通过激光烧蚀电极支架改善固体氧化物电池中的气体扩散

Saahir Ganti-Agrawal, Dalton Cox, Scott A Barnett
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To test the difference in mass transport through patterned and pristine electrode supports, symmetric electrode-supported Ni-YSZ cells are patterned on one side, which enables comparison of the electrochemical performance of two otherwise identical electrodes (Figure 1a). Cells with varying pattern geometry, pore geometries, Ni/YSZ ratios, and Ni-YSZ particle sizes were created to fully understand how the support layer microstructure and macrostructure affects the cell performance. Patterned and pristine cells were tested together at three temperatures (600C, 700C, and 800C) in a 97%H 2 :3%H 2 O environment, chosen to produce a clear gas diffusion limitation in H 2 O electrolysis. j-V sweeps and electrochemical impedance spectroscopy (EIS) were carried out on each cell at each test condition, and the microstructure of patterned and control supports was characterized through SEM imaging. Upon removing the ohmic portion and fitting the j-V data to Equation 1 (see Figure 1), patterned electrodes consistently demonstrated higher limiting current density and lower mass transport losses than the control (Figure 1c-d). Three-point-bend mechanical testing revealed that the mean flexural fracture strengths of pristine cells and patterned cells are 36.0 ± 11.4 MPa and 33.0 ± 8.9 MPa respectively. Combining the equations for limiting current density with diffusion in a system with prismatic channels, we determined the ratio of the limiting current density for a patterned and pristine electrode using Equation 2 (see Figure). For the cell data shown in Figures 1c-1d, we expect an average 33% increase (with a standard deviation of 3.5%) in limiting current density based on microscopy measurements of channel and support layer thicknesses. In 1c, we see that the limiting current density of the patterned electrode is 32% higher than the pristine electrode, which matches our expectation. Furthermore, the Nyquist plot in Figure 1d demonstrates that patterned symmetric cells have similar impedance to pristine cells in the high-frequency regime with less impedance in the low-frequency regime, which is consistent with our expectations that the patterned cells have reduced mass transport losses with similar ohmic and activation losses. These j-V and EIS results suggest that macroscopic support patterning is a promising method for improving performance without compromising structural integrity. Figure 1: a) Ni-YSZ symmetric cell cross-section, laser-patterned with 600 µ m by 600 µ m channels and 200 µ m channel spacing. b) Comparison of the flexural fracture strength for pristine and patterned cells, under 3-point-bend testing. c) IR-free current density-voltage profiles of a patterned Ni-YSZ symmetric cell with a predicted current density improvement of 33%, at 700C in a 97%H 2 :3%H 2 O environment. Two distinct j-V responses are observed, based on whether the pristine electrode or the patterned electrode is under a cathodic bias. d) Unbiased potentiostatic EIS (1 MHz - 100 mHz) of a pristine cell versus two patterned cells at 700 C in 97%H 2 :3%H 2 O. The cells all have similar Ohmic resistances, but the impedance of the patterned cells is significantly lower in the low-frequency regime, due to the reduction in mass-transport losses. Equation 1: a is a constant, α is the transfer coefficient, j is current density, and j lim,H2O is the limiting current density for H 2 O diffusion. Equation 2: j lim /j lim,0 is the limiting current density ratio, A is the fraction of the cell surface that is patterned, and t c is the ratio of the channel depth to the patterned electrode thickness. References: (1) Gaudillere, C.; Serra, J. M. Freeze-Casting: Fabrication of Highly Porous and Hierarchical Ceramic Supports for Energy Applications. Bol. Soc. Esp. Cerámica Vidr. 2016 , 55 (2), 45–54. https://doi.org/10.1016/j.bsecv.2016.02.002. (2) Geisendorfer, N. R.; Barnett, S. A. Fuel Cell and Electrolysis Operation of Solid Oxide Cells Containing 3D-Printed Electrode Supports in H2/H2o and CO/CO2 Gas Mixtures. ECS Meet. Abstr. 2020 , MA2020-01 (36), 1463. https://doi.org/10.1149/MA2020-01361463mtgabs. 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Conventional methods of improving diffusion through the electrode support include increasing the support porosity and reducing the support thickness, but these can reduce the cell’s structural integrity. Freeze casting 1 and 3D printing 2 have also been explored to enhance diffusion. Here we explore cells in which the Ni-YSZ supports have macroscopic channels, produced by laser ablation, that reduce the average gas diffusion length. To test the difference in mass transport through patterned and pristine electrode supports, symmetric electrode-supported Ni-YSZ cells are patterned on one side, which enables comparison of the electrochemical performance of two otherwise identical electrodes (Figure 1a). Cells with varying pattern geometry, pore geometries, Ni/YSZ ratios, and Ni-YSZ particle sizes were created to fully understand how the support layer microstructure and macrostructure affects the cell performance. Patterned and pristine cells were tested together at three temperatures (600C, 700C, and 800C) in a 97%H 2 :3%H 2 O environment, chosen to produce a clear gas diffusion limitation in H 2 O electrolysis. j-V sweeps and electrochemical impedance spectroscopy (EIS) were carried out on each cell at each test condition, and the microstructure of patterned and control supports was characterized through SEM imaging. Upon removing the ohmic portion and fitting the j-V data to Equation 1 (see Figure 1), patterned electrodes consistently demonstrated higher limiting current density and lower mass transport losses than the control (Figure 1c-d). Three-point-bend mechanical testing revealed that the mean flexural fracture strengths of pristine cells and patterned cells are 36.0 ± 11.4 MPa and 33.0 ± 8.9 MPa respectively. Combining the equations for limiting current density with diffusion in a system with prismatic channels, we determined the ratio of the limiting current density for a patterned and pristine electrode using Equation 2 (see Figure). For the cell data shown in Figures 1c-1d, we expect an average 33% increase (with a standard deviation of 3.5%) in limiting current density based on microscopy measurements of channel and support layer thicknesses. In 1c, we see that the limiting current density of the patterned electrode is 32% higher than the pristine electrode, which matches our expectation. Furthermore, the Nyquist plot in Figure 1d demonstrates that patterned symmetric cells have similar impedance to pristine cells in the high-frequency regime with less impedance in the low-frequency regime, which is consistent with our expectations that the patterned cells have reduced mass transport losses with similar ohmic and activation losses. These j-V and EIS results suggest that macroscopic support patterning is a promising method for improving performance without compromising structural integrity. Figure 1: a) Ni-YSZ symmetric cell cross-section, laser-patterned with 600 µ m by 600 µ m channels and 200 µ m channel spacing. b) Comparison of the flexural fracture strength for pristine and patterned cells, under 3-point-bend testing. c) IR-free current density-voltage profiles of a patterned Ni-YSZ symmetric cell with a predicted current density improvement of 33%, at 700C in a 97%H 2 :3%H 2 O environment. Two distinct j-V responses are observed, based on whether the pristine electrode or the patterned electrode is under a cathodic bias. d) Unbiased potentiostatic EIS (1 MHz - 100 mHz) of a pristine cell versus two patterned cells at 700 C in 97%H 2 :3%H 2 O. The cells all have similar Ohmic resistances, but the impedance of the patterned cells is significantly lower in the low-frequency regime, due to the reduction in mass-transport losses. Equation 1: a is a constant, α is the transfer coefficient, j is current density, and j lim,H2O is the limiting current density for H 2 O diffusion. Equation 2: j lim /j lim,0 is the limiting current density ratio, A is the fraction of the cell surface that is patterned, and t c is the ratio of the channel depth to the patterned electrode thickness. References: (1) Gaudillere, C.; Serra, J. M. Freeze-Casting: Fabrication of Highly Porous and Hierarchical Ceramic Supports for Energy Applications. Bol. Soc. Esp. Cerámica Vidr. 2016 , 55 (2), 45–54. https://doi.org/10.1016/j.bsecv.2016.02.002. (2) Geisendorfer, N. R.; Barnett, S. A. Fuel Cell and Electrolysis Operation of Solid Oxide Cells Containing 3D-Printed Electrode Supports in H2/H2o and CO/CO2 Gas Mixtures. ECS Meet. 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引用次数: 0

摘要

提高固体氧化物电池的功率密度将使sofc和soec更便宜。在Ni-YSZ电极支持电池中,气体通过电极支持层的扩散可能是高h2或h2o利用率和高温下的主要限制因素。通过电极支架改善扩散的传统方法包括增加支架孔隙度和减少支架厚度,但这些方法会降低电池的结构完整性。还探索了冷冻铸造和3D打印来增强扩散。在这里,我们探索了Ni-YSZ支持具有激光烧蚀产生的宏观通道的细胞,这些通道减少了平均气体扩散长度。为了测试通过图图化和原始电极支撑的质量传递的差异,对称电极支撑的Ni-YSZ电池在一侧进行图图化,从而可以比较两个其他相同电极的电化学性能(图1a)。为了充分了解支撑层微观结构和宏观结构如何影响电池性能,研究人员创建了具有不同图案几何形状、孔隙几何形状、Ni/YSZ比和Ni-YSZ粒径的电池。在97% h2o2:3% h2o2环境下,在三种温度(600C, 700C和800C)下对图案电池和原始电池进行测试,选择用于在h2o2电解中产生明确的气体扩散限制。在每个测试条件下对每个电池进行了j-V扫描和电化学阻抗谱(EIS),并通过SEM成像表征了图案支架和控制支架的微观结构。在去除欧姆部分并将j-V数据拟合到方程1(见图1)后,与对照相比,图案电极始终显示出更高的极限电流密度和更低的质量输运损失(图1c-d)。三点弯曲力学试验表明,原始细胞和图案细胞的平均弯曲断裂强度分别为36.0±11.4 MPa和33.0±8.9 MPa。结合棱镜通道系统中限制电流密度与扩散的方程,我们使用公式2确定了图案电极和原始电极的限制电流密度之比(见图)。对于图1c-1d所示的电池数据,我们预计基于通道和支撑层厚度的显微镜测量,极限电流密度平均增加33%(标准偏差为3.5%)。在1c中,我们看到图案电极的极限电流密度比原始电极高32%,这与我们的预期相符。此外,图1d中的Nyquist图表明,图案对称细胞在高频状态下与原始细胞具有相似的阻抗,在低频状态下阻抗更小,这与我们的期望一致,即图案细胞在类似的欧姆和激活损失下减少了质量传输损失。这些j-V和EIS结果表明,宏观支撑模式是一种很有前途的方法,可以在不影响结构完整性的情况下提高性能。图1:a) Ni-YSZ对称单元截面,激光图形,600µm × 600µm通道,200µm通道间距。b)在三点弯曲测试下,原始细胞和图案细胞的弯曲断裂强度比较。c)在97% h2:3% h2o环境下,在700C温度下,Ni-YSZ对称电池的无ir电流密度-电压曲线,预测电流密度提高33%。两个不同的j-V响应被观察到,基于是否原始电极或图案电极是在阴极偏压下。d)在700℃、97% h2:3% h2o条件下,原始细胞与两个图案细胞的无偏恒电位EIS (1 MHz - 100 MHz)。这些细胞都具有相似的欧姆电阻,但图案细胞的阻抗在低频状态下明显较低,这是由于质量传输损失的减少。式1:a为常数,α为传递系数,j为电流密度,jlim,H2O为H2O扩散的极限电流密度。式2:j lim /j lim,0为极限电流密度比,A为图画化电池表面的比例,tc为通道深度与图画化电极厚度之比。参考文献:(1)Gaudillere, C.;冷冻铸造:用于能源应用的高多孔和分层陶瓷支架的制造。波尔。Soc。特别是Cerámica Vidr. 2016, 55(2), 45-54。https://doi.org/10.1016/j.bsecv.2016.02.002。(2) Geisendorfer, n.r.;燃料电池和电解操作固体氧化物电池含有3d打印电极支持H2/H2o和CO/CO2气体混合物。ECS见面。摘要/ abstract摘要:2020,MA2020-01(36), 1463。https://doi.org/10.1149/ma2020 mtgabs——01361463。图1
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Improving Gas Diffusion in Solid Oxide Cells Through Laser-Ablated Electrode Supports
Improving solid oxide cell power density will enable cheaper commercial-scale SOFCs and SOECs. In Ni-YSZ electrode-supported cells, gas diffusion through the electrode support layer can be a major limitation at high H 2 or H 2 O utilization and high temperature. Conventional methods of improving diffusion through the electrode support include increasing the support porosity and reducing the support thickness, but these can reduce the cell’s structural integrity. Freeze casting 1 and 3D printing 2 have also been explored to enhance diffusion. Here we explore cells in which the Ni-YSZ supports have macroscopic channels, produced by laser ablation, that reduce the average gas diffusion length. To test the difference in mass transport through patterned and pristine electrode supports, symmetric electrode-supported Ni-YSZ cells are patterned on one side, which enables comparison of the electrochemical performance of two otherwise identical electrodes (Figure 1a). Cells with varying pattern geometry, pore geometries, Ni/YSZ ratios, and Ni-YSZ particle sizes were created to fully understand how the support layer microstructure and macrostructure affects the cell performance. Patterned and pristine cells were tested together at three temperatures (600C, 700C, and 800C) in a 97%H 2 :3%H 2 O environment, chosen to produce a clear gas diffusion limitation in H 2 O electrolysis. j-V sweeps and electrochemical impedance spectroscopy (EIS) were carried out on each cell at each test condition, and the microstructure of patterned and control supports was characterized through SEM imaging. Upon removing the ohmic portion and fitting the j-V data to Equation 1 (see Figure 1), patterned electrodes consistently demonstrated higher limiting current density and lower mass transport losses than the control (Figure 1c-d). Three-point-bend mechanical testing revealed that the mean flexural fracture strengths of pristine cells and patterned cells are 36.0 ± 11.4 MPa and 33.0 ± 8.9 MPa respectively. Combining the equations for limiting current density with diffusion in a system with prismatic channels, we determined the ratio of the limiting current density for a patterned and pristine electrode using Equation 2 (see Figure). For the cell data shown in Figures 1c-1d, we expect an average 33% increase (with a standard deviation of 3.5%) in limiting current density based on microscopy measurements of channel and support layer thicknesses. In 1c, we see that the limiting current density of the patterned electrode is 32% higher than the pristine electrode, which matches our expectation. Furthermore, the Nyquist plot in Figure 1d demonstrates that patterned symmetric cells have similar impedance to pristine cells in the high-frequency regime with less impedance in the low-frequency regime, which is consistent with our expectations that the patterned cells have reduced mass transport losses with similar ohmic and activation losses. These j-V and EIS results suggest that macroscopic support patterning is a promising method for improving performance without compromising structural integrity. Figure 1: a) Ni-YSZ symmetric cell cross-section, laser-patterned with 600 µ m by 600 µ m channels and 200 µ m channel spacing. b) Comparison of the flexural fracture strength for pristine and patterned cells, under 3-point-bend testing. c) IR-free current density-voltage profiles of a patterned Ni-YSZ symmetric cell with a predicted current density improvement of 33%, at 700C in a 97%H 2 :3%H 2 O environment. Two distinct j-V responses are observed, based on whether the pristine electrode or the patterned electrode is under a cathodic bias. d) Unbiased potentiostatic EIS (1 MHz - 100 mHz) of a pristine cell versus two patterned cells at 700 C in 97%H 2 :3%H 2 O. The cells all have similar Ohmic resistances, but the impedance of the patterned cells is significantly lower in the low-frequency regime, due to the reduction in mass-transport losses. Equation 1: a is a constant, α is the transfer coefficient, j is current density, and j lim,H2O is the limiting current density for H 2 O diffusion. Equation 2: j lim /j lim,0 is the limiting current density ratio, A is the fraction of the cell surface that is patterned, and t c is the ratio of the channel depth to the patterned electrode thickness. References: (1) Gaudillere, C.; Serra, J. M. Freeze-Casting: Fabrication of Highly Porous and Hierarchical Ceramic Supports for Energy Applications. Bol. Soc. Esp. Cerámica Vidr. 2016 , 55 (2), 45–54. https://doi.org/10.1016/j.bsecv.2016.02.002. (2) Geisendorfer, N. R.; Barnett, S. A. Fuel Cell and Electrolysis Operation of Solid Oxide Cells Containing 3D-Printed Electrode Supports in H2/H2o and CO/CO2 Gas Mixtures. ECS Meet. Abstr. 2020 , MA2020-01 (36), 1463. https://doi.org/10.1149/MA2020-01361463mtgabs. Figure 1
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