High spatial frequency laser induced periodic surface structure formation in germanium by mid-IR femtosecond pulses

Drake R. Austin; Kyle R.P. Kafka; Yu Hang Lai; Zhou Wang; Kaikai Zhang; Hui Li; Cosmin I. Blaga; Allen Y. Yi; Louis F. DiMauro; Enam A. Chowdhury

doi:10.1063/1.4964737

High spatial frequency laser induced periodic surface structure formation in germanium by mid-IR femtosecond pulses

Drake R. Austin
, Kyle R.P. Kafka
, Yu Hang Lai
, Zhou Wang
, Kaikai Zhang
, Hui Li
, Cosmin I. Blaga
, Allen Y. Yi
, Louis F. DiMauro
, Enam A. Chowdhury

Ohio State University

科研成果: 期刊稿件 › 文章 › 同行评审

27 引用（Scopus）

摘要

Formation of high spatial frequency laser induced periodic surface structures (HSFL) in germanium by 90 fs mid-IR pulses at a 1 kHz repetition rate with wavelengths between λ = 2 and 3.6 μm was studied with varying angle of incidence and polarization. The period of these structures varied from λ/3 to λ/8. A modified surface-scattering model including Drude excitation and the optical Kerr effect explains the spatial period scaling of HSFL across the mid-IR wavelengths. Transmission electron microscopy shows the presence of a 30 nm amorphous layer above the structure of crystalline germanium. Various mechanisms including two photon absorption and defect-induced amorphization are discussed as probable causes for the formation of this layer.

源语言	英语
文章编号	143103
期刊	Journal of Applied Physics
卷	120
期	14
DOI	https://doi.org/10.1063/1.4964737
出版状态	已出版 - 14 10月 2016
已对外发布	是

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title = "High spatial frequency laser induced periodic surface structure formation in germanium by mid-IR femtosecond pulses",

abstract = "Formation of high spatial frequency laser induced periodic surface structures (HSFL) in germanium by 90 fs mid-IR pulses at a 1 kHz repetition rate with wavelengths between λ = 2 and 3.6 μm was studied with varying angle of incidence and polarization. The period of these structures varied from λ/3 to λ/8. A modified surface-scattering model including Drude excitation and the optical Kerr effect explains the spatial period scaling of HSFL across the mid-IR wavelengths. Transmission electron microscopy shows the presence of a 30 nm amorphous layer above the structure of crystalline germanium. Various mechanisms including two photon absorption and defect-induced amorphization are discussed as probable causes for the formation of this layer.",

author = "Austin, \{Drake R.\} and Kafka, \{Kyle R.P.\} and Lai, \{Yu Hang\} and Zhou Wang and Kaikai Zhang and Hui Li and Blaga, \{Cosmin I.\} and Yi, \{Allen Y.\} and DiMauro, \{Louis F.\} and Chowdhury, \{Enam A.\}",

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AU - Austin, Drake R.

AU - Kafka, Kyle R.P.

AU - Lai, Yu Hang

AU - Wang, Zhou

AU - Zhang, Kaikai

AU - Li, Hui

AU - Blaga, Cosmin I.

AU - Yi, Allen Y.

AU - DiMauro, Louis F.

AU - Chowdhury, Enam A.

PY - 2016/10/14

Y1 - 2016/10/14

N2 - Formation of high spatial frequency laser induced periodic surface structures (HSFL) in germanium by 90 fs mid-IR pulses at a 1 kHz repetition rate with wavelengths between λ = 2 and 3.6 μm was studied with varying angle of incidence and polarization. The period of these structures varied from λ/3 to λ/8. A modified surface-scattering model including Drude excitation and the optical Kerr effect explains the spatial period scaling of HSFL across the mid-IR wavelengths. Transmission electron microscopy shows the presence of a 30 nm amorphous layer above the structure of crystalline germanium. Various mechanisms including two photon absorption and defect-induced amorphization are discussed as probable causes for the formation of this layer.

AB - Formation of high spatial frequency laser induced periodic surface structures (HSFL) in germanium by 90 fs mid-IR pulses at a 1 kHz repetition rate with wavelengths between λ = 2 and 3.6 μm was studied with varying angle of incidence and polarization. The period of these structures varied from λ/3 to λ/8. A modified surface-scattering model including Drude excitation and the optical Kerr effect explains the spatial period scaling of HSFL across the mid-IR wavelengths. Transmission electron microscopy shows the presence of a 30 nm amorphous layer above the structure of crystalline germanium. Various mechanisms including two photon absorption and defect-induced amorphization are discussed as probable causes for the formation of this layer.

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DO - 10.1063/1.4964737

M3 - 文章

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SN - 0021-8979

VL - 120

JO - Journal of Applied Physics

JF - Journal of Applied Physics

IS - 14

M1 - 143103

ER -

High spatial frequency laser induced periodic surface structure formation in germanium by mid-IR femtosecond pulses

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