Vacuum ultraviolet thin films 1: Optical constants of BaF_2, CaF_2, LaF_3, MgF_2, Al_2O_3, HfO_2, and SiO_2 thin films

Zukic, Muamer; Torr, D. G.; Spann, James F.; Torr, Marsha R.

doi:10.1364/ao.29.004284

Cited by 101 publications

(36 citation statements)

References 17 publications

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“…The returned values confirmed the expected behavior of all films, except HfO 2 . We found the index of refraction below 250 nm was much higher than that measured [19,20] (maximum difference of 30%). Values for k were as expected.…”

Section: A Test Setupscontrasting

confidence: 63%

“…There are several published indices of refraction for the Si substrate, which contributes to some uncertainty in the predicted reflectance. The indices of refraction for all materials were taken from Palik [17,18], except for HfO 2 , which came from Zukic et al [19,20]. An alternative index of refraction for Si was also consulted, taken from Philipp and Taft [21].…”

Section: Deposition Techniquesmentioning

confidence: 99%

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Ultraviolet antireflection coatings for use in silicon detector design

et al. 2011

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We report on the development of coatings for a charged-coupled device (CCD) detector optimized for use in a fixed dispersion UV spectrograph. Because of the rapidly changing index of refraction of Si, single layer broadband antireflection (AR) coatings are not suitable to increase quantum efficiency at all wavelengths of interest. Instead, we describe a creative solution that provides excellent performance over UV wavelengths. We describe progress in the development of a coated CCD detector with theoretical quantum efficiencies (QEs) of greater than 60% at wavelengths from 120 to 300 nm. This high efficiency may be reached by coating a backside-illuminated, thinned, delta-doped CCD with a series of thin film AR coatings. The materials tested include MgF 2 (optimized for highest performance from 120-150 nm), SiO 2 (150-180 nm), Al 2 O 3 (180-240 nm), , and HfO 2 (240-300 nm). A variety of deposition techniques were tested and a selection of coatings that minimized reflectance on a Si test wafer were applied to functional devices. We also discuss future uses and improvements, including graded and multilayer coatings.

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Section: A Test Setupscontrasting

confidence: 63%

Section: Deposition Techniquesmentioning

confidence: 99%

Ultraviolet antireflection coatings for use in silicon detector design

et al. 2011

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“…LaF 3 thin films exhibit extremely good moisture resistance, therefore they are very useful, e.g., for protecting optical components. [3] Due to its high band-gap and refractive index, higher than those of the other VUV transparent films, LaF 3 is a useful material for VUV optics, particularly for constructing a high-low refractive index pair with, e.g., MgF 2 [4][5][6][7][8][9][10][11][12][13] as the low refractive index material. AlF 3 has also been used together with LaF 3 in optical multilayer structures.…”

Section: Introductionmentioning

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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“…LaF 3 is considered as the best choice for high index material in UV region, especially DUV region [5,6]. The HR coating comprising LaF 3 as high index material possesses excellent UV laser damage resistance [7,8].…”

Section: Introductionmentioning

confidence: 99%

Characterization of LaF3 coatings prepared at different temperatures and rates

Shen

Cui

et al. 2008

Applied Surface Science

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Vacuum ultraviolet thin films 1: Optical constants of BaF_2, CaF_2, LaF_3, MgF_2, Al_2O_3, HfO_2, and SiO_2 thin films

Cited by 101 publications

References 17 publications

Ultraviolet antireflection coatings for use in silicon detector design

Ultraviolet antireflection coatings for use in silicon detector design

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

Characterization of LaF3 coatings prepared at different temperatures and rates

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Vacuum ultraviolet thin films 1: Optical constants of BaF_2, CaF_2, LaF_3, MgF_2, Al_2O_3, HfO_2, and SiO_2 thin films

Cited by 101 publications

References 17 publications

Ultraviolet antireflection coatings for use in silicon detector design

Ultraviolet antireflection coatings for use in silicon detector design

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

Characterization of LaF3 coatings prepared at different temperatures and rates

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Product

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