermal and defect activated mechanisms responsible for electrical breakdown in nanostructured devices.

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Titanium trisulfide (TiS3): a 2D semiconductor with quasi-1D optical and electronic properties

Cited by 113 publications

References 44 publications

Emerging in‐plane anisotropic two‐dimensional materials

Emerging in‐plane anisotropic two‐dimensional materials

Selectively tunable optical Stark effect of anisotropic excitons in atomically thin ReS2

High Current Density Electrical Breakdown of TiS₃ Nanoribbon‐Based Field‐Effect Transistors

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Titanium trisulfide (TiS3): a 2D semiconductor with quasi-1D optical and electronic properties

Cited by 113 publications

References 44 publications

Emerging in‐plane anisotropic two‐dimensional materials

Emerging in‐plane anisotropic two‐dimensional materials

Selectively tunable optical Stark effect of anisotropic excitons in atomically thin ReS2

High Current Density Electrical Breakdown of TiS3 Nanoribbon‐Based Field‐Effect Transistors

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High Current Density Electrical Breakdown of TiS₃ Nanoribbon‐Based Field‐Effect Transistors