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1. Zirconium disulfide single crystal, ZrS2(0001), characterized by X-ray photoelectron spectroscopy

   https://doi.org/10.1116/6.0004276  

   Chavez, Daniela; Berube, Abigail D; Davis, Luke M (June 2025, Surface Science Spectra)

   We analyzed the surface of a freshly exfoliated single crystal of zirconium(IV) sulfide, ZrS₂. Survey spectra and high-resolution spectra from the core levels Zr 4p, Zr 4s, Zr 3d, Zr 3p, Zr 3s, S 2p, S 2s, O 1s, and C 1s were acquired. The binding energies and peak area ratios of a stoichiometric ZrS₂ single crystal provide a pure reference of well-defined composition for material deposited by chemical or physical vapor deposition methods. 

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2. Molecular beam epitaxy of PtSe ₂ using a co-deposition approach

   https://doi.org/10.1088/2053-1583/ac606f  

   Hilse, Maria; Wang, Ke; Engel-Herbert, Roman (April 2022, 2D Materials)

   Abstract The structural properties of co-deposited ultrathin PtSe 2 films grown at low temperatures by molecular beam epitaxy on c-plane Al 2 O 3 are studied. By simultaneously supplying a Se flux from a Knudsen cell and Pt atoms from an electron-beam evaporator, crystalline (001)-oriented PtSe 2 films were formed between 200 °C and 300 °C. The long separation between substrate and electron beam evaporator of about 60 cm ensured minimal thermal load. At optimum deposition temperatures, a ten times or even higher supply rate of Se compared to Pt ensured that the pronounced volatility of the Se was compensated and the PtSe 2 phase was formed and stabilized at the growth front. Postgrowth anneals under a Se flux was found to dramatically improve the crystalline quality of the films. Even before the postgrowth anneal in Se, the crystallinity of PtSe 2 films grown with the co-deposition method was superior to films realized by thermal assisted conversion. Postgrowth annealed films showed Raman modes with narrower peaks and more than twice the intensity. Transmission electron microscopy investigations revealed that the deposited material transitioned to a two-dimensional layered structure only after the postgrowth anneal. PtSe 2 growth was found to start as single layer islands that preferentially nucleated at atomic steps of the substrate and progressed in a layer-by-layer like fashion. A close to ideal wetting behavior resulted in coalesced PtSe 2 films after depositing about 1.5 PtSe 2 layers. Detailed Raman investigation of the observed PtSe 2 layer breathing modes of films grown under optimized co-deposition conditions revealed an interlayer coupling force constant of 5.0–5.6 × 10 19 N m −3 . 

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3. Structural and mechanical properties of nanocrystalline Ga ₂ O ₃ films made by pulsed laser deposition onto transparent quartz substrates

   https://doi.org/10.1088/2632-959X/abf3d3  

   Zade, Vishal; Makeswaran, Nanthakishore; Boyce, Brad L.; Paraguay-Delgado, Francisco; Ramana, C. V. (April 2021, Nano Express)

   Abstract This work reports on the correlation between structure, surface/interface morphology and mechanical properties of pulsed laser deposited (PLD)β-Ga₂O₃films on transparent quartz substrates. By varying the deposition temperature in the range of 25 °C–700 °C, ∼200 nm thick Ga₂O₃films with variable microstructure and amorphous-to-nanocrystalline nature were produced onto quartz substrates by PLD. The Ga₂O₃films deposited at room temperature were amorphous; nanocrystalline Ga₂O₃films were realized at 700 °C. The interface microstructure is characterized with a typical nano-columnar morphology while the surface exhibits the uniform granular morphology. Corroborating with structure and surface/interface morphology, and with increasing deposition temperature, tunable mechanical properties were seen in PLD Ga₂O₃films. At 700 °C, for nanocrystalline Ga₂O₃films, the dense grain packing reduces the elastic modulus E_rwhile improving the hardness. The improved crystallinity at elevated temperatures coupled with nanocrystallinity, theβ-phase stabilization is accounted for the observed enhancement in the mechanical properties of PLD Ga₂O₃films. The structure-morphology-mechanical property correlation in nanocrystalline PLDβ-Ga₂O₃films deposited on quartz substrates is discussed in detail. 

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4. Extracting the Optical Constants of Partially Absorbing TiO2 ALD Films

   https://doi.org/10.3390/coatings14121555  

   Chowdhary, Nimarta Kaur; Gougousi, Theodosia (December 2024, Coatings)

   Typical titanium oxide (TiO2) films are transparent in the visible range, allowing for their index of refraction and thickness to be extracted by single-angle spectroscopic ellipsometry (SE) using a Cauchy model. However, TiO2 films grown by atomic layer deposition (ALD) from tetrakis(dimethylamino)titanium (IV) (TDMAT) and H2O at 350 °C absorb in the visible range due to the formation of Ti-O-N/Ti-N bonds. Single-angle SE is inadequate for extracting the optical constants of these films, as there are more unknowns (n, k, d) than measurable parameters (ψ, Δ). To overcome this limitation, we combined SE with transmission (T) measurements, a method known as SE + T. In the process, we developed an approach to prevent backside deposition on quartz substrates during ALD deposition. When applying a B-spline model to SE + T data, the film thicknesses on the quartz substrates closely matched those on companion Si samples measured via standard lithography. The resulting optical constants indicate a reduced refractive index, n, and increased extinction coefficient, k, when compared to purer TiO2 thin films deposited via a physical vapor deposition (PVD) method, reflecting the influence of nitrogen incorporation on the optical properties. 

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5. Epitaxial Thin Film Growth on Recycled SrTiO ₃ Substrates Toward Sustainable Processing of Complex Oxides

   https://doi.org/10.1002/smtd.202401148  

   Shen, Jianan; Quigley, Lizabeth; Barnard, James P; Lu, Ping; Tsai, Benson Kunhung; Zemlyanov, Dmitry; Zhang, Yizhi; Sheng, Xuanyu; Gan, Jeremy; Moceri, Matteo; et al (April 2025, Small Methods)

   Abstract Complex oxide thin films cover a range of physical properties and multifunctionalities that are critical for logic, memory, and optical devices. Typically, the high‐quality epitaxial growth of these complex oxide thin films requires single crystalline oxide substrates such as SrTiO₃(STO), MgO, LaAlO₃, a‐Al₂O_3,and many others. Recent successes in transferring these complex oxides as free‐standing films not only offer great opportunities in integrating complex oxides on other devices, but also present enormous opportunities in recycling the deposited substrates after transfer for cost‐effective and sustainable processing of complex oxide thin films. In this work, the surface modification effects introduced on the recycled STO are investigated, and their impacts on the microstructure and properties of subsequently grown epitaxial oxide thin films are assessed and compared with those grown on the pristine substrates. Detailed analyses using high‐resolution scanning transmission electron microscopy and geometric phase analysis demonstrate distinct strain states on the surfaces of the recycled STO versus the pristine substrates, suggesting a pre‐strain state in the recycled STO substrates due to the previous deposition layer. These findings offer opportunities in growing highly mismatched oxide films on the recycled STO substrates with enhanced physical properties. Specifically, yttrium iron garnet (Y₃Fe₅O₁₂) films grown on recycled STO present different ferromagnetic responses compared to that on the pristine substrates, underscoring the effects of surface modification. The study demonstrates the feasibility of reuse and redeposition using recycled substrates. Via careful handling and preparation, high‐quality epitaxial thin films can be grown on recycled substrates with comparable or even better structural and physical properties toward sustainable process of complex oxide devices. 

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