LaF3 insulators for MIS structures

Sher, A.; Miller, William E.; Tsuo, Y. H.; Moriarty, John A.; Crouch, R. K.; Seiber, B. A.

doi:10.1063/1.90649

Cited by 11 publications

(5 citation statements)

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“…The permittivity is close to the bulk value of 14. [59] The leakage current density versus electric field is depicted in Figure 10. The catastrophic breakdown occurred at electric field values of À1.8 and þ2.3 MV cm…”

Section: Film Propertiesmentioning

confidence: 99%

Atomic Layer Deposition of LaF₃ Thin Films using La(thd)₃ and TiF₄ as Precursors

Pilvi

Puukilainen

Arstila

et al. 2008

Chemical Vapor Deposition

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Lanthanum fluoride is a vacuum ultraviolet (VUV) transparent material which is widely used in optical applications. An atomic layer deposition (ALD) process is developed for depositing lanthanum fluoride thin films for the first time. LaF 3 films are grown at 225-350 -C using La(thd) 3 and TiF 4 as precursors. The crystallinity, morphology, composition, thicknesses, and refractive indices of the films are analyzed by X-ray diffraction/reflection (XRD/XRR), atomic force microscopy (AFM), scanning electron microscopy (SEM), time-of-flight elastic recoil detection analysis (TOF-ERDA), and UV-vis spectrophotometry. Electrical properties, such as permittivity and leakage current density, are also studied. An exceptionally high growth rate of about 5 Å per cycle is achieved at 225-250 -C. The films are polycrystalline, the refractive indices vary between 1.57 and 1.61, and the permittivity is 12.3. The impurities detected in the LaF 3 film are Ti, C, O, and H. The level of all of these tends to decrease with increase in the deposition temperature, and is only 3.5 at.-% at 350 -C.

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Section: Film Propertiesmentioning

confidence: 99%

Atomic Layer Deposition of LaF₃ Thin Films using La(thd)₃ and TiF₄ as Precursors

Pilvi

Puukilainen

Arstila

et al. 2008

Chemical Vapor Deposition

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“…28 LaF 3 is an ionic conductor at room temperature where the mobile carriers are fluorine ion vacancies. 28 Like liquid or ion-gel electrolytes previously employed to gate graphene, 13,29 LaF 3 can induce larger electrostatic doping than dielectric oxides. A LaF 3 film forms a thin dipole layer at its surface that produces a large capacitance, which can be effectively treated as that of a 10−20 nm thick insulating layer (independent of the actual film thickness) with a dielectric constant of 14.…”

mentioning

confidence: 99%

“…A LaF 3 film forms a thin dipole layer at its surface that produces a large capacitance, which can be effectively treated as that of a 10−20 nm thick insulating layer (independent of the actual film thickness) with a dielectric constant of 14. 28 This work assumed 10 nm for the insulator's effective thickness. Graphene was covered with a thin film of insulating poly(methyl methacrylate) (PMMA) with varying thicknesses.…”

mentioning

confidence: 99%

“…To test the effect of electrostatic doping on resonant energy transfer to graphene, we fabricated the device structure shown in Figure d,e. The graphene layer was back-gated with lanthanum fluoride (LaF 3 ), a solid-state electrolyte . LaF 3 is an ionic conductor at room temperature where the mobile carriers are fluorine ion vacancies .…”

mentioning

confidence: 99%

“…The graphene layer was back-gated with lanthanum fluoride (LaF 3 ), a solid-state electrolyte . LaF 3 is an ionic conductor at room temperature where the mobile carriers are fluorine ion vacancies . Like liquid or ion-gel electrolytes previously employed to gate graphene, , LaF 3 can induce larger electrostatic doping than dielectric oxides.…”

mentioning

confidence: 99%

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Switching Individual Quantum Dot Emission through Electrically Controlling Resonant Energy Transfer to Graphene

Lee

Bao

Ju³

et al. 2014

Nano Lett.

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Electrically controlling resonant energy transfer of optical emitters provides a novel mechanism to switch nanoscale light sources on and off individually for optoelectronic applications. Graphene's optical transitions are tunable through electrostatic gating over a broad wavelength spectrum, making it possible to modulate energy transfer from a variety of nanoemitters to graphene at room temperature. We demonstrate photoluminescence switching of individual colloidal quantum dots by electrically tuning their energy transfer to graphene. The gate dependence of energy transfer modulation confirms that the transition occurs when the Fermi level is shifted over half the emitter's excitation energy. The modulation magnitude decreases rapidly with increasing emitter-graphene distance (d), following the 1/d(4) rate trend unique to the energy transfer process to two-dimensional materials.

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Photoemission study of the growth of the NdF3/Si(111) interface

et al. 1994

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LaF3 insulators for MIS structures

Cited by 11 publications

References 8 publications

Atomic Layer Deposition of LaF₃ Thin Films using La(thd)₃ and TiF₄ as Precursors

Atomic Layer Deposition of LaF₃ Thin Films using La(thd)₃ and TiF₄ as Precursors

Switching Individual Quantum Dot Emission through Electrically Controlling Resonant Energy Transfer to Graphene

Photoemission study of the growth of the NdF3/Si(111) interface

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LaF3 insulators for MIS structures

Cited by 11 publications

References 8 publications

Atomic Layer Deposition of LaF3 Thin Films using La(thd)3 and TiF4 as Precursors

Atomic Layer Deposition of LaF3 Thin Films using La(thd)3 and TiF4 as Precursors

Switching Individual Quantum Dot Emission through Electrically Controlling Resonant Energy Transfer to Graphene

Photoemission study of the growth of the NdF3/Si(111) interface

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Atomic Layer Deposition of LaF₃ Thin Films using La(thd)₃ and TiF₄ as Precursors

Atomic Layer Deposition of LaF₃ Thin Films using La(thd)₃ and TiF₄ as Precursors