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Journal of Minerals & Materials Characterization & Engineering, Vol. 7, No.1, pp 1-26, 2007
jmmce.org Printed in the USA. All rights reserved
1
Mineralogical Transformations in Altasteel Electric Arc Furnace Dust
Roasted with Na
2
CO
3
and Secondary Ferrite-Forming Additives
P. C. Holloway and T. H. Etsell
Department of Chemical and Materials Engineering,
University of Alberta, Edmonton, Alberta, Canada T6G 2G6
Email: prestonh@ualberta.net
ABSTRACT
The effect of secondary additives, such as CaCO
3
and MnCO
3
, on the mineralogical
transformations in Altasteel EAF dust (9.4% Zn, 31.9% Fe) during roasting with
Na
2
CO
3
, and metal extractions during hot water and H
2
SO
4
leaching of the roasted
residues, was studied using a combination of techniques, including Design of
Experiments testing, x-ray diffraction, scanning electron microscope/energy dispersive x-
ray analysis and chemical analysis. The research objective was to promote the formation
of acid insoluble metal ferrites during roasting to try to lower iron extractions during
acid leaching.
Neither additive was effective in reducing iron extractions due to the unexpected
mineralogical changes caused during roasting by the addition of these secondary
additives to this poorly crystalline EAF dust. Low CaCO
3
or MnCO
3
additions promoted
the formation of manganese rich iron oxides (e.g., Mn
2
FeO
4
), instead of MnFe
2
O
4
, which
caused more iron to be available to react with Na
2
CO
3
during roasting to form acid
soluble NaFeO
2
. Increased CaCO
3
additions further increased iron extractions, by
further increasing the formation of Mn
2
FeO
4
ferrites, but increased MnCO
3
additions at
roasting temperatures above 950°C led to the formation of a ZnFe
2
O
4
-MnFe
2
O
4
solid
solution. While this resulted in lower iron extractions, lower overall zinc recoveries
during acid leaching were also observed.
Keywords: Electric arc furnace dust, Phase transformations, Pyrometallurgy,
Leaching, Sodium carbonate roasting
1. INTRODUCTION
Electric arc furnace (EAF) dust is produced globally as a byproduct of EAF
steelmaking as a result of the interactions of metallic iron, volatilized metal oxides, and
other slag components in the gas phase above the electric arc furnaces [1]. The resulting
dust is predominantly a magnetite-franklinite-jacobsite (Fe
3
O
4
/ZnFe
2
O
4
/MnFe
2
O
4
) solid
2 P. C. Holloway and T. H. Etsell Vol.7, No.1
solution, but also contains significant quantities of toxic elements or deleterious
impurities, such as Pb, Cd, Cr, Cl and F, which not only make the dust difficult to treat,
but also cause it to fail toxicity leaching requirements, resulting in the classification of
EAF dust as a hazardous waste [2]. Treatment or disposal of the EAF dust is an
expensive and global problem, with about 1.8 million tonnes per year produced in North
America, Europe and Japan [3,4] and treatment or disposal costs as high as $2 to 3 US
per tonne of steel produced [4].
In spite of significant research globally into the treatment of EAF dust, Waelz kiln
processing remains the dominant treatment technology with 80 to 85% of the EAF dust in
the US [5] and up to 76% worldwide [6] treated in Waelz kilns, in spite of the high
energy consumption, the production of relatively low quality zinc products and the
general inability to recycle the iron values from the dust back to the steel furnaces.
Economics and product purity from Waelz kiln processing dictate the non-localized
treatment of the dust near electrothermic or Imperial Smelting Process zinc smelters or
chemical or fertilizer plants that can accept the zinc product.
Transformational roasting, or roasting where a solid reagent is added which reacts
with the feed material in the solid state to produce a desirable mineralogical change in the
starting material, to treat EAF dusts has been proposed as a potential alternative to Waelz
kiln processing [7]. Transformational roasting would, ideally, use pyro- and
hydrometallurgical operations synergistically to achieve high metal recoveries while
lowering the volume and increasing the disposability of the residues produced.
Initial tests into transformational roasting of a sample of EAF dust from the Scaw
Metals’ Altasteel plant in Edmonton, Alberta, Canada, indicated that roasting with 45%
Na
2
CO
3
at 1000°C results in zinc extractions of up to 94% after leaching with 200 g/L
H
2
SO
4
, with 55% of the iron also dissolved [7]. (Leaching the same roasted material with
NaOH resulted in zinc extractions of 43%, lead extractions of 13%, and negligible iron
extractions [7].) Mineralogically, the mixture of zinc-iron-manganese
((Zn,Mn,Fe)(Fe,Mn)
2
O
4
) spinels in the EAF dust reacts with Na
2
CO
3
to form α- and β-
NaFeO
2
and CaCO
3
reacts with Fe
3
O
4
in the dust to form srebrodolskite (Ca
2
Fe
2
O
5
)
during roasting [7]. Leaching the roasted EAF dust with hot water dissolves any
unreacted Na
2
CO
3
, or Na
2
O or Na
2
SO
4
formed during roasting, and any Na-Cr, Na-Mo,
or Na-V compounds formed during roasting while ZnO, NaFeO
2
, Ca
2
Fe
2
O
5
and Ca
2
SiO
4
are dissolved during subsequent acid leaching to produce a residue consisting of gypsum
(CaSO
4
·2H
2
O), magnetite (Fe
3
O
4
) and jacobsite (MnFe
2
O
4
) [7].
Research on Na
2
CO
3
roasting of another ferrite-containing waste (i.e., zinc ferrite
residue from La Oroya, Peru) indicated that the addition of secondary additives, such as
CaCO
3
or MnCO
3
, could be used to decrease iron extractions in H
2
SO
4
leaching through
the formation of acid insoluble metal ferrites during roasting [8]. Mineralogical studies
from the roasting of the Altasteel EAF dust with Na
2
CO
3
show that a significant
proportion of the iron forms minerals that are insoluble in 200 g/L H
2
SO
4
solutions [7],
but further reductions in iron extraction, if high zinc and chromium recoveries could be
maintained, would be advantageous in processing the EAF dust with Na
2
CO
3
roasting.
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 3
This paper discusses the effects of secondary additives, such as CaCO
3
and
MnCO
3
, on the mineralogical transformations in the Altasteel EAF dust during roasting
with Na
2
CO
3
, and metal extractions during leaching of the roasted residues. A
combination of techniques were used, including Design of Experiments testing, x-ray
diffraction (XRD), scanning electron microscope (SEM)/energy dispersive x-ray (EDX)
analysis and chemical analysis, to ascertain the minerals formed, and their relative
proportions, with particular focus on changes in the type and quantity of iron minerals
formed during roasting.
2. FEED MATERIALS
Electric arc furnace dust is produced as a byproduct of the recycling and
production of carbon steel at Altasteel’s plant at a rate of 15000 t/y [9]. A chemical
analysis of the sample obtained from Altasteel is presented in Table 1. Elements, such as
Cr, F and Pb, are of particular concern, as it is usually based on these elements that the
dust fails Toxicity Characteristic Leaching Procedure (TCLP) tests and is then classified
as a hazardous waste [9].
Table 1 Chemical Analysis of As-Received Altasteel EAF Dust
Analysis, % Analysis, ppm
Al 0.50 Cr 0.34 K 0.82 Co 70
As 0.04 Cu 0.40 Si 1.92 F 130
Cd 0.03 Fe 31.9 Na 1.32 Mo 150
Ca 7.14 Pb 0.90 S 0.43 Ni 390
C 4.71 Mg 1.39 Zn 9.40 V 80
Cl 1.45 Mn 3.56
The as-received EAF dust had a particle size of 50% passing 84 µm, but with
almost 35% greater than 417 µm. After drying the residue, the oversize was pulverized to
give a final particle size of 90% passing 75 µm for the EAF dust used in the roasting
tests.
Mineralogically, x-ray diffraction analysis shows that the Altasteel EAF dust
contains a mixture of Zn-Mn-Fe spinels ((Zn,Mn,Fe)(Fe,Mn)
2
O
4
), CaCO
3
, NaCl,
CaZn
2
(OH)
6
Å2H
2
O and larnite (Ca
2
SiO
4
), but several different analyses, including x-ray
diffraction, scanning electron microscopy (SEM) imaging, energy dispersive x-ray
analysis (EDX) and diagnostic leaching, strongly indicated that the EAF dust is much less
crystalline than zinc ferrite materials produced from zinc sulphide roasting [7].
3. BACKGROUND
Thermodynamically, calcium and manganese ferrites should be more
thermodynamically favorable ferrites than franklinite (ZnFe
2
O
4
) or NaFeO
2
and recent
studies indicate that both srebrodolskite (Ca
2
Fe
2
O
5
) and manganese ferrites, such as
4 P. C. Holloway and T. H. Etsell Vol.7, No.1
jacobsite (MnFe
2
O
4
), can be formed during roasting of zinc ferrite materials with Na
2
CO
3
along with secondary additives, such as CaCO
3
and MnCO
3
[8].
ZnFe
2
O
4
+ 2 CaO Ca
2
Fe
2
O
5
+ ZnO G°= -37.8 - 0.006T (kJ/mol) (1)
ZnFe
2
O
4
+ MnO MnFe
2
O
4
+ ZnO G°= -5.0 - 0.004T (kJ/mol) (2)
2 NaFeO
2
+ 2 CaO Ca
2
Fe
2
O
5
+ Na
2
O G°= -104.5 - 0.037T (kJ/mol)(3)
2 NaFeO
2
+ MnO MnFe
2
O
4
+ Na
2
O G°= -71.6 - 0.028T (kJ/mol)(4)
All thermodynamic data reported in this article was obtained from either the
FREED or FACTSAGE thermodynamic databases. FREED is a trademark of
THERMART. FACTSAGE is a trademark of Thermafact/CRCT and GTT-Technologies.
Mineralogical results from the roasting of Altasteel EAF dust with Na
2
CO
3
indicate that both Ca
2
Fe
2
O
5
and MnFe
2
O
4
are present, along with Fe
3
O
4
and NaFeO
2
,
after roasting and MnFe
2
O
4
, in particular, plays a role in reducing the overall iron
extraction during acid leaching observed from these roasted samples [7]. While these
results are favorable, further reductions in iron extractions would be advantageous and,
thus, design of experiments (DOE) testing were performed to determine whether
secondary additions of CaCO
3
or MnCO
3
during Na
2
CO
3
roasting could further promote
the formation of acid insoluble metal ferrites and further depress iron extractions during
H
2
SO
4
leaching while maintaining high zinc and chromium extractions.
4. PROCEDURE
4.1. Roasting and Leaching Tests
Dried Altasteel EAF dust was mixed with a certain weight of Na
2
CO
3
in a mortar
and pestle and this mixture was transferred to an alumina crucible, heated to the reaction
temperature and roasted in a muffle furnace in air for 5 h. The samples were removed
from the furnace, air cooled, and ground to a uniform particle size and a subsample was
taken for x-ray diffraction (XRD) and/or scanning electron microscope (SEM) analysis.
After roasting, the roasted EAF dust was leached with water at 95 to 97°C for 1 h,
followed by filtration of the slurry, washing and drying of the solids, and collection of the
filtrate and wash samples for analysis. A subsample of the solids was taken for XRD and
SEM analysis and the remaining solids were then leached with 200 g/L H
2
SO
4
for 1.5 h
at room temperature, followed by filtration of the slurry, washing and drying of the
solids, and collection of the filtrate and wash samples for analysis.
4.2. Design of Experiments (DOE) Tests
The effects of temperature, Na
2
CO
3
addition, and secondary additions of either
CaCO
3
or MnCO
3
on the zinc and iron extractions were further quantified through the use
of a Design of Experiments (DOE) test. This test was conducted using a 2
3
circumscribed central composite design (CCD). A circumscribed central composite
design consists of a standard 2
3
factorial design with the addition of center points to all
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 5
for quantification of nonlinearity in the response of output variables, and axial points to
allow for the construction of response surface models (RSM) from the output variables.
Input variables were selected for the axial points to produce a fully rotatable design (i.e.,
with the additional axial points of the design at a radius of α=(2
k
)
1/4
from the design
centre) to allow RSM to be constructed from the output variables.
The conditions used for each sample in these DOE tests are shown in Table 2;
samples were designated as matrix (M), centre (C) or axial (A) points, respectively,
depending on their location relative to the centre of the design. Each individual sample
for these tests was prepared using the roasting and leaching procedure outlined earlier.
Table 2 Input Variables for Each Sample Tested in the Design of Experiments
Tests
Sample Temperature,
°C
Na
2
CO
3
Addition, %
Secondary Addition, %
CaCO
3
MnCO
3
M1 800 50.0 3.7 4.3
M2 800 50.0 14.1 16.3
M3 800 50.0 3.7 4.3
M4 800 90.0 14.1 16.3
M5 1000 50.0 3.7 4.3
M6 1000 50.0 14.1 16.3
M7 1000 90.0 3.7 4.3
M8 1000 90.0 14.1 16.3
C1 900 70.0 8.9 10.2
C2 900 70.0 8.9 10.2
A1 732 70.0 8.9 10.2
A2 1068 70.0 8.9 10.2
A3 900 36.4 8.9 10.2
A4 900 103.6 8.9 10.2
A5 900 70.0 0.17 0.19
A6 900 70.0 17.6 20.2
Lower additions of CaCO
3
(3.7 to 14.1%) and MnCO
3
(4.3 to 16.3%) were made
than were used during the DOE tests using secondary additives for the La Oroya zinc
ferrite [8]. These additions were determined based on the stoichiometric additions that
would be required to form 100% MnFe
2
O
4
or 100% CaFe
2
O
4
(50% Ca
2
Fe
2
O
5
) or from
iron in the zinc ferrite component of the EAF dust.
A software package called DOE XL Pro (a trademark of Digital Computations,
Inc. and Air Academy Associates, LLC) was used to assist in the experimental design,
and aid in the analysis of the results and the construction of the response surface models
from these results. The R
2
values for the response surface models for overall zinc and
iron extractions were 0.898 and 0.945, respectively, for CaCO
3
and 0.884 and 0.986,
6 P. C. Holloway and T. H. Etsell Vol.7, No.1
respectively for MnCO
3
. The R
2
value for the RSM for chromium extractions by water
leaching was 0.765 for both CaCO
3
and MnCO
3
.
4.3. Chemical and Mineralogical Analysis
All solutions and solids were analyzed with atomic absorption spectroscopy (AA)
with a single-element Perkin-Elmer 4000 instrument. Solids were digested by fusion
with lithium metaborate at 950°C and dissolved in HCl prior to analysis.
Scanning electron microscope analysis was performed on selected samples using
a Hitachi
Model S-2700 Microscope equipped with a GW Electronics Annular Four-
Quadrant Backscattered Electron Detector and a Princeton Gamma Tech Prism Intrinsic
Germanium (IG) x-ray detector and operating at an accelerating voltage of 20 kV. The
digital images were taken using a Princeton Gamma Tech IMIX system.
X-ray diffraction analysis was performed using a Rigaku Rotoflex XRD with a
rotating Cu anode. The x-ray patterns were then analyzed using Version 7 of the Jade
software obtained from Materials Data, Inc.
5. RESULTS
The DOE tests for roasting Altasteel EAF dust with Na
2
CO
3
reported in earlier
work [7] were conducted at slightly lower temperatures and Na
2
CO
3
additions than this
study. Fig. 1 and Fig. 2 show an extrapolation of the RSM from this previous study to
allow the results, and the effects of secondary additives, to be readily compared and
quantified.
FIG 1. Extrapolation of the
Response Surface Model
Describing the Effect of
Temperature and Na
2
CO
3
Addition on the Extraction
of Chromium from Roasted
Altasteel EAF Dust by
Leaching with Hot Water
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 7
FIG 2. Extrapolation of the Response Surface Models Describing the Effect of
Temperature and Na
2
CO
3
Addition on the Extraction of Zinc and Iron
from Roasted Altasteel EAF Dust after Leaching with 200 g/L H
2
SO
4
5.1. Roasting with CaCO
3
as a Secondary Additive
5.1.1. Response Surface Models and Metals Extractions
The shape of the chromium and zinc extraction response surface models (Fig. 3 to
Fig. 5) for leaching the roasted ash with water and 200 g/L H
2
SO
4
, respectively, closely
follows the trends in extraction observed in the scoping tests and roasting with Na
2
CO
3
alone (Fig. 1 and Fig. 2), with a maximum around 50% Na
2
CO
3
and 1000°C and a
decrease in extractions at higher Na
2
CO
3
additions and lower temperatures. However, the
addition of CaCO
3
as a secondary additive during roasting significantly broadened the
area of maximum (90 to 100%) chromium extraction possible with water leaching (Fig.
3) and of the maximum zinc extraction possible with acid leaching (Fig. 4 and Fig. 5),
even at low CaCO
3
additions. This makes extractions of over 90% possible over a wider
range of temperatures and Na
2
CO
3
additions. With increasing CaCO
3
additions, the
region of maximum chromium extraction shrinks, while the region of maximum zinc
extraction increases in size, making these extractions possible at lower temperatures and
a broader range of Na
2
CO
3
additions. Chromium extractions from water leaching, though,
are consistently greater than 90% in the regions where zinc extractions are over 90%.
Iron extractions are greatly affected by the addition of CaCO
3
to the EAF dust
during roasting. Iron extractions were 50 to 60% in the region where zinc extractions
were over 90% for roasting with Na
2
CO
3
alone (Fig. 2), but adding CaCO
3
during
roasting causes iron extractions to increase to 60 to 90%, depending on the temperature,
Na
2
CO
3
and CaCO
3
addition used, for conditions where zinc extractions are greater than
90% (Fig. 4 and Fig. 5).
8 P. C. Holloway and T. H. Etsell Vol.7, No.1
FIG 3. Effect of Na
2
CO
3
and Temperature on Hot Water Leach Extractions of
Chromium from Altasteel EAF Dust Roasted with CaCO
3
FIG 4. Effect of Na
2
CO
3
and Temperature on Zinc and Iron Extractions from
Altasteel EAF Dust Roasted with 3.7% CaCO
3
after Leaching with 200 g/L
H
2
SO
4
Furthermore, the iron extraction for roasting with CaCO
3
and Na
2
CO
3
(Fig. 4 and
Fig. 5) does not show the same trend as roasting with Na
2
CO
3
alone (Fig. 2) where higher
Na
2
CO
3
additions cause an increase in iron extractions. Instead iron extractions increase
with increasing temperature and decreasing Na
2
CO
3
addition similar to the trend
observed for zinc and chromium extractions.
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 9
FIG 5. Effect of Na
2
CO
3
and Temperature on Zinc and Iron Extractions from
Altasteel EAF Dust Roasted with 14.1% CaCO
3
after Leaching with
200 g/L H
2
SO
4
5.1.2. X-ray Diffraction Analysis
To try to correlate this behaviour to the phases formed during roasting, and
remaining after leaching with 200 g/L H
2
SO
4
, samples at various conditions described by
the model for roasting with Na
2
CO
3
and the lowest CaCO
3
addition tested (3.7%) were
analyzed using x-ray diffraction (Points A through D on Fig. 3 and Fig. 4). The
diffraction patterns for the samples of EAF dust after roasting and after leaching are
shown in Fig. 6 and Fig. 7, respectively, while the identified phases are listed in Tables 3
and 4, respectively.
Table 3 Phases Identified by XRD Analysis of EAF Dust Roasted with Na
2
CO
3
and 3.7% CaCO
3
Sample Identified Phases (in order of intensity)
A α-NaFeO
2
, Ca
2
Fe
2
O
5
, (Zn,Mn,Fe)(Fe,Mn)
2
O
4
, ZnO
B Ca
2
Fe
2
O
5
, (Zn,Mn,Fe)(Fe,Mn)
2
O
4
, α-NaFeO
2
, ZnO
C α-NaFeO
2
, Ca
2
Fe
2
O
5
, ZnO, β-NaFeO
2
, CaCO
3
D (Zn,Mn,Fe)(Fe,Mn)
2
O
4
, α-NaFeO
2
, Ca
2
Fe
2
O
5
, β-NaFeO
2
, ZnO
Table 4 Phases Identified by X-ray Diffraction Analysis of EAF Dust after
Roasting with Na
2
CO
3
and CaCO
3
and Leaching with 200 g/L H
2
SO
4
Sample Identified Phases (in order of intensity) Leaching Wt. Loss, %
A (Zn,Mn,Fe)(Fe,Mn)
2
O
4
, CaSO
4
Å2H
2
O 24
1
, 67
2
B (Zn,Mn,Fe)(Fe,Mn)
2
O
4
, CaSO
4
Å2H
2
O 42
1
, 52
1
C Ca
2
Fe
2
O
5,
CaSO
4
Å2H
2
O 14
1
, 41
2
D (Zn,Mn,Fe)(Fe,Mn)
2
O
4
, CaSO
4
Å2H
2
O, Ca
2
Fe
2
O
5
41
1
, 45
2
1
Hot Water Leach
2
Acid Leach
10 P. C. Holloway and T. H. Etsell Vol.7, No.1
FIG. 6 XRD Patterns of EAF Dust Residue after Roasting with Na
2
CO
3
and
CaCO
3
Decomposition, or partial decomposition, of ZnFe
2
O
4
occurs across the entire
temperature range tested with NaFeO
2
and ZnO identified in all the samples tested after
roasting using XRD. Srebrodolskite is also observed in all four samples, and is the major
phase in Sample B, likely forming from the reaction of free calcium with magnetite
(Fe
3
O
4
) or NaFeO
2
. The absence of any residual Zn-Mn-Fe ferrite peaks in Sample C is
consistent with the high zinc extractions observed for that sample, indicating that near
complete decomposition of ZnFe
2
O
4
occurs at these conditions. (Similarly, the lower zinc
extractions in Sample D for higher Na
2
CO
3
additions are consistent with the presence of
(Zn,Mn,Fe)(Fe,Mn)
2
O
4
in Sample D as the major phase.) Specific silicate phases could
not be identified using x-ray diffraction but, based on the phases observed from roasting
with Na
2
CO
3
alone [7] and in the EAF dust feed, it is likely that the majority of silicon is
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 11
present in the roasted dust as larnite (Ca
2
SiO
4
). In these samples, the formation of α-
NaFeO
2
is favored, even at higher temperatures, over β-NaFeO
2
; this behaviour is
consistent with the results from roasting this EAF dust with Na
2
CO
3
alone [7], but differs
from the results of roasting of the La Oroya zinc ferrite where β-NaFeO
2
is preferred at
temperatures of 950°C and higher [10].
FIG. 7 XRD Patterns of EAF Dust Residue after Roasting with Na
2
CO
3
and
CaCO
3
and Leaching with 200 g/L H
2
SO
4
After leaching with 200 g/L H
2
SO
4
, gypsum (CaSO
4
Å2H
2
O) was identified in all
the samples analyzed with x-ray diffraction (Table 4 and Fig. 7), with
(Zn,Mn,Fe)(Fe,Mn)
2
O
4
as the major phase in Samples A, B and D where zinc extractions
were lower and absent from Sample C where high zinc extractions were observed.
Srebrodolskite (Ca
2
Fe
2
O
5
) is also detected in significant quantities in samples roasted at
1000°C (Samples C and D). (Even though srebrodolskite (Ca
2
Fe
2
O
5
) was formed when
roasting the EAF dust with Na
2
CO
3
alone, it could not be detected by x-ray diffraction
and could only be observed in trace quantities using SEM/EDX analysis after leaching
with 200 g/L H
2
SO
4
[7].)
12 P. C. Holloway and T. H. Etsell Vol.7, No.1
5.1.3. Scanning Electron Microscopy/Energy Dispersive X-ray Analysis
Fig. 8 shows a micrograph of Sample C (1000°C, 50% Na
2
CO
3
, 3.7% CaCO
3
)
after roasting using back-scattered SEM imaging and EDX analysis. The zinc oxide (A)
and srebrodolskite (C) phases identified using XRD are visible with the SEM, but a
separate Na-Fe phase (i.e., NaFeO
2
) was not detected in the field of view. Several other
types of particles are observed, including particles high in Pb, Ca and O (i.e., PbO and
CaO (B)), high in Ca, Mn, Fe and O (i.e., likely a mixture of MnFe
2
O
4
and Ca
2
Fe
2
O
5
(D)), and high in Fe and O (i.e., Fe
3
O
4
(E)), as well a darker phase containing Na, K and
O (i.e., likely (Na,K)
2
O (F)).
Fig. 8 Secondary Electron (SE) and Backscattered Electron (BSE) Images of EAF
Dust after Roasting at 1000°C with 50% Na
2
CO
3
and 3.7% CaCO
3
(Sample C)
After leaching with 200 g/L H
2
SO
4
, Samples C (1000°C, 50% Na
2
CO
3
, 3.7%
CaCO
3
) and D (1000°C, 90% Na
2
CO
3
, 3.7% CaCO
3
) were reexamined using SEM/EDX
analysis (Fig. 9 and Fig. 10) to try to better understand the iron deportment in this system.
Gypsum (CaSO
4
Å2H
2
O) is the major phase in the field of view in both samples and is
labeled as phase G in both Fig. 9 and Fig. 10.
In Sample C (Fig. 9), several phases containing iron are identified, including
particles high in Ca, Fe and O (i.e., Ca
2
Fe
2
O
5
(E)) and high in Fe, Mn, Zn and O (i.e.,
residual unreacted (Zn,Mn)Fe
2
O
4
(D)). Several particles were also found to be high in Fe,
Mn and O, but the ratio of manganese to iron in the EDX intensities differed, with some
particles showing a ratio of intensities of Mn:Fe of between 2:1 and 3:1 (A, B) and others
with a ratio of about 0.33:1 to 0.5:1 (C). Thus, this would indicate that some manganese
may substitute for ferric iron in the Mn-ferrite structure, resulting in Mn-ferrites closer to
the composition of Mn
2
FeO
4
(particles A and B) while other Mn-ferrites are more typical
of jacobsite (MnFe
2
O
4
) (particles C and F). (Particle B contains Ca, Pb and S, in addition
to Mn, Fe and O, and is likely a mixture of Mn
2
FeO
4
, gypsum and anglesite (PbSO
4
)
while Particle F contains Ca, Mn, Fe and O and is likely a mixture of MnFe
2
O
4
and
Ca
2
Fe
2
O
5
.)
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 13
FIG. 9 Secondary Electron (SE) and Backscattered Electron (BSE) Images of EAF
Dust after Roasting at 1000°C with 50% Na
2
CO
3
and 3.7% CaCO
3
and
Leaching with 200 g/L H
2
SO
4
(Sample C)
In Sample D (Fig. 10), similar particles likely representing (Zn,Mn)Fe
2
O
4
(A),
MnFe
2
O
4
(C), Ca
2
Fe
2
O
5
(D) and a mixture of Mn
2
FeO
4
and gypsum (B) were identified.
However, in Sample D, (Zn,Mn)Fe
2
O
4
particles are much more abundant, due to the
lower zinc extractions in this sample, and particles likely containing Mn
2
FeO
4
are not
observed as frequently as in Sample C.
FIG. 10 Secondary Electron (SE) and Backscattered Electron (BSE) Images of EAF
Dust after Roasting at 1000°C with 90% Na
2
CO
3
and 3.7% CaCO
3
and
Leaching with 200 g/L H
2
SO
4
(Sample D)
14 P. C. Holloway and T. H. Etsell Vol.7, No.1
5.1.4. Iron Deportment
The increase in iron extractions observed with the addition of CaCO
3
were not
observed when roasting the La Oroya zinc ferrite with CaCO
3
, as a small, but steady
decrease in iron extractions occurred with increasing CaCO
3
additions [8].
Thus, in order to explain this difference in behaviour, an iron balance for the
roasting of EAF dust with Na
2
CO
3
and CaCO
3
was then constructed using the chemical,
x-ray diffraction and SEM/EDX analyses of the feed and of samples after roasting and
after leaching (Table 5).
Table 5 Deportment of Iron Minerals during Roasting of EAF Dust with Na
2
CO
3
and CaCO
3
and Leaching with 200 g/L H
2
SO
4
Iron % of Total Iron in Feed
Minerals Feed Sample A Sample B Sample C Sample D
ZnFe
2
O
4
50.3 20.9 24.1 2.0 30.7
MnFe
2
O
4
22.7 22.1 22.1 1.1
a
13.5
b
Mn
2
FeO
4
0.0 0.0 0.0 5.3
a
2.3
b
Fe
3
O
4
27.0 20.3 20.3 0.0 0.0
Ca
2
Fe
2
O
5
0.0 13.8 13.8 13.8 13.8
NaFeO
2
0.0 22.9 19.7 77.8 39.8
Total 100.0 100.0 100.0 100.0 100.0
Fe Extraction
Projected, % 36.7
1
33.5
1
77.8
2
39.8
2
Actual, % 38.9 24.1 79.3 39.6
Difference, % -2.2 9.4 -1.5 0.2
a
Calculated assuming 90% of Mn is present as Mn
2
FeO
4
b
Calculated assuming 40% of the Mn is present as Mn
2
FeO
4
1
Calculated assuming the total dissolution of NaFeO
2
and Ca
2
Fe
2
O
5
during leaching
2
Calculated assuming only the dissolution of NaFeO
2
during leaching
The iron balance for the feed is calculated assuming 100% of Zn and Mn in the
feed are present as ZnFe
2
O
4
and MnFe
2
O
4
and the balance of the iron is present as Fe
3
O
4
.
The iron balance for Samples A to D is calculated, first, using zinc extractions to
determine the conversion of ZnFe
2
O
4
to NaFeO
2
and, second, assuming that Fe
3
O
4
present in the dust after roasting is insoluble under the acid leaching conditions used.
Third, it was assumed for this balance that the calcium in the feed that is not associated
with silicon as Ca
2
SiO
4
reacts with Fe
3
O
4
to form Ca
2
Fe
2
O
5
while the CaCO
3
added
during roasting reacted with NaFeO
2
to form Ca
2
Fe
2
O
5
. (The assumption made in the iron
balance for roasting with Na
2
CO
3
alone that 100% of the available calcium reacts with
magnetite to form Ca
2
Fe
2
O
5
[7] would lead to a significant overestimate of the iron
extraction in Samples A and B.) Fourth, because srebrodolskite (Ca
2
Fe
2
O
5
) is observed in
the XRD and SEM/EDX analysis of the leach residue from Samples C and D, but not in
Samples A and B, it was assumed that the Ca
2
Fe
2
O
5
formed at high temperatures was
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 15
insoluble (Samples C and D), but was still assumed to be leached completely at lower
temperatures (Samples A and B). Fifth, it was assumed, based on the SEM/EDX analysis
of Samples C and D, that some of the iron was present as Mn
2
FeO
4
, instead of as
MnFe
2
O
4
, with the remaining iron assumed to react with Na
2
CO
3
to form NaFeO
2
.
(Without this assumption, complete leaching of Ca
2
Fe
2
O
5
and complete conversion of
magnetite (Fe
3
O
4
) to NaFeO
2
in Sample C, with all the manganese as MnFe
2
O
4
, would
not explain the high iron extractions observed.) In Samples A and B, all the manganese
was assumed to be present as MnFe
2
O
4
.
With these assumptions, the balance agrees reasonably well with the iron
extractions observed. However, the deportment of iron in samples roasted at 1000°C
differs considerably from the iron deportment observed for roasting the Altasteel EAF
dust with Na
2
CO
3
alone [7] or roasting the La Oroya zinc ferrite with Na
2
CO
3
[10] or
with Na
2
CO
3
and CaCO
3
[8].
Some of the phenomena came be readily explained. For example, the apparent
decrease in the solubility of srebrodolskite (Ca
2
Fe
2
O
5
) in H
2
SO
4
solution former at higher
roasting temperatures is consistent the results from tests performed by roasting the
Altasteel EAF dust with coal and CaCO
3
which showed that, though srebrodolskite
(Ca
2
Fe
2
O
5
) is formed at all temperatures between 850 and 1050°C, the srebrodolskite
formed at lower temperatures is leached more readily than that formed at higher
temperatures. As well, the reaction of magnetite (Fe
3
O
4
) to form NaFeO
2
and Ca
2
Fe
2
O
5
has been proposed to explain the iron deportment during roasting of the EAF dust with
Na
2
CO
3
alone [7], although the extent of reaction increases significantly with the increase
in temperature and Na
2
CO
3
addition used in these tests.
However, some phenomena, such as the formation of Mn(Fe,Mn)
2
O
4
spinels, are
not as easily explained. Research on manganese iron spinels indicates that the formation
of Mn
2
FeO
4
is more likely where, instead of direct substitution of Mn
3+
for Fe
3+
in the
octahedral sites, a combination of Mn
4+
and Fe
2+
are found in the octahedral sites, with
Mn
2+
remaining in the tetrahedral sites [11]. The results from roasting with Na
2
CO
3
alone or roasting at lower temperatures with Na
2
CO
3
and CaCO
3
would indicate that
manganese is predominantly present as Mn
2+
, leading to the formation of jacobsitic
(MnFe
2
O
4
) spinels. Thus, if Mn
2+
is the predominant manganese species, the formation
of Mn(Fe,Mn)
2
O
4
spinels would require the oxidation of manganese to Mn
4+
. (Some
ferrous iron should be present in the dust in the tetrahedral sites of magnetite (Fe
3
O
4
).)
This is possible, considering that the roasting tests were conducted in air, but it is
uncertain why this oxidation, and the formation of Mn(Fe,Mn)
2
O
4
spinels, would be
favored, or catalyzed, by the addition of even small amounts of CaCO
3
to the roasting
system.
Nevertheless, these Mn(Fe,Mn)
2
O
4
spinels do form, and based on the iron
extractions in Fig. 5, their formation increases significantly with increasing CaCO
3
additions.
16 P. C. Holloway and T. H. Etsell Vol.7, No.1
This type of behaviour, though, is not observed during Na
2
CO
3
roasting of the La
Oroya zinc ferrite at similar roasting temperatures and much higher CaCO
3
additions [8].
It is possible that this difference in behaviour may be related to the low crystallinity of
the EAF dust, as outlined earlier and in other studies on this material [7]. If portions of
the EAF dust are indeed poorly crystalline and, hence, metastable, then crystallization
would be expected on heating and it is possible that, if crystallization occurs in the
presence of other ionic compounds, such as CaCO
3
or CaO, more thermodynamically
stable ferrites, such as Ca
2
Fe
2
O
5
, may be formed preferentially. (The formation of
calcium ferrites upon crystallization may reduce the amount of iron available to react
with manganese in the dust to form MnFe
2
O
4
type ferrites, thus, leading to the observed
increase in the formation of Mn
2
FeO
4
spinels.) Additional characterization and phase
identification, though, would be required to be able to more confidently explain the
mechanisms behind these observed phenomena and will be the subject of future research.
5.2. Roasting with MnCO
3
as a Secondary Additive
5.2.1. Response Surface Models and Metal Extractions
The shape of the chromium and zinc extraction response surface models (Fig. 11
to Fig. 14) for leaching the roasted ash with water and 200 g/L H
2
SO
4
, respectively,
closely follows the trends in extraction observed in the scoping tests for roasting with
Na
2
CO
3
(Fig. 1 and Fig. 2) or Na
2
CO
3
-CaCO
3
(Fig. 3 to Fig. 5), with a maximum around
50% Na
2
CO
3
and 1000°C and a decrease in extractions at higher Na
2
CO
3
additions and
lower temperatures. Increased MnCO
3
additions broaden the area of maximum (90 to
100%) chromium extraction possible with water leaching (Fig. 11), compared to roasting
with Na
2
CO
3
alone (Fig. 1), but the size of the area of the maximum zinc extractions
(Fig. 12 to Fig. 14) is drastically decreased as MnCO
3
additions increase.
FIG. 11 Effect of Na
2
CO
3
and Temperature on Chromium Extractions from
Altasteel EAF Dust Roasted with MnCO
3
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 17
FIG. 12 Effect of Na
2
CO
3
and Temperature on Zinc and Iron Extractions from
Altasteel EAF Dust Roasted with 4.3% MnCO
3
FIG. 13 Effect of Na
2
CO
3
and Temperature on Zinc and Iron Extractions from
Altasteel EAF Dust Roasted with 10.2% MnCO
3
Iron extractions are also affected by the addition of MnCO
3
to the EAF dust
during roasting. While the overall iron extraction profile is similar in shape to that
observed for roasting with Na
2
CO
3
and CaCO
3
(Fig. 4 and Fig. 5), low MnCO
3
additions
cause an initial increase in iron extractions to up to 80 to 90% in the region where zinc
extractions were over 90% (Fig. 12) which is significantly higher than the 50 to 60%
observed for roasting with Na
2
CO
3
alone (Fig. 2). Additions of up to 16.3% MnCO
3
(Fig.
14) are required to return iron extractions to the levels observed when roasting with
Na
2
CO
3
alone (50 to 60%), but zinc extractions are drastically reduced at those MnCO
3
additions.
18 P. C. Holloway and T. H. Etsell Vol.7, No.1
FIG. 14 Effect of Na
2
CO
3
and Temperature on Zinc and Iron Extractions from
Altasteel EAF Dust Roasted with 16.3% MnCO
3
5.2.2. X-ray Diffraction Analysis
Samples at various conditions described by the model for roasting with Na
2
CO
3
and the highest MnCO
3
addition tested (16.3%) were analyzed using x-ray diffraction
(Points A through D on Fig. 11 and Fig. 14) to try to correlate this behaviour to the
phases formed during roasting, and remaining after leaching with 200 g/L H
2
SO
4
. The
diffraction patterns for the samples of EAF dust after roasting and after leaching are
shown in Fig. 15 and Fig. 16, respectively, while the identified phases are listed in Tables
6 and 7, respectively.
As with the x-ray diffraction analysis of La Oroya ferrite roasted with Na
2
CO
3
and MnCO
3
[8], phase identification for the EAF dust samples roasted with MnCO
3
was
less definitive than for EAF dust roasted with Na
2
CO
3
or Na
2
CO
3
-CaCO
3
. In several
cases, x-ray diffraction peaks of significant intensity could not be positively identified
from the available database. However, it was possible to positively identify several
phases with x-ray diffraction including α-NaFeO
2
, β-NaFeO
2
, (Zn,Mn,Fe)(Fe,Mn)
2
O
4
,
zincite (ZnO) and srebrodolskite (Ca
2
Fe
2
O
5
), which are found in most of the samples
tested. In Sample D, a calcium-manganese oxide (Ca
4
Mn
3
O
10
) was also identified after
roasting along with trace amounts of β-NaFeO
2
.
After leaching with 200 g/L H
2
SO
4
, zincite (ZnO) and NaFeO
2
are dissolved,
some calcium is dissolved and precipitated as gypsum (CaSO
4
Å2H
2
O) and spinel phases,
such as (Zn,Mn,Fe)(Fe,Mn)
2
O
4
, MnFe
2
O
4
or Fe
3
O
4
, which were not dissolved during
leaching were positively identified from x-ray diffraction on the leach residue (Table 7
and Fig. 16). However, several peaks could not be positively identified using the
available database and software in these samples as well.
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 19
FIG. 15 XRD Patterns of EAF Dust Roasted with Na
2
CO
3
and MnCO
3
Table 6 Phases Identified by XRD Analysis of EAF Dust Roasted with Na
2
CO
3
and MnCO
3
Sample Identified Phases (in order of intensity)
A α-NaFeO
2
, (Zn,Mn,Fe)(Fe,Mn)
2
O
4
, ZnO, Ca
2
Fe
2
O
5
B α-NaFeO
2
, ZnO, (Zn,Mn,Fe)(Fe,Mn)
2
O
4
, ZnO, Ca
2
Fe
2
O
5
C α-NaFeO
2
, Ca
2
Fe
2
O
5,
(Zn,Mn,Fe)(Fe,Mn)
2
O
4
, ZnO
D α-NaFeO
2
, ZnO, Ca
4
Mn
3
O
10
, Ca
2
Fe
2
O
5,
β-NaFeO
2
20 P. C. Holloway and T. H. Etsell Vol.7, No.1
FIG. 16 XRD Patterns of EAF Dust Residue after Roasting with Na
2
CO
3
and
MnCO
3
and Leaching with 200 g/L H
2
SO
4
Table 7 Phases Identified by X-ray Diffraction Analysis of EAF Dust after
Roasting with Na
2
CO
3
and MnCO
3
and Leaching with 200 g/L H
2
SO
4
Sample Identified Phases (in order of intensity) Leaching Wt. Loss, %
A CaSO
4
Å2H
2
O, (Zn,Mn,Fe)(Fe,Mn)
2
O
4
19
1
, 72
2
B CaSO
4
Å2H
2
O, (Zn,Mn,Fe)(Fe,Mn)
2
O
4
34
1
, 54
2
C CaSO
4
Å2H
2
O, MnFe
2
O
4
/Fe
3
O
4
9
1
, 62
2
D CaSO
4
Å2H
2
O, (Zn,Mn,Fe)(Fe,Mn)
2
O
4
,
MnFe
2
O
4
/Fe
3
O
4
35
1
, 50
2
1
Hot Water Leach
2
Acid Leach
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 21
5.2.3. Scanning Electron Microscopy/Energy Dispersive X-ray Analysis
Phase analysis using backscattered electron imaging in the scanning electron
microscope and EDX analysis was performed on Sample C (1000°C, 50% Na
2
CO
3
,
16.3% MnCO
3
), where the highest zinc extractions for this MnCO
3
addition were
observed (Fig. 17 and Fig. 18). This analysis provided a much clearer picture of the
phases present in the roasted EAF dust than x-ray diffraction.
FIG. 17 Secondary Electron (SE) and Backscattered Electron (BSE) Images of EAF
Dust after Roasting at 1000°C with 50% Na
2
CO
3
and 16.3%MnCO
3
(Sample C)
22 P. C. Holloway and T. H. Etsell Vol.7, No.1
After roasting, zinc oxide is visible as bright particles (A) in the backscattered
images in Sample C (Fig. 17). Ferrites containing Mn, Fe and O (i.e., MnFe
2
O
4
(B)) are
the dominant iron bearing phase identified, but particles high in Ca, Fe and O (i.e.,
CaFe
2
O
5
(C)) are also identified and both are consistent with the phases detected using x-
ray diffraction. In addition, some darker particles were shown to be high in Ca, Si and O
(i.e.,Ca
2
SiO
4
(D)) or high in Ca and O (i.e., CaO/Ca(OH)
2
(E)). The particles in view in
some of the SEM micrographs are very interesting texturally, showing what appear to be
lamellar type layers of MnFe
2
O
4
and ZnO in some particles.
FIG. 18 Secondary Electron (SE) and Backscattered Electron (BSE) Images of EAF
Dust after Roasting at 1000°C with 50% Na
2
CO
3
and 16.3%MnCO
3
and
Leaching with 200 g/L H
2
SO
4
(Sample C)
After leaching with 200 g/L H
2
SO
4
, the leach residue for Sample C showed
gypsum (A), present as fine elongate crystals, as the major phase and likely forms
because of the dissolution of larnite (Ca
2
SiO
4
) and reprecipitation of the dissolved
calcium as gypsum during leaching (Fig. 18). Iron is present mostly as metal ferrites,
with particles high in Fe, Mn and O (i.e., MnFe
2
O
4
(B)) or high in Fe, Mn, Zn and O (i.e.,
(Zn,Mn)Fe
2
O
4
(C)) being the most common in the SEM micrograph and particles high in
Ca, Fe and O (i.e., Ca
2
Fe
2
O
5
(E)) present in smaller quantities. (The presence of
significant amounts of (Zn,Mn)Fe
2
O
4
would be expected, with zinc extractions of less
than 90% at these roasting conditions.) Iron is also found in Particle D, which contains
Fe, Mn, Si and O, likely as a Mn-Fe silicate.
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 23
5.2.5. Iron and Zinc Deportment
From the above analysis, it is evident that the addition of MnCO
3
promotes the
formation of acid insoluble Mn-ferrites during roasting. This is indicated, first of all, by
the detection of Mn ferrites using SEM/EDX analysis both before and after leaching and,
second, by the decrease in iron extractions observed with increased MnCO
3
additions
during roasting. However, for roasting this sample of EAF dust with Na
2
CO
3
and
MnCO
3
, several phenomena remain unexplained.
First, small additions of MnCO
3
(4.3%) cause an initial increase in the iron
extractions observed, compared to those from roasting with Na
2
CO
3
alone, and additions
of up to 16.3% are required to return iron extractions to those observed from roasting
with Na
2
CO
3
alone. (In contrast, iron extractions from roasting La Oroya zinc ferrite with
MnCO
3
cause a steady decrease in iron extractions, compared to roasting with Na
2
CO
3
alone.) In roasting with low CaCO
3
additions, as discussed earlier, significant amounts of
Mn
2
FeO
4
, or other manganese rich ferrites, formed, resulting in less iron associated with
manganese and, thus, more iron available to react with Na
2
CO
3
to form acid soluble iron
compounds. A similar phenomenon may occur during roasting of the EAF dust with
MnCO
3
, resulting, initially, in higher iron extractions and, then, in a steady decrease in
iron extractions with higher MnCO
3
additions as MnCO
3
reacts with NaFeO
2
to form
MnFe
2
O
4
.
Second, increased MnCO
3
additions drastically decrease the zinc extractions
possible at a given temperature. A similar phenomenon is observed for roasting La Oroya
zinc ferrite with MnCO
3
, but the effect is much less significant, even at MnCO
3
additions
of up to 35% [8]. The behaviour could be caused either by the presence of a ZnFe
2
O
4
-
MnFe
2
O
4
solid solution in the EAF dust initially, or by its formation during roasting,
either by crystallization of the EAF dust after heating in the presence of Mn either in the
dust or added as MnCO
3
, or by reaction of ZnFe
2
O
4
in the EAF dust with the manganese
added as MnCO
3
. (Tests indicate that, at high temperatures, MnCO
3
added without the
addition of Na
2
CO
3
to La Oroya zinc ferrite readily reacts to form a ZnFe
2
O
4
-MnFe
2
O
4
solid solution leading to a low zinc extraction [8,12].) If the majority of the zinc is
present as a solid solution in (Zn,Mn)Fe
2
O
4
, then it is possible that the increase in
manganese content could decrease the activity of ZnFe
2
O
4
in the roasting reactions,
which, in turn, could decrease the zinc extractions possible after roasting.
To examine this possibility, calculations were made to determine the effect of
ZnFe
2
O
4
activity on the thermodynamics of the roasting reaction (ZnFe
2
O
4
+ Na
2
CO
3
2 NaFeO
2
+ ZnO + CO
2
(G°=163-0.149T (kJ/mol)) using the equation,
G=G°+RTlnK. Several assumptions were made in these calculations, including
assuming that all the manganese in the feed, and that added as MnCO
3
during roasting,
reacts to form a solid solution of (Zn,Mn)Fe
2
O
4
, that the activity of ZnFe
2
O
4
in that solid
solution is defined by Raoult’s law (i.e., ideal solution), that P
CO
¿
is approximately 1 atm
close to the reaction surface, that little change occurs in the activities of the other solids
in the equilibrium constant expression over the temperature range considered (i.e.,
a
solids
1, and, thus, K
1/a
ZnFe
¿
O
Á
) and
that the maximum zinc extraction occurs where
24 P. C. Holloway and T. H. Etsell Vol.7, No.1
the activity of ZnFe
2
O
4
is lowered enough to cause G to equal zero for a given
temperature. Based on these assumptions, Fig. 19 was constructed to compare the
theoretical maximum extractions from these activity and thermodynamic calculations
with the extractions observed for roasting with 50% Na
2
CO
3
for each temperature from
the response surface models (Fig. 12 to Fig. 14) for each level of MnCO
3
used in the
DOE tests.
FIG. 19 Comparison of Maximum Zinc Extractions and Zinc Extractions at 50%
Na
2
CO
3
, from the Response Surface Models (RSM) with Maximum
Extractions Calculated from the Change in Activity in a (Zn,Mn)Fe
2
O
4
Solid Solution
Vol.7, No.1 Mineralogical Transformation of Altasteel EAF Dust 25
Fig. 19 clearly shows a decrease in the theoretical zinc extraction with an increase
in the MnCO
3
addition, which is a trend that is consistent with the experimental results,
as is the observed trend of increasing maximum zinc extraction with increasing roasting
temperature. Without MnCO
3
added, the theoretical and experimental zinc extractions do
not agree closely, except at 1000°C, and the curves diverge above that temperature. With
4.3% MnCO
3
, the curves agree between 925 and 975°C but diverge at lower or higher
temperatures. However, as the MnCO
3
additions are increased further, the discrepancy
between the maximum theoretical and experimental zinc extractions decrease to the point
that the curves converge above 950°C for 10.2% MnCO
3
addition and above 975°C for
16.3% MnCO
3
. Thus, it is probable that, at higher roasting temperatures, as MnCO
3
additions are increased, the activity of ZnFe
2
O
4
in the (Zn,Mn)Fe
2
O
4
spinel solid solution
does affect the maximum zinc extractions possible during roasting of this sample of EAF
dust with Na
2
CO
3
. Thus, this behaviour would be expected to make it increasingly
difficult to obtain high zinc extractions with high MnCO
3
additions.
6. CONCLUSIONS
From these results, neither CaCO
3
nor MnCO
3
was effective as a secondary
additive to reduce iron extractions during roasting with Na
2
CO
3
. Roasting with CaCO
3
increases the amount of iron dissolved in acid leaching. Iron extractions also increase
initially with the addition of MnCO
3
, but decrease with increasing MnCO
3
additions;
however, zinc extractions decreased significantly with increasing MnCO
3
additions and
no improvement in iron extractions over roasting with Na
2
CO
3
alone was observed.
From the mineralogical analysis, these process outcomes occur because the
addition of secondary additives to the Altasteel EAF dust caused significant changes
mineralogically compared to roasting with Na
2
CO
3
alone. Even low CaCO
3
additions
were shown to promote the formation of manganese rich iron oxides (e.g., Mn
2
FeO
4
)
which reduced the amount of iron associated with acid insoluble Mn-ferrites and caused
more iron to react with Na
2
CO
3
to form acid soluble NaFeO
2
during roasting. Low
additions of MnCO
3
may have had a similar effect, but larger MnCO
3
additions appear to
have encouraged the formation of a ZnFe
2
O
4
-MnFe
2
O
4
solid solution while roasting at
temperatures above 950°C which led to lower overall zinc recoveries during acid
leaching.
Because of the significant differences observed after comparison with roasting a
more crystalline material (i.e., the La Oroya zinc ferrite) with similar secondary additives,
it is likely that this reaction behaviour may be related to the low crystallinity of the
Altasteel EAF dust as, at the high roasting temperatures tested, the ionic compounds
added as secondary additives may produce changes in the initial mineralogy of the EAF
dust as it crystallizes upon heating which can significantly affect the results observed
from roasting with Na
2
CO
3
.
26 P. C. Holloway and T. H. Etsell Vol.7, No.1
ACKNOWLEDGEMENTS
The authors would like to thank Altasteel, a division of Scaw Metals Group, for
supplying a sample of electric arc furnace dust for metallurgical testing. The authors
would also like to thank NSERC and Alberta Ingenuity for supplying student funding that
helped support this research.
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