Low‐Symmetry α‐MoO<sub>3</sub> Heterostructures for Wave Plate Applications in Visible Frequencies

Dereshgi, Sina Abedini; Lee, Yea‐Shine; Larciprete, Maria Cristina; Centini, Marco; Dravid, Vinayak P.; Aydın, Koray

doi:10.1002/adom.202202603

Cited by 6 publications

(7 citation statements)

References 48 publications

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“…Using the reported refractive indices, we calculate the interference enhancement factors of SVPM and TVPM for α-MoO 3 with different thicknesses on the SiO 2 /Si substrate excited by 532 and 633 nm, as shown in Figure S5 (for more calculated details, please see Part 3 in the Supporting Information). Compared to BP and b-As, , the enhancement factors of α-MoO 3 vary less with thickness, which may be attributed to the low extinction coefficient and refractive indices (close to 2) of α-MoO 3 . , When the thickness of α-MoO 3 is less than 50 nm, the enhancement factors decrease (increase) with thickness under 532 (633) nm excitation. The variation of the I of α-MoO 3 with thickness is most likely attributed to the enhancement factor.…”

Section: Resultsmentioning

confidence: 91%

“…It is reported that Δn equals 0.15 (0.12) under 532 (633) nm excitation. 46 For the tBL α-MoO 3 samples (∼28.0 nm), ϕ ac 532 = ∼2.84°and ϕ ac 633 = ∼1.91°. Such a small ϕ ac guarantees that the birefringence modulation is weak and can be ignored.…”

Section: ■ Results and Discussionmentioning

confidence: 97%

“…Compared to BP and b-As, 18,51 the enhancement factors of α-MoO 3 vary less with thickness, which may be attributed to the low extinction coefficient and refractive indices (close to 2) of α-MoO 3 . 46,52 When the thickness of α-MoO 3 is less than 50 nm, the enhancement factors decrease (increase) with thickness under 532 (633) nm excitation. The variation of the I of α-MoO 3 with thickness is most likely attributed to the enhancement factor.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…It is estimated as ϕ a c = 2 π Δ n d λ , , where d is the thickness of α-MoO 3 sample and Δ n is the refractive index difference of α-MoO 3 along the [100] and [001] directions. It is reported that Δ n equals 0.15 (0.12) under 532 (633) nm excitation . For the tBL α-MoO 3 samples (∼28.0 nm), ϕ ac 532 = ∼2.84° and ϕ ac 633 = ∼1.91°.…”

Section: Resultsmentioning

confidence: 99%

See 3 more Smart Citations

Configurable Phonon Polarization Responses in Twisted α-MoO₃

Bai,

Wang,

Yang

et al. 2024

J. Phys. Chem. C

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Section: Resultsmentioning

confidence: 91%

Section: ■ Results and Discussionmentioning

confidence: 97%

Section: ■ Results and Discussionmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

See 2 more Smart Citations

Configurable Phonon Polarization Responses in Twisted α-MoO₃

Bai,

Wang,

Yang

et al. 2024

J. Phys. Chem. C

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“…The birefringence values for the P4/nmm phase of the system, as estimated from SCF (nSCF) calculation are found to be ∼1.99 (1.53), 2.03 (1.42) and 1.83 (1.15) at E M ∼ 1.8, 2 and 2.5 eV respectively. The high n D values for the above referred phase of the compound in the visible region of the EM wave (1.7 < E M < 3 eV) may be helpful in designing enhanced optoelectronic devices such as polarizing prisms, optic-axis gratings, light modulators and polaroids [94,[119][120][121][122].…”

Section: Imaginary Part Of Complex Dielectric Functionmentioning

confidence: 99%

Pressure driven structural phase transitions and modulations in optical properties of lanthanum nitride: an account from on the fly molecular dynamics and SCF vis-à-vis non-SCF first-principle calculations

Banik,

Ghosh,

Chowdhury

2023

Phys. Scr.

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The paper is focused to explore the pressure induced structural phase transitions and modulations of optical properties of lanthanum nitride (LaN) for the first time with the aid of first-principle density functional theory and Born-Oppenheimer on the fly molecular dynamics calculations. Crystal structures, Gibbs free energies and phonon dispersion spectra of the compound in its various phases under ambient and external pressures have been critically investigated. The key phonon modes responsible for these pressure driven transitions have also been unveiled. Electronic band structures and associated optoelectronic properties of the system have been studied in detail from both the self-consistent field and non-self-consistent field calculations. The early signature of topological insulator for the high pressure phase of LaN has been addressed from the electronic band structure calculations. We believe that this study will not only help for futuristic designs of improved functionalized systems with LaN compound but also can augment their applications such as pressure sensors, pressure conducting switches, dissipationless transistors and in optoelectronic devices.

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Deeply subwavelength mid-infrared phase retardation with α-MoO3 flakes

Enders,

Sarkar,

Giteau

et al. 2024

Commun Mater

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Phase retardation is a cornerstone of modern optics, yet, at mid-infrared (mid-IR) frequencies, it remains a major challenge due to the scarcity of simultaneously transparent and birefringent crystals. Most materials resonantly absorb due to lattice vibrations occurring at mid-IR frequencies, and natural birefringence is weak, calling for hundreds of microns to millimeters-thick phase retarders for sufficient polarization rotation. Here, we demonstrate mid-IR phase retardation with flakes of α-MoO3 that are more than ten times thinner than the operational wavelength, achieving 90 degrees polarization rotation within one micrometer of material. We report conversion ratios above 50% in reflection or transmission mode, and wavelength tunability by several micrometers. Our results showcase that exfoliated flakes of low-dimensional crystals can serve as a platform for mid-IR miniaturized integrated low-loss polarization control.

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Low‐Symmetry α‐MoO₃ Heterostructures for Wave Plate Applications in Visible Frequencies

Cited by 6 publications

References 48 publications

Configurable Phonon Polarization Responses in Twisted α-MoO₃

Configurable Phonon Polarization Responses in Twisted α-MoO₃

Pressure driven structural phase transitions and modulations in optical properties of lanthanum nitride: an account from on the fly molecular dynamics and SCF vis-à-vis non-SCF first-principle calculations

Deeply subwavelength mid-infrared phase retardation with α-MoO3 flakes

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Low‐Symmetry α‐MoO3 Heterostructures for Wave Plate Applications in Visible Frequencies

Cited by 6 publications

References 48 publications

Configurable Phonon Polarization Responses in Twisted α-MoO3

Configurable Phonon Polarization Responses in Twisted α-MoO3

Pressure driven structural phase transitions and modulations in optical properties of lanthanum nitride: an account from on the fly molecular dynamics and SCF vis-à-vis non-SCF first-principle calculations

Deeply subwavelength mid-infrared phase retardation with α-MoO3 flakes

Contact Info

Product

Resources

About

Low‐Symmetry α‐MoO₃ Heterostructures for Wave Plate Applications in Visible Frequencies

Configurable Phonon Polarization Responses in Twisted α-MoO₃

Configurable Phonon Polarization Responses in Twisted α-MoO₃