Mie-resonances, infrared emission and band gap of InN

A. Kasic; A. Kavokin; A. Vasson; B. Monemar; C. Stampfl; D. D. Solnyshkov; D. D. Nolte; G. Mie; H. Amano; I. Tamm; J. Leymarie; J. C. Maxwell-Garnett; K. Shimono; L. Tansley; L. D. Landau; P. S. Kop’ev; R. Y. Koyama; S. V. Ivanov; S. V. Ivanov; T. Inushima; T. V. Shubina; U. Kreibig; V. A. Vekshin; V. N. Jmerik; V. V. Sobolev

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Mie-resonances, infrared emission and band gap of InN

Authors: A. Kasic
A. Kavokin
A. Vasson
B. Monemar
C. Stampfl
D. D. Solnyshkov
D. D. Nolte
G. Mie
H. Amano
I. Tamm
J. Leymarie
J. C. Maxwell-Garnett
K. Shimono
L. Tansley
L. D. Landau
P. S. Kop’ev
R. Y. Koyama
S. V. Ivanov
S. V. Ivanov
T. Inushima
T. V. Shubina
U. Kreibig
V. A. Vekshin
V. N. Jmerik
V. V. Sobolev
Publication date: 30 October 2003
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Mie resonances due to scattering/absorption of light in InN containing clusters of metallic In may have been erroneously interpreted as the infrared band gap absorption in tens of papers. Here we show by direct thermally detected optical absorption measurements that the true band gap of InN is markedly wider than currently accepted 0.7 eV. Micro-cathodoluminescence studies complemented by imaging of metallic In have shown that bright infrared emission at 0.7-0.8 eV arises from In aggregates, and is likely associated with surface states at the metal/InN interfaces.Comment: 4 pages, 5 figures, submitted to PR

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