Smartlab theta theta diffractometer

Manufactured by Rigaku

The SmartLab theta-theta diffractometer is a versatile X-ray diffraction (XRD) instrument manufactured by Rigaku. It is designed to perform high-resolution powder and thin-film XRD measurements. The instrument features a theta-theta goniometer configuration, which allows for the sample and detector to rotate synchronously, providing precise control over the incident and diffracted X-ray beam angles.

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Lab products found in correlation

Axis supra x ray photoelectron spectrometer, by Shimadzu (2 mentions) Uv 1600pc, by Avantor (2 mentions) Flir ets320, by Teledyne (2 mentions) S 4700, by Hitachi (2 mentions)

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SmartLab diffractometer SmartLab

2 protocols using smartlab theta theta diffractometer

Comprehensive Characterization of Functional Nanocomposites

Check if the same lab product or an alternative is used in the 5 most similar protocols

The SEM images were taken by the field emission scanning electron microscope (Hitachi S-4700 with EDS). The XPS spectra were obtained by Kratos Axis Supra x-ray photoelectron spectrometer, allowing to determine the elemental composition of the top ~ 10 nm of the sample surface. The XRD patterns of functional nanocomposites were obtained using the Rigaku SmartLab theta-theta diffractometer. The FTIR spectra were recorded using Hyperion 1000 with Tensor 27 spectrometer. The thermal images were taken with an infrared (IR) camera (FLIR ETS320). The performance of the drug-release patch was characterized with a Ultraviolet-visible (UV-vis) spectrometer (VWR UV-1600PC).

Bai W., Zhang L., Xing S., Yin H., Weisbecker H., Tran H.T., Guo Z., Han T., Wang Y., Liu Y., Wu Y., Xie W., Huang C., Luo W., Demaesschalck M., McKinney C., Hankley S., Huang A., Brusseau B., Messenger J, & Zou Y. (2023). Skin-inspired, sensory robots for electronic implants. Research Square.

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Characterization of Functional Nanocomposites

Check if the same lab product or an alternative is used in the 5 most similar protocols

The SEM images were taken by the field emission scanning electron microscope (Hitachi S-4700 with EDS). The XPS spectra were obtained by Kratos Axis Supra x-ray photoelectron spectrometer, allowing to determine the elemental composition of the top ~10 nm of the sample surface. The XRD patterns of functional nanocomposites were obtained using the Rigaku SmartLab theta-theta diffractometer. The FTIR spectra were recorded using Hyperion 1000 with Tensor 27 spectrometer. The thermal images were taken with an infrared (IR) camera (FLIR ETS320). The performance of the drug-release patch was characterized with a Ultraviolet-visible (UV-vis) spectrometer (VWR UV-1600PC).

Zhang L., Xing S., Yin H., Weisbecker H., Tran H.T., Guo Z., Han T., Wang Y., Liu Y., Wu Y., Xie W., Huang C., Luo W., Demaesschalck M., McKinney C., Hankley S., Huang A., Brusseau B., Messenger J., Zou Y, & Bai W. (2024). Skin-inspired, sensory robots for electronic implants. Nature communications, 15(1).

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