F82H data from Xu 2017

h_transport_materials/property_database/rafm_steel.py

@@ -222,6 +222,69 @@
 )
 
 
+xu_permeability_h = htm.Permeability(
+    pre_exp=1.0e-9 * u.mol * u.cm**-1 * u.s**-1 * u.Pa**-0.5,
+    act_energy=0.46 * u.eV * u.particle**-1,
+    range=(u.Quantity(150, u.degC), u.Quantity(500, u.degC)),
+    isotope="H",
+    source="xu_bi-directional_2017",
+    note="Eq 2, F82H",
+)
+
+xu_permeability_d = htm.Permeability(
+    pre_exp=6.8e-10 * u.mol * u.cm**-1 * u.s**-1 * u.Pa**-0.5,
+    act_energy=0.46 * u.eV * u.particle**-1,
+    range=(u.Quantity(150, u.degC), u.Quantity(500, u.degC)),
+    isotope="D",
+    source="xu_bi-directional_2017",
+    note="Eq 3, F82H",
+)
+
+xu_diffusivity_h = htm.Diffusivity(
+    D_0=9.9e-4 * u.cm**2 * u.s**-1,
+    E_D=0.14 * u.eV * u.particle**-1,
+    range=(u.Quantity(250, u.degC), u.Quantity(500, u.degC)),
+    isotope="H",
+    source="xu_bi-directional_2017",
+    note="Eq 5, F82H, effective diffusivity",
+)
+
+xu_diffusivity_d = htm.Diffusivity(
+    D_0=7.2e-4 * u.cm**2 * u.s**-1,
+    E_D=0.14 * u.eV * u.particle**-1,
+    range=(u.Quantity(250, u.degC), u.Quantity(500, u.degC)),
+    isotope="D",
+    source="xu_bi-directional_2017",
+    note="Eq 6, F82H, effective diffusivity",
+)
+
+xu_solubility_h = htm.Solubility(
+    S_0=1.0e-6 * u.mol * u.cm**-3 * u.Pa**-0.5,
+    E_S=0.32 * u.eV * u.particle**-1,
+    range=(u.Quantity(250, u.degC), u.Quantity(500, u.degC)),
+    isotope="H",
+    source="xu_bi-directional_2017",
+    note="Eq 8, F82H",
+)
+
+xu_solubility_d = htm.Solubility(
+    S_0=9.4e-7 * u.mol * u.cm**-3 * u.Pa**-0.5,
+    E_S=0.32 * u.eV * u.particle**-1,
+    range=(u.Quantity(250, u.degC), u.Quantity(500, u.degC)),
+    isotope="D",
+    source="xu_bi-directional_2017",
+    note="Eq 9, F82H",
+)
+
+xu_recombination_coeff_d = htm.RecombinationCoeff(
+    pre_exp=3.8e-17 * u.particle**-1 * u.cm**4 * u.s**-1,
+    act_energy=-0.20 * u.eV * u.particle**-1,
+    range=(u.Quantity(250, u.degC), u.Quantity(510, u.degC)),
+    isotope="D",
+    source="xu_bi-directional_2017",
+    note="Eq 11, F82H",
+)
+
 properties = [
     causey_diffusivity,
     forcey_diffusivity,
@@ -245,6 +308,13 @@
     kulsartov_solubility_d,
     serra_solubility_f82h,
     serra_solubility_batman,
+    xu_permeability_h,
+    xu_permeability_d,
+    xu_diffusivity_h,
+    xu_diffusivity_d,
+    xu_solubility_h,
+    xu_solubility_d,
+    xu_recombination_coeff_d,
 ]
 
 for prop in properties:

h_transport_materials/references.bib

@@ -2704,4 +2704,20 @@ @article{fuerst_hastelloyn_2024
 	author = {Thomas F. Fuerst and Masashi Shimada and Hanns Gietl and Paul W. Humrickhouse},
 	keywords = {Hydrogen, Tritium, Permeation, Hastelloy N, FLiBe},
 	abstract = {Hastelloy N was chosen as the fluoride salt-contacting structural material for the Molten Salt Reactor Experiment due to its excellent compatibility with the fuel salt FLiBe. FLiBe is currently investigated for several advanced fusion and fission reactor concepts where tritium generation in the FLiBe is anticipated. Knowledge of hydrogen transport properties through Hastelloy N is important to understand how tritium would permeate through this material and result in an unintentional release. In this study, the hydrogen and deuterium permeability, diffusivity, and solubility were measured from 500 to 700 °C at a primary-side pressure of 10 kPa in a well-characterized sample of Hastelloy N. The prepared polycrystalline Hastelloy N had C and O impurities present on the surface. These impurities were investigated using Auger Emission Spectroscopy and Ar depth profiling. The adventitious C was removed upon the first Ar sputter cycle whereas O persisted deeper into the sample. For permeation experiments, applied deuterium pressures ranged from 13 Pa to 100 kPa and deuterium transport remained in the diffusion-limited regime (J ∝ P0.5) throughout the pressure range examined. Two methods are employed to measure the effective hydrogen and deuterium diffusivity: rise and decline. The decline method produced improved statistical model fits for calculating the effective diffusion coefficient compared to the rise method. The resultant transport properties compared well to published values for other nickel alloys.}
+}
+
+@article{xu_bi-directional_2017,
+	title = {Bi-directional hydrogen isotopes permeation through a reduced activation ferritic steel {F82H}},
+	volume = {125},
+	issn = {0920-3796},
+	url = {https://www.sciencedirect.com/science/article/pii/S0920379617304258},
+	doi = {10.1016/j.fusengdes.2017.04.022},
+	abstract = {The first wall of a magnetic fusion reactor serves to separate the edge plasma from breeding blankets, which will be subjected to bi-directional hydrogen isotopes permeation: in one direction by plasma-driven permeation, and in the other direction by gas-driven permeation. In this work, hydrogen isotopes transport through a reduced activation ferritic steel F82H has been investigated in the temperature range of 150–500°C. The transport parameters including permeability, diffusivity, solubility and surface recombination coefficient have been measured and the isotopic mass effect has been discussed. Bi-directional hydrogen isotopes gas- and plasma-driven permeation has been demonstrated for the first time under controlled experimental conditions.},
+	urldate = {2024-06-05},
+	journal = {Fusion Engineering and Design},
+	author = {Xu, Yue and Hirooka, Yoshi and Nagasaka, Takuya},
+	month = dec,
+	year = {2017},
+	keywords = {F82H, First wall, Gas- and plasma-driven permeation, Isotopic effect, Transport parameters},
+	pages = {343--348},
 }