The nature and impacts of fines in smelter-grade alumina

Perander, Linus; Žujović, Zoran D.; Kemp, Thomas F.; Smith, Mark E.; Metson, James B.

doi:10.1007/s11837-009-0164-x

Cited by 28 publications

(19 citation statements)

References 14 publications

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“…A high SSA material is an ineffective scrubbing agent if much of the porosity cannot be accessed fully on time scales relevant to dry scrubbing. This consideration has been recently been identified by Perander et al 9,10 who suggest that the finer porosity may be difficult to access. This becomes relevant when it is recognized that the SSA of a material of under-and over-calcined aluminas blended together may have a comparable BET SSA to a more evenly calcined material (so-called bimodal aluminas).…”

Section: Introductionmentioning

confidence: 81%

“…However, it has been recognized earlier that the smallest pores may not be readily accessible by HF. 9,10 This porosity, the surface area of which is included in the BET method, can vary considerably between different alumina sources and would therefore introduce a significant amount of noise into the model. Pore size distribution (PSD)-based surface areas were therefore explored.…”

Section: The Impact Of Alumina Pore Size On Fluoride Balances In An Omentioning

confidence: 99%

“…However, as one moves to increasingly narrow pores, limited access on kinetic grounds has been postulated. 9,10 The transition from unhindered access to kinetically restricted porosity, to which unique surface area loss models are to be applied, is not likely to occur abruptly at some threshold pore diameter. Therefore, our model partitions pores according to a gradually varying function that determines the fraction of the length of a pore of a given diameter that should be treated with the each of the adsorption models.…”

Section: Psd Reconstruction Modelsmentioning

confidence: 99%

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The Pivotal Role of Alumina Pore Structure in HF Capture and Fluoride Return in Aluminum Reduction

McIntosh

Agbenyegah

Hyland

et al. 2016

JOM

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Fluoride emissions during primary aluminum production are mitigated by dry scrubbing on alumina which, as the metal feedstock, also returns fluoride to the pots. This ensures stable pot operation and maintains process efficiency but requires careful optimization of alumina for both fluoride capture and solubility. The Brunauer-Emmett-Teller (BET) surface area of 70-80 m 2 g À1 is currently accepted. However, this does not account for pore accessibility. We demonstrate using industry-sourced data that pores <3.5 nm are not correlated with fluoride return. Reconstructing alumina pore size distributions (PSDs) following hydrogen fluoride (HF) adsorption shows surface area is not lost by pore diameter shrinkage, but by blocking the internal porosity. However, this alone cannot explain this 3.5 nm threshold. We show this is a consequence of surface diffusion-based inhibition with surface chemistry probably playing an integral role. We advocate new surface area estimates for alumina which account for pore accessibility by explicitly ignoring <3.5 nm pores.

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Section: Introductionmentioning

confidence: 81%

Section: The Impact Of Alumina Pore Size On Fluoride Balances In An Omentioning

confidence: 99%

Section: Psd Reconstruction Modelsmentioning

confidence: 99%

See 1 more Smart Citation

The Pivotal Role of Alumina Pore Structure in HF Capture and Fluoride Return in Aluminum Reduction

McIntosh

Agbenyegah

Hyland

et al. 2016

JOM

Self Cite

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“…Inconstant feeding can lead to over‐feeding and under‐feeding in the downstream refinery of aluminum, causing the forming of clusters onside the anode and the reduction of bath component respectively . Second, the content of α‐alumina in ultra‐fine particle is significantly higher than in larger particles, making it difficult to dissolve in the reaction cell . Moreover, ultra‐fine particles can cause health and environmental problems.…”

Section: Introductionmentioning

confidence: 99%

“…Gibbsite crystallite's cracking is widely considered as a result of the shrinkage of crystallites alongside their c ‐axis during calcination . Various factors, such as the calcination methods, the morphology of gibbsite particles, as well as the transition and storage condition can cast influence on the cracking and breakage of gibbsite particles.…”

Section: Introductionmentioning

confidence: 99%

Cracking Behavior and Mechanism of Gibbsite Crystallites during Calcination

Zhang

Chen

et al. 2018

Crystal Research and Technology

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Cracking is one of the major contributors to the breakage of gibbsite particles during calcination, which generates superfine particles causing detrimental effects to the quality of product in the downstream smelter grade alumina production. Therefore, understanding the cracking behavior and mechanism can provide a solution to avoid the generation of superfine particles. In this study, for the first time, the phase transformation and structural evolutions from gibbsite to boehmite then to amorphous alumina during calcination via using focus ion beam-scanning electronic microscopy and in situ transmission electron microscopy are investigated. After detailed and real-time observations, it is illustrated that the crack formation on gibbsite particles during calcination can be attributed to the stress introduced by crystal shrinkage inside the crystallites during the phase transformation. Moreover, cracks in calcined gibbsite crystallites are found to initiate as pores inside the crystallites, which grow toward the surface and then form open cracks. Studies will open the possibility to tune the breakage of gibbsite particles.

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