Extremely high negative electron affinity of diamond via magnesium adsorption

K. M. O'Donnell; M. T. Edmonds; A. Tadich; L. Thomsen; A. Stacey; A. Schenk; C. I. Pakes; L. Ley

doi:10.1103/PhysRevB.92.035303

Extremely high negative electron affinity of diamond via magnesium adsorption

K. M. O'Donnell
, M. T. Edmonds
, A. Tadich
, L. Thomsen
, A. Stacey
, A. Schenk
, C. I. Pakes
, L. Ley

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

48 Scopus citations

Abstract

We report large negative electron affinity (NEA) on diamond (100) using magnesium adsorption on a previously oxygen-terminated surface. The measured NEA is up to (-2.01±0.05) eV, the largest reported negative electron affinity to date. Despite the expected close relationship between the surface chemistry of Mg and Li species on oxygen-terminated diamond, we observe differences in the adsorption properties between the two. Most importantly, a high-temperature annealing step is not required to activate the Mg-adsorbed surface to a state of negative electron affinity. Diamond surfaces prepared by this procedure continue to possess negative electron affinity after exposure to high temperatures, air, and even immersion in water.

Original language	English (US)
Article number	035303
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	92
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevB.92.035303
State	Published - Jul 16 2015
Externally published	Yes

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.92.035303

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title = "Extremely high negative electron affinity of diamond via magnesium adsorption",

abstract = "We report large negative electron affinity (NEA) on diamond (100) using magnesium adsorption on a previously oxygen-terminated surface. The measured NEA is up to (-2.01±0.05) eV, the largest reported negative electron affinity to date. Despite the expected close relationship between the surface chemistry of Mg and Li species on oxygen-terminated diamond, we observe differences in the adsorption properties between the two. Most importantly, a high-temperature annealing step is not required to activate the Mg-adsorbed surface to a state of negative electron affinity. Diamond surfaces prepared by this procedure continue to possess negative electron affinity after exposure to high temperatures, air, and even immersion in water.",

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T1 - Extremely high negative electron affinity of diamond via magnesium adsorption

AU - O'Donnell, K. M.

AU - Edmonds, M. T.

AU - Tadich, A.

AU - Thomsen, L.

AU - Stacey, A.

AU - Schenk, A.

AU - Pakes, C. I.

AU - Ley, L.

PY - 2015/7/16

Y1 - 2015/7/16

N2 - We report large negative electron affinity (NEA) on diamond (100) using magnesium adsorption on a previously oxygen-terminated surface. The measured NEA is up to (-2.01±0.05) eV, the largest reported negative electron affinity to date. Despite the expected close relationship between the surface chemistry of Mg and Li species on oxygen-terminated diamond, we observe differences in the adsorption properties between the two. Most importantly, a high-temperature annealing step is not required to activate the Mg-adsorbed surface to a state of negative electron affinity. Diamond surfaces prepared by this procedure continue to possess negative electron affinity after exposure to high temperatures, air, and even immersion in water.

AB - We report large negative electron affinity (NEA) on diamond (100) using magnesium adsorption on a previously oxygen-terminated surface. The measured NEA is up to (-2.01±0.05) eV, the largest reported negative electron affinity to date. Despite the expected close relationship between the surface chemistry of Mg and Li species on oxygen-terminated diamond, we observe differences in the adsorption properties between the two. Most importantly, a high-temperature annealing step is not required to activate the Mg-adsorbed surface to a state of negative electron affinity. Diamond surfaces prepared by this procedure continue to possess negative electron affinity after exposure to high temperatures, air, and even immersion in water.

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DO - 10.1103/PhysRevB.92.035303

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Extremely high negative electron affinity of diamond via magnesium adsorption

Abstract

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