Adatom Fe(III) on the hematite surface: Observation of a key reactive surface species

Carrick M. Eggleston; Andrew G. Stack; Kevin M. Rosso; Angela M. Bice

doi:10.1063/1.1772991

Adatom Fe(III) on the hematite surface: Observation of a key reactive surface species

Carrick M. Eggleston, Andrew G. Stack, Kevin M. Rosso, Angela M. Bice

Research output: Contribution to journal › Article › peer-review

44 Scopus citations

Abstract

The reactivity of a mineral surface is determined by the variety and population of different types of surface sites (e.g., step, kink, adatom, and defect sites). The concept of "adsorbed nutrient" has been built into crystal growth theories, and many other studies of mineral surface reactivity appeal to ill-defined "active sites." Despite their theoretical importance, there has been little direct experimental or analytical investigation of the structure and properties of such species. Here, we use ex-situ and in-situ scanning tunneling microcopy (STM) combined with calculated images based on a resonant tunneling model to show that observed nonperiodic protrusions and depressions on the hematite (001) surface can be explained as Fe in an adsorbed or adatom state occupying sites different from those that result from simple termination of the bulk mineral. The number of such sites varies with sample preparation history, consistent with their removal from the surface in low pH solutions.

Original language	English
Pages (from-to)	33-40
Number of pages	8
Journal	Geochemical Transactions
Volume	5
Issue number	2
DOIs	https://doi.org/10.1063/1.1772991
State	Published - 2004
Externally published	Yes

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abstract = "The reactivity of a mineral surface is determined by the variety and population of different types of surface sites (e.g., step, kink, adatom, and defect sites). The concept of {"}adsorbed nutrient{"} has been built into crystal growth theories, and many other studies of mineral surface reactivity appeal to ill-defined {"}active sites.{"} Despite their theoretical importance, there has been little direct experimental or analytical investigation of the structure and properties of such species. Here, we use ex-situ and in-situ scanning tunneling microcopy (STM) combined with calculated images based on a resonant tunneling model to show that observed nonperiodic protrusions and depressions on the hematite (001) surface can be explained as Fe in an adsorbed or adatom state occupying sites different from those that result from simple termination of the bulk mineral. The number of such sites varies with sample preparation history, consistent with their removal from the surface in low pH solutions.",

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AU - Eggleston, Carrick M.

AU - Stack, Andrew G.

AU - Rosso, Kevin M.

AU - Bice, Angela M.

PY - 2004

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AB - The reactivity of a mineral surface is determined by the variety and population of different types of surface sites (e.g., step, kink, adatom, and defect sites). The concept of "adsorbed nutrient" has been built into crystal growth theories, and many other studies of mineral surface reactivity appeal to ill-defined "active sites." Despite their theoretical importance, there has been little direct experimental or analytical investigation of the structure and properties of such species. Here, we use ex-situ and in-situ scanning tunneling microcopy (STM) combined with calculated images based on a resonant tunneling model to show that observed nonperiodic protrusions and depressions on the hematite (001) surface can be explained as Fe in an adsorbed or adatom state occupying sites different from those that result from simple termination of the bulk mineral. The number of such sites varies with sample preparation history, consistent with their removal from the surface in low pH solutions.

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Adatom Fe(III) on the hematite surface: Observation of a key reactive surface species

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