Effect of Drying Temperature on Iron Fischer-Tropsch Catalysts Prepared by Solvent Deficient Precipitation

Michael K Albretsen,Baiyu Huang,Calvin H Bartholomew,William C Hecker,Kamyar Keyvanloo,Morris D Argyle,Brian F Woodfield

doi:10.1155/2017/7258650

Michael K Albretsen, Baiyu Huang + Show 5 more

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https://doi.org/10.1155/2017/7258650

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Journal: Journal of Nanomaterials	Publication Date: Jan 1, 2017
Citations: 4	License type: CC BY 4.0

Affiliation: Brigham Young University

Abstract

A novel solvent deficient precipitation (SDP) method to produce nanoparticles was studied for its potential in Fischer-Tropsch synthesis (FTS) catalysis. Using Fe(NO3)3·9H2O as the iron-containing precursor, this method produces ferrihydrite particles which are then dried, calcined, reduced, and carbidized to form the active catalytic phase for FTS. Six different drying profiles, including final drying temperatures ranging between 80 and 150°C, were used to investigate the effect of ammonium nitrate (AN), a major by-product of reaction between Fe(NO3)3·9H2O and NH4HCO3 in the SDP method. Since AN has two phase-transitions within this range of drying temperatures, three different AN phases can exist during the drying of the catalyst precursors. These AN phases, along with physical changes occurring during the phase transitions, may affect the pore structure and the agglomeration of ferrihydrite crystallites, suggesting possible reasons for the observed differences in catalytic performance. Catalysts dried at 130°C showed the highest FTS rate and the lowest methane selectivity. In general, better catalytic performance is related to the AN phase present during drying as follows: phase III > phase II > phase I. However, within each AN phase, lower drying temperatures led to better catalytic properties.

Highlights

Fischer-Tropsch synthesis (FTS) is a proven process for converting low-value syngas obtained from natural gas, coal, and/or biomass into hydrocarbon fuels [1]
Previous research on iron FTS catalyst preparation has shown that the catalytic performance and physical characteristics are influenced by a number of variables, including the selection of catalytic phase, type of promoter and support, and method of active catalytic phase loading [6]
The additional mass loss appeared to be due to loss of ammonium nitrate, which is a byproduct of the solvent deficient precipitation (SDP) reaction, which was observed to seep out of the samples and crystallize as water evaporated, especially for the catalysts dried at higher temperatures

Summary

Introduction

Fischer-Tropsch synthesis (FTS) is a proven process for converting low-value syngas obtained from natural gas, coal, and/or biomass into hydrocarbon fuels [1]. Previous research on iron FTS catalyst preparation has shown that the catalytic performance and physical characteristics are influenced by a number of variables, including the selection of catalytic phase, type of promoter and support, and method of active catalytic phase loading [6]. Among these variables, drying is often viewed as a routine procedure that has minimal, if any, effect on the final precipitated catalysts [7]. Freeze-drying the catalyst produces a more uniform particle size distribution [14]

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