J.A. Torres-Ochoa scite author profile

The background in X-ray photoelectron spectroscopy data originates, partially, from inelastically scattered photoelectrons. In fact, the current theoretical methods for calculating the background intensity are based on electron energy losses. However, a critical part of the experimental signal, which is known as the Shirley background, cannot be described within the current formalisms. This suggests that the Shirley electrons are not associated with energy losses of photoelectrons and must originate from a different photoexcitation phenomenon with a cross section of its own.We propose a mechanism based on core channeling as the physical origin of the Shirley signal.

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Accelerated weathering study of extruded polyethylene/poly (lactic acid)/chitosan films

Lizárraga-Laborín

Quiroz-Castillo

Encinas

et al. 2018

Polymer Degradation and Stability

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Study of the dehydroxylation of kaolinite and alunite from a Mexican clay with DRIFTS-MS

et al. 2016

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Few reports exist on the use of Diffuse Reflectance Infrared Fourier Transform Spectrometry coupled with Mass Spectrometry (DRIFTS-MS) in situ to monitor the dehydroxylation of kaolinitic clays. The use of DRIFTS-MS in situ allows study of the effect of heat treatment on the dehydroxylation, identifying intensities and temperatures at which the hydroxyl groups are released, forming metakaolinite and meta-alunite. The effluent gases from the infrared cell were analysed by mass spectrometry. The decrease in intensity of the bands at 3694, 3669, 3650 and 3621 cm−1 associated with the −OH stretching vibration modes of AlVI−OH−AlVI of kaolinite began at 450°C. Two additional bands at 3513 and 3485 cm−1 are associated with the vibration of AlVI−OH of alunite that also began to disappear during thermal treatment. Monitoring of the fractions m/e 17 and 18 using a mass spectrometer revealed that the intensity of these fractions increased starting at 450°C. Therefore, it is possible to study the dehydroxylation process of clays during thermal treatment.Chemical and mineralogical characterization of a kaolinitic clay (KN) fromMexico showed that the clay consists of 64.8% kaolinite, 11.0% alunite and 24.4% quartz based on PXRD, EDS, TG/DTA, TEM and FTIR results, and suggested that the material might have potential for use in the manufacture of ceramics, refractory bricks or geopolymers.

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Low-temperature sol-gel ZrHfO2-PMMA hybrid dielectric thin-films for metal oxide TFTs

Rao¹,

Pacheco-Zuñiga

Garcı́a-Cerda

et al. 2018

Journal of Non-Crystalline Solids

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Dielectric constant measurement using atomic force microscopy of dielectric films: a system theory approach

et al. 2018

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J.A. Torres-Ochoa

Intensity modulation of the Shirley background of the Cr 3p spectra with photon energies around the Cr 2p edge

Accelerated weathering study of extruded polyethylene/poly (lactic acid)/chitosan films

Study of the dehydroxylation of kaolinite and alunite from a Mexican clay with DRIFTS-MS

Low-temperature sol-gel ZrHfO2-PMMA hybrid dielectric thin-films for metal oxide TFTs

Dielectric constant measurement using atomic force microscopy of dielectric films: a system theory approach

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