Journal of The Electrochemical Society, 158 (6) E51-E54 (2011)
0
E51
013-4651/2011/158(6)/E51/4/$28.00 VC The Electrochemical Society
Production of Oxygen Gas and Liquid Metal by Electrochemical
Decomposition of Molten Iron Oxide
a,b
Dihua Wang, Andrew J. Gmitter,
a,c,*
a,**,z
and Donald R. Sadoway
a
Department of Materials Science and Engineering, Massachusetts Institute of Technology, Cambridge,
Massachusetts 02139-4307, USA
School of Resource and Environmental Sciences, Wuhan University, China
b
Molten oxide electrolysis (MOE) is the electrolytic decomposition of a metal oxide, most preferably into liquid metal and oxygen
gas. The successful deployment of MOE hinges upon the existence of an inert anode capable of sustained oxygen evolution.
Herein we report the results of a program of materials design, selection, and testing of candidate anode materials and demonstrate
ꢀ2
the utility of iridium in this application. An electrolysis cell fitted with an iridium anode operating at 0.55 A cm produced liquid
metal and oxygen gas by the decomposition of iron oxide dissolved in a solvent electrolyte of molten MgO–CaO–SiO –Al
2
2 3
O .
ꢀ
1
The erosion rate of iridium was measured to be less than 8 mm y . The stability of iridium is attributed to a mix of mechanisms
including the electrochemical formation and simultaneous thermal decomposition of a surface film of iridium oxide.
VC 2011 The Electrochemical Society. [DOI: 10.1149/1.3560477] All rights reserved.
Manuscript submitted October 25, 2010; revised manuscript received January 31, 2011. Published April 4, 2011.
Modern metals extraction technologies face difficult environmen-
Experimental
9
tal challenges. With worldwide steel production exceeding 1 ꢁ 10
Chemicals and equipment.— Powders of lime, magnesia, alu-
ꢃ
1
tonnes annually, the amount of byproduct carbon dioxide that
mina, and silica (all from Alfa Aesar) were stored at 100 C with
2
accompanies steelmaking (>1.5 tonnes CO per tonne of steel) is
desiccant to prevent adsorption of water and agglomeration. 200 g
batches were dry milled with no milling media in 500 mL Nalgene
jars for roughly 24 h to thoroughly mix. The dry, mixed powders
were poured into an alumina crucible (80 mm OD) or a molybde-
num crucible (60 mm OD). The crucible was set into another alu-
mina crucible and then placed into the bottom of a vertical closed-
one-end alumina tube reactor (113 mm OD ꢁ 105 mm ID ꢁ 750 mm
L, McDanel) in a vertical tube furnace heated by molybdenum disi-
licide elements (Mellen). The electrolyte was blanketed by flowing
argon introduced via a mullite tube positioned in the hot zone of the
noteworthy on the scale of anthropogenic greenhouse gas (GHG)
emissions. The electrolytic production of aluminum also leads to
generation of GHGs in the form of CO , CF , and C F owing to the
2 4 2 6
2
use of a consumable carbon anode (ꢂ1.5 tonnes CO per tonne of
2
aluminum). In response, Sadoway has advocated molten oxide elec-
trolysis (MOE) as a carbon-free alternative to existing metals extrac-
tion technology. MOE is the electrolytic decomposition of a metal
3
oxide, most preferably into liquid metal and oxygen gas. Early efforts
to produce metal by oxide electrolysis go back more than 100 years,
4
but with few exceptions the process has not succeeded in moving
beyond the confines of the laboratory. More recently, variants of
ꢃ
ꢃ
furnace. The furnace was ramped at 85 C=h to 1575 C, and the con-
tents were allowed to equilibrate for roughly one hour prior to elec-
trochemical measurements.
5
MOE have been studied with the intention of exploiting indigenous
resources on the moon and on Mars for the generation of oxygen
along with the production of structural metals such as iron and photo-
Cyclic voltammetry.— The reference electrode was a 3.17 mm
diameter Mo rod shrouded in a mullite tube. The counter electrode
was identically prepared. Two kinds of working electrodes were
used: (1) 0.5 mm diameter Ir wire connected to a 0.368 mm diame-
ter Pt wire; (2) 3.17 mm diameter Mo rod. The exact electrode area
exposed to the electrolyte was determined by a relation between cur-
rent increment and electrode area increment (can be controlled from
the top of the working electrode) at a specific electrode potential.
Cyclic voltammetry with 70% iR compensation was used for all
electrochemical measurements. Higher compensation values
resulted in instability of the system.
6–13
voltaic materials such as silicon.
At this point, the success of
MOE hinges upon the existence of an inert anode capable of sus-
tained oxygen evolution.
Previous work in this laboratory on inert anodes for aluminum-
producing Hall–H e´ roult cells led to the enunciation of a set of selec-
tion criteria for the identification of materials for use as anodes in
1
4
the fluoride-based electrolyte. By analogy, in a molten oxide elec-
trolyte an oxygen-evolving inert anode would desirably be com-
posed of a material with the following attributes:
-
-
-
-
-
-
-
physically stable (preferably solid) at service temperature.
resistant to chemical attack by the molten oxide electrolyte.
resistant to chemical attack by pure oxygen.
electrochemically stable.
electronically conductive.
resistant to thermal shock.
mechanically robust.
Electrolysis and materials characterization.— Constant current
electrolysis was conducted with an electrolyte of composition MgO
(
CaO (18 wt %)–Al O (20 wt %)–SiO (46 wt %) (S1A) to which
26 wt %)–CaO (25 wt %)–SiO
2
(49 wt %) (S1) or MgO (16 wt %)–
2
3
2
was added either 5 or 10 wt % FeO. A Mo rod (3.17 or 6.34 mm in
diameter) was used as the cathode; an Ir plate (5 ꢁ 1 ꢁ 40 mm) or Ir
wire (0.5 mm in diameter, 9.5 mm in length) served as the anode.
The Ir plate was welded to a Mo rod which served as the current
lead. The Ir wire anode was connected to a Pt wire, which served as
the current lead. The Ir that served as the active anode was weighed
before and after electrolysis. The entrained electrolyte on the anode
was removed by immersing it in 47–51% HF aqueous solution. Af-
ter electrolysis the Ir anode and the cathode metal product were
examined by SEM and EDS (JEOL 5910).
In addition, the material should be easy to deploy at industrial
scale; for example, practicalities such as electrical connection to the
bus, cell startup, response to loss of electrical power, etc., should be
straightforward. Application of these selection criteria resulted in
the choice of iridium. The performance of this material as an inert
anode for MOE was assessed in the context of iron production by
electrolysis of FeO dissolved in an alumino-silicate supporting elec-
2 3
trolyte of composition MgO(16 wt %)–CaO(18 wt %)–Al O (20 wt
%
)–SiO (46 wt %).
2
Results
*
*
Electrochemical Society Student Member.
Electrochemical Society Active Member.
Present address: Rutgers University, New Brunswick, NJ.
E-mail: dsadoway@mit.edu
Figure 1 shows the results of cyclic voltammetry on an iridium
wire, 0.5 mm diameter, at oxidizing potentials capable of generating
oxygen gas. The blue trace represents data taken in the supporting
*
c
z