High Throughput Screening of Materials for Solid Oxide Fuel Cells

PDF / 174,587 Bytes
6 Pages / 612 x 792 pts (letter) Page_size
24 Downloads / 316 Views

JJ2.10.1

High Throughput Screening of Materials for Solid Oxide Fuel Cells John P. Lemmon, Venkatesan Manivannan, Tracey Jordan, Lamyaa Hassib, Oltea Siclovan, Michelle Othon, and Mile Pilliod General Electric Global Research, Niskayuna, Schenectady, NY 12309, USA. ABSTRACT State of the art commercial cathodes for solid oxide fuel cells (SOFC) include LaMnO3 with a zirconia-based electrolyte. However, the vacancy concentration in A site doped LaMnO3 is low, thus ionic conductivity is also very low (10-7 – 10-8 S/cm at 800 ºC). The surface path dominates the reaction rate of the LaMnO3 cathode; therefore the optimized electrode is a porous composite material of both the cathode material and electrolyte and relies on triple-point boundaries for performance. The electrical conductivity and thermal expansion properties of this cathode material and other A3+B3+O3 perovskites can be tuned by substitution at the A and/or B site. The numerous combinations of composition, processing and microstructure needed for improved cathode performance is well suited for a high throughput screening (HTS) approach towards optimization and discovery. We present here a high throughput discovery process that includes, synthesis, performance testing and characterization techniques directed towards new low temperature SOFC cathode materials. INTRODUCTION Fuel cells are considered to be a potential future energy system expected to substitute existing energy conversion system which use fossil fuels. In this respect, (SOFCs) have attracted great attention due to the high-energy conversion efficiency and low or zero emission of air pollutants such as NOx. Significant gains in efficiency can be achieved when combining a SOFC stack with a conventional gas or steam turbine as shown in Figure 1. Steam Turbine

Combined Cycle

Micro- Fuel turbine Cell

Hybrid

Fuel cell mitigates combustion irreversibility and provides additional output Fuel

Efficiency

Advance Bottomin

80%

Stack

60%

Residual Exhaust Burner

Air

Compressor

Turbine

40%

Residual energy from stack recovered in GT

20% 0% Steam Turbine

Combined Cycle

Micro- Fuel turbine Cell

Hybrid

Figure 1 Fuel cells as viable source of "green energy" power generation.

A SOFC is an electrochemical device that converts chemical energy to electricity. They differ from other fuel cell technologies by their high operating temperature (1000 ºC) and efficiency (50-60%). The high operating temperature creates several issues for materials of construction such as oxidation, thermal expansion differences, and sealing. To reduce degradation and cost, lowering the operating temperature (700 – 800 ºC) while maintaining performance is one of the main goals of SOFC research today [1]. The performance of a fuel cell is dependent on several

JJ2.10.2

factors such as diffusion, mass transfer, and electronic, ionic, and catalytic properties. The focus of this paper will be on improving cathode performance, where the half reaction of the cell can be described as ½O2 +2e- O2-. There are several performance

Data Loading...

High Throughput Screening of Materials for Solid Oxide Fuel Cells

Recommend Documents

Perovskite Oxide for Solid Oxide Fuel Cells

Materials Development for Solid Oxide Fuel Cells Using Qualitative Models

Porous Thin-Film Anode Materials for Solid-Oxide fuel Cells

Electrolytes for Solid-Oxide Fuel Cells

Intermediate-Temperature Solid Oxide Fuel Cells Materials and Applic

High Performance Single Step Co-Fired Solid Oxide Fuel Cells

High-Throughput Screening of Catalytic Materials for JP-8 Fuel Cracking to Liquefied Petroleum Gas

Low-temperature solid-oxide fuel cells

Future energy, fuel cells, and solid-oxide fuel-cell technology

Solid State Ionics in Solid Oxide Fuel Cells

A simple model for solid oxide fuel cells

Self-repairable glass seals for solid oxide fuel cells