<b>Wind speed manipulation experimental data from the Community Land Model version 5 (CLM5)</b> by Haohao Wu (18243244)

“…Then, experimental simulations were conducted using CLM5 for varying wind speed scenarios for the period of 1983 – 2014, including:</p><p dir="ltr">i) Control run: The simulation was forced by the default air forcing dataset of CLM5 – CRUNCEP version 7 meteorological data (6-hourly data; https://rda.ucar.edu/datasets), except for wind speed, which was replaced by data from the CRU JRA version 2.2 dataset, because the CRUNCEP7 wind speed revealed widespread increasing trend of terrestrial wind speed during 1983 – 2014, inconsistent with observations; in contrast, CRU JRA2.2 wind speed showed overall decreasing trend of terrestrial wind speed during the same period. …”

Mean TOC concentration and mean bacterioplankton abundance for Santa Barbara Channel phytoplankton-DOC experiments. by Anna K. James (3812875)

Transfluthrin repellency depends on its action on voltage-gated sodium channels. by Felipe Andreazza (11098928)

Illustrations of the SeqFold2D network and the Stralign dataset. by Xiangyun Qiu (316117)

Repellency by commercial transfluthrin products consists of both Or-mediated and Or-independent repellency in <i>Ae</i>. <i>aegypti</i>. by Felipe Andreazza (11098928)

Transfluthrin repellency does not requires activation of Ors in <i>Ae</i>. <i>aegypti</i>. by Felipe Andreazza (11098928)

Acclimation of <i>V_c,max25</i> (<i>V_{c, max}</i> scaled to 25°C) to altered environmental conditions. by Chonggang Xu (108726)

“…The change of <i>V_c,max25</i> to environmental conditions in our model results from a decrease or an increase in nitrogen allocation to carboxylation. …”

Ethanol Oxidation by Imidorhenium(V) Complexes:  Formation of Amidorhenium(III) Complexes by Annette L. Suing (2962386)

“…Complexes <b>1-H</b> (orthorhombic, <i>Pcab</i>, <i>a</i> = 22.3075(10) Å, <i>b</i> = 23.1271(10) Å, <i>c</i> = 23.3584(10) Å, <i>Z</i> = 8), <b>1-Cl</b> (triclinic, <i>P</i>1̄, <i>a</i> = 11.9403(6) Å, <i>b</i> = 14.6673(8) Å, <i>c</i> = 17.2664(9) Å, α = 92.019(1)°, β = 97.379(1)°, γ = 90.134(1)°, <i>Z</i> = 2), and <b>1-OMe</b> (triclinic, <i>P</i>1, <i>a</i> = 11.340(3) Å, <i>b</i> = 13.134(4) Å, <i>c</i> = 13.3796(25) Å, α = 102.370(20)°, β = 107.688(17)°, γ = 114.408(20)°, <i>Z</i> = 1) are crystallographically characterized and show an average Re−N bond length (1.71 Å) typical of imidorhenium(V) complexes. There is a small systematic decrease in the Re−N bond length on going from Cl to H to OMe. …”

2D cross-sectional plots of pre-polarisation field B_p along the x-axis (switched on). by Michael W. Vogel (2819560)

“…(b) For array <i>A</i> with constant magnet size, the field strength decreases with decreasing numbers of magnets. (c) Within the FOV the field inhomogeneity decreases slightly with decreasing numbers of magnets for both constant fill factor (c) and magnet size (d). …”

Lipidic <i>Carbo</i>-benzenes: Molecular Probes of Magnetic Anisotropy and Stacking Properties of α‑Graphyne by Chongwei Zhu (1825735)

“…The products display classical UV–vis electronic spectra of <i>carbo</i>-benzenes in solution (λ_max = 445.5 ± 1 nm, ε ≈ 200 000 L·mol^–1·cm^–1). …”

The full characterization of the V Kβ spectral profile on an absolute energy scale by C T Chantler (557430)

“…The peak energy of the titanium Kβ spectral profile is found to be 4931.966 ± 0.022 eV prior to instrumental broadening. This 4.5 ppm result decreases the uncertainty over the past literature by a factor of 2.6 and is 2.4 standard deviations from the previous standard. …”

Fig 2 - by Andreas Schmittner (18990473)

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”