TY - JOUR
T1 - Liquid lithium wetting and percolation in a porous tungsten/liquid Li plasma facing component (PFC)
AU - Kapat, A.
AU - Allain, J. P.
AU - Bedoya, F.
AU - Woller, K. B.
N1 - Publisher Copyright:
© 2022
PY - 2022/5
Y1 - 2022/5
N2 - This work explores the concept of a hybrid material system designed to protect the plasma from high-Z material emission while also protecting an underlying high-Z wall material from erosion by integrating a low-Z component in the liquid phase. Plasma-surface interaction properties of a porous tungsten (W)-liquid metal hybrid system, having the favorable bulk thermomechanical properties of W while serving as a scaffold for a liquid metal with self-healing and radiative vapor shielding characteristics, are examined. W-substrates with 70% density of bulk W and 1–5 μm sized pores have been fabricated with 50-nm W powders using spark plasma sintering. Enhanced lithium (Li) wettability, driven by percolation through the porous W architecture, is demonstrated with in-situ liquid Li drop measurements. Results show complete wetting of liquid Li at 250 °C in the porous W, 100 °C lower temperature than what has been observed on traditional W surfaces. In operando ion beam analysis of Li films deposited on porous W substrates provides microscopic evidence of Li percolation into the substrate and a first look at D retention up to a depth of 100 nm after plasma exposure at a flux of 1020 m−2s−1, 250 eV/amu D+ plasma to a fluence of 1.16 × 1023 m−2 at a temperature of 200 °C.
AB - This work explores the concept of a hybrid material system designed to protect the plasma from high-Z material emission while also protecting an underlying high-Z wall material from erosion by integrating a low-Z component in the liquid phase. Plasma-surface interaction properties of a porous tungsten (W)-liquid metal hybrid system, having the favorable bulk thermomechanical properties of W while serving as a scaffold for a liquid metal with self-healing and radiative vapor shielding characteristics, are examined. W-substrates with 70% density of bulk W and 1–5 μm sized pores have been fabricated with 50-nm W powders using spark plasma sintering. Enhanced lithium (Li) wettability, driven by percolation through the porous W architecture, is demonstrated with in-situ liquid Li drop measurements. Results show complete wetting of liquid Li at 250 °C in the porous W, 100 °C lower temperature than what has been observed on traditional W surfaces. In operando ion beam analysis of Li films deposited on porous W substrates provides microscopic evidence of Li percolation into the substrate and a first look at D retention up to a depth of 100 nm after plasma exposure at a flux of 1020 m−2s−1, 250 eV/amu D+ plasma to a fluence of 1.16 × 1023 m−2 at a temperature of 200 °C.
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U2 - 10.1016/j.fusengdes.2022.113087
DO - 10.1016/j.fusengdes.2022.113087
M3 - Article
AN - SCOPUS:85126070714
SN - 0920-3796
VL - 178
JO - Fusion Engineering and Design
JF - Fusion Engineering and Design
M1 - 113087
ER -