c Bi-exponential fitting based on the IVIM measurements.
c Bi-assisted CdTe NWs grown on a Au-coated film at 460 °C.
and f k − = ∑ a ∈ k c ai 2 + c ai ∑ b ≠ a c bi S ab (where i = HOMO) (13).
Open image in new window Fig. 4 Time-on-stream tests for 1 % LNZ catalyst at 750 °C for a dry-reforming, b oxy-reforming, c bi-reforming.
LoRa supported functionalities can be classified to three classes: class A (bi-directional end-devices), class B (bi-directional end-devices with scheduled receive slots), and class C (bi-directional end-devices with maximal receive slots).
Five different cases are analyzed: Case A: Bi-convection thickness-wise Bi-metallic fins; Case B: Bi-convection span-wise rectangular fins; Case C: Bi-convection longitudinal-wise fins; Case D: Bi-convection perimeter-wise fins with uniform cross-section; and Case E: Bi-convection perimeter-wise permeable fins.
The catalyst was tested under three reforming reaction conditions at a reference temperature of 750 °C: (a) dry-reforming (reaction 1), (b) oxy-reforming (reaction 2), and (c) bi-reforming (reaction 3).
c Bi content profiles along [001] direction extracted after integration of an area of around 130 nm from the EDX map of samples S1 (blue line) and S2 (black line).
It was found that the exponent n was independent on the normalized crack extension and specimen thickness, whereas the parameter log(c) bi-linearly decreased with the normalized crack extension and kept constant once fibre bridging became saturation.
It is possible to evaluate condensed Fukui functions from single-points calculations directly, without resorting to additional calculations involving the systems with N-1 and N+1 electrons: f k + = ∑ a ∈ k c ai 2 + c ai ∑ b ≠ a c bi S ab (where i = LUMO) (12).
The catalyst was characterized by H2-TPR, and pre- and post-reaction XRD, and tested for its methane-reforming activity under three different reaction conditions: (a) dry-reforming (CH4 + CO2), (b) oxy-CO2 reforming (CH4 + CO2 + O2), and (c) bi-reforming (CH4 + CO2 + H2O).
