Sulfur Poisoning of Ni Anode as a Function of Operating Conditions in Solid Oxide Fuel Cells

Lee, Ho Seong; Lee, Hyun Mi; Lim, Hyung‐Tae

doi:10.3365/kjmm.2018.56.12.893

Cited by 4 publications

(6 citation statements)

References 25 publications

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“…In contrast, the current density was relatively stable in the 2nd drop section at 0.9 V (corresponding to a lower current density), in both 5 and 100 ppm; the lower the current density, the lower the drop % value in the 2nd drop section, which is the opposite to that in the 1st drop section. A higher degradation rate with higher current density was also observed in our previous studies and in other studies [20, 23, 25, 47]. The slow and continuous performance degradation in the 2nd drop section is related to irreversible anode microstructure changes (Ni oxidation and/or agglomeration), accelerated by increasing the current density.…”

Section: Resultssupporting

confidence: 87%

Spatial sulfur poisoning behavior associated with in‐plane electrochemical performance variation of solid oxide fuel cells

Kim

Park

et al. 2022

Fuel Cells

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In this study, sulfur poisoning behavior is investigated on a 5 × 5 cm 2 anodesupported cell as a function of H 2 S concentration, cell voltage, and in-plane region. At a lower cell voltage, the 1st drop % in the current density decreases by promoting sulfur desorption while the 2nd drop % increases slightly. The outlet regions with poor performance show a lower drop % owing to the water vapor effect, while the inlet regions with superior performance show a higher drop %, especially at high H 2 S concentrations. Ni oxidation in the inlet regions is caused by the substantial 2nd drop under the combined conditions of high current density and H 2 S concentration, whereas that in the outlet region is caused by the high H 2 O concentration. The results indicate that in-plane performance variation may aggravate sulfur poisoning in the inlet regions, whereas it may lead to Ni oxidation in the outlet regions.

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Section: Resultssupporting

confidence: 87%

Spatial sulfur poisoning behavior associated with in‐plane electrochemical performance variation of solid oxide fuel cells

Kim

Park

et al. 2022

Fuel Cells

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“…Among the state‐of‐the‐art thermoelectric materials, tin selenide (SnSe) is one of the most promising candidates to apply to thermoelectric devices due to its environmentally friendly feature, high cost‐effectiveness, and outstanding thermoelectric performance derived from its appropriate bandgap of ≈0.9 eV and intrinsic low κ l 9,10 . Figure a shows the development timeline for all SnSe‐based bulk thermoelectric materials,11–124 from which a record high ZT of ≈2.8 at 773 K was found in the n‐type SnSe single crystal,11 derived from its ultralow κ l of ≈0.18 W m −1 K −1 and high S 2 σ of ≈9.0 µW cm −1 K −2 at this temperature 125. Such a high ZT is also very competitive to other state‐of‐the‐art thermoelectric systems which possess ZTs > 2, such as PbTe,126–134 GeTe,135–147 Cu 2 Se/Cu 2 S,148–157 and AgSbTe 2 158.…”

Section: Introductionmentioning

confidence: 97%

“…A summary of ZTs for SnSe‐based thermoelectric materials. a) The timeline for state‐of‐the‐art SnSe bulks thermoelectric materials,11–124,169–182 the performance achieved by solution route are circled by yellow. b) Temperature‐dependent ZT and c) corresponding peak and average ZT values for polycrystalline SnSe through different fabrication techniques 13,16,22,46,58,62,95,99,101.…”

Section: Introductionmentioning

confidence: 99%

High‐Performance Thermoelectric SnSe: Aqueous Synthesis, Innovations, and Challenges

2020

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Tin selenide (SnSe) is one of the most promising candidates to realize environmentally friendly, cost‐effective, and high‐performance thermoelectrics, derived from its outstanding electrical transport properties by appropriate bandgaps and intrinsic low lattice thermal conductivity from its anharmonic layered structure. Advanced aqueous synthesis possesses various unique advantages including convenient morphology control, exceptional high doping solubility, and distinctive vacancy engineering. Considering that there is an urgent demand for a comprehensive survey on the aqueous synthesis technique applied to thermoelectric SnSe, herein, a thorough overview of aqueous synthesis, characterization, and thermoelectric performance in SnSe is provided. New insights into the aqueous synthesis‐based strategies for improving the performance are provided, including vacancy synergy, crystallization design, solubility breakthrough, and local lattice imperfection engineering, and an attempt to build the inherent links between the aqueous synthesis‐induced structural characteristics and the excellent thermoelectric performance is presented. Furthermore, the significant advantages and potentials of an aqueous synthesis route for fabricating SnSe‐based 2D thermoelectric generators, including nanorods, nanobelts, and nanosheets, are also discussed. Finally, the controversy, strategy, and outlook toward future enhancement of SnSe‐based thermoelectric materials are also provided. This Review guides the design of thermoelectric SnSe with high performance and provides new perspectives as a reference for other thermoelectric systems.

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“…Meanwhile, other efforts have been focused on discovering new thermoelectric materials. Among the various new thermoelectric materials, post-transition metal chalcogenides such as SnSe [9], In 4 Se 3 [10] and In 2 Se 3 [11], which consist of a two-dimensional layered structure, have attracted significant attention due to their intrinsically low lattice thermal conductivity (κ latt ), which is caused by the weak atomic bonding between layers (van der Waals bonds).…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, SnSe and In 4 Se 3 materials exhibit a special phenomenon in which lattice softening [9] of the charge density wave (CDW) [10] occurs as the temperature increases.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Thermoelectric Transport Properties of n-type InSe by Sn doping

Choo¹,

Hong²,

Kim³

et al. 2020

Korean J. Met. Mater.

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Layered post transition metal chalcogenides such as SnSe, SnSe2, In2Se3, and In4Se3 have attracted attention as promising thermoelectric materials due to their intrinsically low lattice thermal conductivities. Recently, n-type indium selenide (InSe) based materials have also been suggested as good candidates for thermoelectric materials by optimizing their electrical properties, i.e., increasing carrier concentration. Here, we report enhancement of the thermoelectric properties of n-type InSe by Sn substitutional doping at the In site. A series of In1-xSnxSe for x = 0, 0.03, 0.05, 0.15 and 0.2 was examined. The carrier concentration and electrical conductivity increased due to the Sn substitution, since Sn behaves as a shallow electron donor in InSe, while the Seebeck coefficient decreased moderately. In addition, it was found that effective mass was increased by more than 10 times by Sn doping. As a result, the power factor was enhanced from 0.07 mW/mK2 to 0.13 mW/mK2 at 800 K. The total thermal conductivity was unchanged despite Sn doping because the electrical contribution to the total thermal conductivity was very small. Consequently, Sn doping in InSe enhanced the dimensionless thermoelectric figure of merit zT from 0.04 to 0.14 at 800 K, mainly due to enhanced electrical properties.

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Sulfur Poisoning of Ni Anode as a Function of Operating Conditions in Solid Oxide Fuel Cells

Cited by 4 publications

References 25 publications

Spatial sulfur poisoning behavior associated with in‐plane electrochemical performance variation of solid oxide fuel cells

Spatial sulfur poisoning behavior associated with in‐plane electrochemical performance variation of solid oxide fuel cells

High‐Performance Thermoelectric SnSe: Aqueous Synthesis, Innovations, and Challenges

Enhanced Thermoelectric Transport Properties of <i>n</i>-type InSe by Sn doping

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