An improved laboratory-based x-ray absorption fine structure and x-ray emission spectrometer for analytical applications in materials chemistry research

Jahrman, Evan P.; Holden, William M.; Ditter, Alexander S.; Mortensen, Devon R.; Seidler, Gerald T.; Fister, Timothy T.; Kozimor, Stosh A.; Piper, Louis F. J.; Rana, Jatinkumar; Hyatt, Neil C.; Stennett, Martin C.

doi:10.1063/1.5049383

Cited by 86 publications

(61 citation statements)

References 110 publications

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“…The concentration of each oxidation state of vanadium cations was estimated from the corresponding peak area percentage. The overall vanadium oxidation states of the samples were examined by X‐ray absorption near‐edge structure measurements in the vanadium K‐edge using laboratory‐based instrumentation (University of Washington), and analyzed with a reported methodology . Fitting was performed in Mathematica with the energy from 5460 to 5490 eV, using the function NonlinearModelFit through a linear combination of the spectra of reference compounds.…”

Section: Methodsmentioning

confidence: 99%

Interface Engineering V₂O₅ Nanofibers for High‐Energy and Durable Supercapacitors

Wang

Jahrman

et al. 2019

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been made on elaborating the electrode materials with higher energy density for supercapacitors to meeting ever-increasing requirements. The energy density (E) of a supercapacitor is mainly dependent on the specific capacitance (C) and cell potential window (V) of electrode materials according to the equation E = 1/2CV 2 . [3] Thus, developing electrode materials with enhanced specific capacitance is crucial for high-energy supercapacitors. Carbonaceous material based electric double-layer capacitors appear with a low capacitance due to the physical absorption/desorption at the electrode surface. [4] Comparatively, transition metal oxides (TMOs) and conductive polymers (CPs) based pseudocapacitors exhibit higher theoretical storage capacitance because of the reversible faradic reactions on or near the electrode surface. [5] Vanadium pentoxide (V 2 O 5 ), a layer-structured TMO, has prospective applications in electrochemical energy storage due to its high theoretical capacitance (2020 F g −1 ), a broader operating voltage( up to ≈2.8 V), as well as low cost and abundance in nature. [6] However, the poor electrical conductivity of V 2 O 5 (10 −3 to 10 −2 S cm −1 ) limits the electron transfer kinetics for redox reactions. As a result, the pseudocapacitive reactions mainly occur on the surface or near-surface region of V 2 O 5 electrode materials, leading to a low utilization of V 2 O 5 and unsatisfactory specific capacitance. [7] In addition, the vanadium dissolution and structural instability reduces its cycling life. [8] To address these problems, many synthetic methods have been proposed. First, nanostructured V 2 O 5 materials with a large specific surface area are fabricated to provide sufficient contact area for fast Faradic reactions, such nanoribbons, [9] and nanobelts. [10] Second, tailoring the materials with multiple physicochemical properties can effectively enhance the electrochemical performance of V 2 O 5 with diverse functions from components. For instance, layered V 2 O 5 /poly(3,4-ethylenedioxythiophene) (PEDOT)/MnO 2 nanosheets show enhanced energy density (39.2 W h kg −1 ) and cycling stability (93.5% capacitance retention after 3000 cycles) due to the synergistic combination of PEDOT, MnO 2 , and V 2 O 5 . [11] However, V 2 O 5 electrode materials with enhanced electrochemical performance, fabricated in an uncomplicated and low-cost process are still necessary for practical applications. Based on the previous study, both polyaniline (PANI) and PEDOT improve the electrical conductivity as well as the stability of V 2 O 5 by forming a conductive coating, [8,11] A local electric field is induced to engineer the interface of vanadium pentoxide nanofibers (V 2 O 5 -NF) to manipulate the charge transport behavior and obtain high-energy and durable supercapacitors. The interface of V 2 O 5 -NF is modified with oxygen vacancies (Vö) in a one-step polymerization process of polyaniline (PANI). In the charge storage process, the local electric field deriving from the lopsided charge distribution arou...

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Section: Methodsmentioning

confidence: 99%

Interface Engineering V₂O₅ Nanofibers for High‐Energy and Durable Supercapacitors

Wang

Jahrman

et al. 2019

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“…[34][35][36] To date, most vtc-XES measurements have been performed at high-brightness user facilities, such as synchrotrons, while a few groups have developed laboratory-based systems. [37][38][39][40][41][42][43][44] A constant in all previous vtc-XES measurements is the use of wavelength dispersive detection techniques, where specially designed gratings or crystals are used to spatially separate the different photon energies in the emission spectrum. In earlier work, we have described a tabletop apparatus capable of performing static and dynamic XES measurements in the Kα and Kβ regions using a combination of a laser-based plasma source and energy-resolving cryogenic sensors.…”

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confidence: 99%

Valence‐to‐core X‐ray emission spectroscopy of titanium compounds using energy dispersive detectors

et al. 2020

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X-ray emission spectroscopy (XES) of transition metal compounds is a powerful tool for investigating the spin and oxidation state of the metal centers. Valence-to-core (vtc) XES is of special interest, as it contains information on the ligand nature, hybridization, and protonation. To date, most vtc-XES studies have been performed with high-brightness sources, such as synchrotrons, due to the weak fluorescence lines from vtc transitions. Here, we present a systematic study of the vtc-XES for different titanium compounds in a laboratory setting using an X-ray tube source and energy dispersive microcalorimeter sensors. With a full-width at half-maximum energy resolution of approximately 4 eV at the Ti Kβ lines, we measure the XES features of different titanium compounds and compare our results for the vtc line shapes and energies to previously published and newly acquired synchrotron data as well as to new theoretical calculations. Finally, we report simulations of the feasibility of performing time-resolved vtc-XES studies with a laser-based plasma source in a laboratory setting. Our results show that microcalorimeter sensors can already perform high-quality measurements of vtc-XES features in a laboratory setting under static conditions and that dynamic measurements will be possible in the future after reasonable technological developments. 1 | INTRODUCTION Non-resonant X-ray emission spectroscopy (XES) is a powerful technique for the study of occupied electron orbitals in the valence shell with elemental selectivity and under in situ conditions. 1-8 In XES, X-ray photons with energy greater than the binding energy of an innershell electron produce core-hole vacancies. These core holes are quickly filled by the relaxation of less tightly bound electrons with concomitant X-ray fluorescence or

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“…One approach for novel XAS instrumentation employs spherically bent crystals in Rowland geometry. [2][3][4][5][6] These scanning type spectrometers offer spectral resolutions down to around 1 eV. Applications were, for example, reported in catalysis research, 7 environmental research 8 and in the investigation of actinides.…”

Section: Introductionmentioning

confidence: 99%

Recent progress in the performance of HAPG based laboratory EXAFS and XANES spectrometers

Schlesiger

Praetz

Gnewkow

et al. 2020

J. Anal. At. Spectrom.

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An improved laboratory-based x-ray absorption fine structure and x-ray emission spectrometer for analytical applications in materials chemistry research

Cited by 86 publications

References 110 publications

Interface Engineering V₂O₅ Nanofibers for High‐Energy and Durable Supercapacitors

Interface Engineering V₂O₅ Nanofibers for High‐Energy and Durable Supercapacitors

Valence‐to‐core X‐ray emission spectroscopy of titanium compounds using energy dispersive detectors

Recent progress in the performance of HAPG based laboratory EXAFS and XANES spectrometers

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An improved laboratory-based x-ray absorption fine structure and x-ray emission spectrometer for analytical applications in materials chemistry research

Cited by 86 publications

References 110 publications

Interface Engineering V2O5 Nanofibers for High‐Energy and Durable Supercapacitors

Interface Engineering V2O5 Nanofibers for High‐Energy and Durable Supercapacitors

Valence‐to‐core X‐ray emission spectroscopy of titanium compounds using energy dispersive detectors

Recent progress in the performance of HAPG based laboratory EXAFS and XANES spectrometers

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Product

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Interface Engineering V₂O₅ Nanofibers for High‐Energy and Durable Supercapacitors

Interface Engineering V₂O₅ Nanofibers for High‐Energy and Durable Supercapacitors