Multiband Laser Action from Organic-Organic Heteroepitaxial Nanofibers

Francesco Quochi; Francesco Floris; Clemens Peter Simbrunner; Günther Schwabegger; Michele Saba; Andrea Mura; Helmut Sitter; Giovanni Bongiovanni

doi:10.1557/opl.2014.115

Multiband Laser Action from Organic-Organic Heteroepitaxial Nanofibers

Francesco Quochi, Francesco Floris, Clemens Peter Simbrunner, Günther Schwabegger, Michele Saba, Andrea Mura, Helmut Sitter, Giovanni Bongiovanni

Department of Solid State Physics

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

We report successful tuning of laser wavelength from ∼420 nm to ∼600 nm in epitaxially aligned nanofibers grown by periodic deposition of para-sexiphenyl (p6P) and sexithiophene (6T) on p-6P/muscovite mica templates. The nanofibers were photoexcited by subpicosecond pulses tuned to the lowest p6P absorption band, and the emission of 6T, whose coverage was kept in the submonolayer regime, was efficiently sensitized through resonance energy transfer (RET). The 6T lasing was achieved at room temperature with threshold fluences as low as 10 μJ/cm2 per pulse. Transient photoluminescence measurements, with picosecond resolution, showed that at these pump fluences the decay dynamics of 6T emission is independent of the excitation density, thereby demonstrating the attainment of room-temperature monomolecular lasing from epitaxially oriented 6T submonolayer aggregates. Main lasing properties remained unaltered upon direct photoexcitation of 6T below the p6P absorption edge.

Original language	English
Title of host publication	Symposium Q – Organic MicrolasersÂ—From Fundamentals to Device Application
Number of pages	6
Volume	1632
DOIs	https://doi.org/10.1557/opl.2014.115
Publication status	Published - Jan 2014

Publication series

Name	MRS Proceedings

Fields of science

210006 Nanotechnology
103 Physics, Astronomy
103011 Semiconductor physics
103018 Materials physics
202032 Photovoltaics
103009 Solid state physics
103017 Magnetism

JKU Focus areas

Engineering and Natural Sciences (in general)

Access to Document

10.1557/opl.2014.115

Cite this

@inproceedings{6e02a20732be48f4a09a601ff707bf8e,

title = "Multiband Laser Action from Organic-Organic Heteroepitaxial Nanofibers",

abstract = "We report successful tuning of laser wavelength from ∼420 nm to ∼600 nm in epitaxially aligned nanofibers grown by periodic deposition of para-sexiphenyl (p6P) and sexithiophene (6T) on p-6P/muscovite mica templates. The nanofibers were photoexcited by subpicosecond pulses tuned to the lowest p6P absorption band, and the emission of 6T, whose coverage was kept in the submonolayer regime, was efficiently sensitized through resonance energy transfer (RET). The 6T lasing was achieved at room temperature with threshold fluences as low as 10 μJ/cm2 per pulse. Transient photoluminescence measurements, with picosecond resolution, showed that at these pump fluences the decay dynamics of 6T emission is independent of the excitation density, thereby demonstrating the attainment of room-temperature monomolecular lasing from epitaxially oriented 6T submonolayer aggregates. Main lasing properties remained unaltered upon direct photoexcitation of 6T below the p6P absorption edge.",

author = "Francesco Quochi and Francesco Floris and Simbrunner, {Clemens Peter} and G{\"u}nther Schwabegger and Michele Saba and Andrea Mura and Helmut Sitter and Giovanni Bongiovanni",

year = "2014",

month = jan,

doi = "10.1557/opl.2014.115",

language = "English",

volume = "1632",

series = "MRS Proceedings",

booktitle = "Symposium Q – Organic Microlasers{\^A}—From Fundamentals to Device Application",

}

TY - GEN

T1 - Multiband Laser Action from Organic-Organic Heteroepitaxial Nanofibers

AU - Quochi, Francesco

AU - Floris, Francesco

AU - Simbrunner, Clemens Peter

AU - Schwabegger, Günther

AU - Saba, Michele

AU - Mura, Andrea

AU - Sitter, Helmut

AU - Bongiovanni, Giovanni

PY - 2014/1

Y1 - 2014/1

N2 - We report successful tuning of laser wavelength from ∼420 nm to ∼600 nm in epitaxially aligned nanofibers grown by periodic deposition of para-sexiphenyl (p6P) and sexithiophene (6T) on p-6P/muscovite mica templates. The nanofibers were photoexcited by subpicosecond pulses tuned to the lowest p6P absorption band, and the emission of 6T, whose coverage was kept in the submonolayer regime, was efficiently sensitized through resonance energy transfer (RET). The 6T lasing was achieved at room temperature with threshold fluences as low as 10 μJ/cm2 per pulse. Transient photoluminescence measurements, with picosecond resolution, showed that at these pump fluences the decay dynamics of 6T emission is independent of the excitation density, thereby demonstrating the attainment of room-temperature monomolecular lasing from epitaxially oriented 6T submonolayer aggregates. Main lasing properties remained unaltered upon direct photoexcitation of 6T below the p6P absorption edge.

AB - We report successful tuning of laser wavelength from ∼420 nm to ∼600 nm in epitaxially aligned nanofibers grown by periodic deposition of para-sexiphenyl (p6P) and sexithiophene (6T) on p-6P/muscovite mica templates. The nanofibers were photoexcited by subpicosecond pulses tuned to the lowest p6P absorption band, and the emission of 6T, whose coverage was kept in the submonolayer regime, was efficiently sensitized through resonance energy transfer (RET). The 6T lasing was achieved at room temperature with threshold fluences as low as 10 μJ/cm2 per pulse. Transient photoluminescence measurements, with picosecond resolution, showed that at these pump fluences the decay dynamics of 6T emission is independent of the excitation density, thereby demonstrating the attainment of room-temperature monomolecular lasing from epitaxially oriented 6T submonolayer aggregates. Main lasing properties remained unaltered upon direct photoexcitation of 6T below the p6P absorption edge.

U2 - 10.1557/opl.2014.115

DO - 10.1557/opl.2014.115

M3 - Conference proceedings

VL - 1632

T3 - MRS Proceedings

BT - Symposium Q – Organic MicrolasersÂ—From Fundamentals to Device Application

ER -