Photon upconversion in trivalent erbium ions

Jeppe Christiansen

Photon upconversion in trivalent erbium ions

Jeppe Christiansen

Department of Physics and Astronomy

Research output: Book/anthology/dissertation/report › Ph.D. thesis

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Abstract

This PhD thesis reports on the experimental and theoretical investigation of 1500 nm to 980 nm photon upconversion in thin films of erbium-doped TiO2, which has applications in improving silicon-based solar cells through upconversion of sub-band-gap photons. Three main publications are included in this thesis reporting on: i) the development of a rate-equation model, ii) the upconversion-luminescence (UCL) dependence on the fabrication parameters, and iii) incorporating gold nanostructures for enhancing the upconversion efficiency through photonic enhancement.

The developed rate-equation model can account for the UCL-intensity dependence over a broad dynamic range, and through the model, a new benchmark parameter -- the saturation intensity -- is introduced. The investigation on the fabrication process shows generally increased UCL yield with deposition temperature up to 350 C and that post-annealing treatment quenches the UCL yield. Through the study of photonic enhancement, an unprecedented 913(51)-fold enhancement of the UCL yield is measured at an intensity of 1.7 W/cm2. The results are compared to an extended version of the rate-equation model with a good qualitative agreement. Through the extended rate-equation model, it is possible to determine the concentration of the mean electromagnetic energy density in the upconverting films, which, together with the saturation intensity, allows for a justified prediction on the required steps before photonic-enhanced upconverters will see the light of day.

The thesis concludes with an assessment of the developed rate-equation model through a comparison of measured and calculated external upconversion quantum yields with outstanding agreement assuming similar absorption strength, as reported in the literature. The assumption of an average energy-transfer rate in the rate-equation model is corroborated through calculation showing a strong coupling of the erbium ions. Lastly, an experiment is proposed for further investigations of the crucial upconversion parameter -- the energy-transfer rate.

Translated title of the contribution	Foton opkonvertering i trvalente erbium ioner
Original language	English

Place of publication	Aarhus
Publisher	Århus Universitet
Number of pages	163
Publication status	Published - Jan 2020

2 Journal article

Analytical model for the intensity dependence of 1500 nm to 980 nm upconversion in Er ³⁺: A new tool for material characterization
Christiansen, J., Lakhotiya, H., Eriksen, E., Madsen, S. P., Balling, P. & Julsgaard, B., 2019, In: Journal of Applied Physics. 125, 4, 8 p., 043106.
Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

Open Access
15 Citations (Scopus)
Upconversion luminescence from magnetron-sputtered Er3+-doped TiO2 films: Influence of deposition- and annealing temperatures and correlation to decay times
Lakhotiya, H., Christiansen, J., Hansen, J. L., BaIling, P. & Julsgaard, B., 28 Oct 2018, In: Journal of Applied Physics. 124, 16, 7 p., 163105.
Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review
8 Citations (Scopus)

Cite this

@phdthesis{64adb5fee593478ab0676c937711a947,

title = "Photon upconversion in trivalent erbium ions",

abstract = "This PhD thesis reports on the experimental and theoretical investigation of 1500 nm to 980 nm photon upconversion in thin films of erbium-doped TiO2, which has applications in improving silicon-based solar cells through upconversion of sub-band-gap photons. Three main publications are included in this thesis reporting on: i) the development of a rate-equation model, ii) the upconversion-luminescence (UCL) dependence on the fabrication parameters, and iii) incorporating gold nanostructures for enhancing the upconversion efficiency through photonic enhancement.The developed rate-equation model can account for the UCL-intensity dependence over a broad dynamic range, and through the model, a new benchmark parameter -- the saturation intensity -- is introduced. The investigation on the fabrication process shows generally increased UCL yield with deposition temperature up to 350 C and that post-annealing treatment quenches the UCL yield. Through the study of photonic enhancement, an unprecedented 913(51)-fold enhancement of the UCL yield is measured at an intensity of 1.7 W/cm2. The results are compared to an extended version of the rate-equation model with a good qualitative agreement. Through the extended rate-equation model, it is possible to determine the concentration of the mean electromagnetic energy density in the upconverting films, which, together with the saturation intensity, allows for a justified prediction on the required steps before photonic-enhanced upconverters will see the light of day.The thesis concludes with an assessment of the developed rate-equation model through a comparison of measured and calculated external upconversion quantum yields with outstanding agreement assuming similar absorption strength, as reported in the literature. The assumption of an average energy-transfer rate in the rate-equation model is corroborated through calculation showing a strong coupling of the erbium ions. Lastly, an experiment is proposed for further investigations of the crucial upconversion parameter -- the energy-transfer rate.",

keywords = "upconversion, luminescent rare-earth ions, improving silicon-based photovoltaics",

author = "Jeppe Christiansen",

note = "Forsvaret d. 28/1 2020",

year = "2020",

month = jan,

language = "English",

publisher = "{\AA}rhus Universitet",

}

TY - BOOK

T1 - Photon upconversion in trivalent erbium ions

AU - Christiansen, Jeppe

N1 - Forsvaret d. 28/1 2020

PY - 2020/1

Y1 - 2020/1

N2 - This PhD thesis reports on the experimental and theoretical investigation of 1500 nm to 980 nm photon upconversion in thin films of erbium-doped TiO2, which has applications in improving silicon-based solar cells through upconversion of sub-band-gap photons. Three main publications are included in this thesis reporting on: i) the development of a rate-equation model, ii) the upconversion-luminescence (UCL) dependence on the fabrication parameters, and iii) incorporating gold nanostructures for enhancing the upconversion efficiency through photonic enhancement.The developed rate-equation model can account for the UCL-intensity dependence over a broad dynamic range, and through the model, a new benchmark parameter -- the saturation intensity -- is introduced. The investigation on the fabrication process shows generally increased UCL yield with deposition temperature up to 350 C and that post-annealing treatment quenches the UCL yield. Through the study of photonic enhancement, an unprecedented 913(51)-fold enhancement of the UCL yield is measured at an intensity of 1.7 W/cm2. The results are compared to an extended version of the rate-equation model with a good qualitative agreement. Through the extended rate-equation model, it is possible to determine the concentration of the mean electromagnetic energy density in the upconverting films, which, together with the saturation intensity, allows for a justified prediction on the required steps before photonic-enhanced upconverters will see the light of day.The thesis concludes with an assessment of the developed rate-equation model through a comparison of measured and calculated external upconversion quantum yields with outstanding agreement assuming similar absorption strength, as reported in the literature. The assumption of an average energy-transfer rate in the rate-equation model is corroborated through calculation showing a strong coupling of the erbium ions. Lastly, an experiment is proposed for further investigations of the crucial upconversion parameter -- the energy-transfer rate.

AB - This PhD thesis reports on the experimental and theoretical investigation of 1500 nm to 980 nm photon upconversion in thin films of erbium-doped TiO2, which has applications in improving silicon-based solar cells through upconversion of sub-band-gap photons. Three main publications are included in this thesis reporting on: i) the development of a rate-equation model, ii) the upconversion-luminescence (UCL) dependence on the fabrication parameters, and iii) incorporating gold nanostructures for enhancing the upconversion efficiency through photonic enhancement.The developed rate-equation model can account for the UCL-intensity dependence over a broad dynamic range, and through the model, a new benchmark parameter -- the saturation intensity -- is introduced. The investigation on the fabrication process shows generally increased UCL yield with deposition temperature up to 350 C and that post-annealing treatment quenches the UCL yield. Through the study of photonic enhancement, an unprecedented 913(51)-fold enhancement of the UCL yield is measured at an intensity of 1.7 W/cm2. The results are compared to an extended version of the rate-equation model with a good qualitative agreement. Through the extended rate-equation model, it is possible to determine the concentration of the mean electromagnetic energy density in the upconverting films, which, together with the saturation intensity, allows for a justified prediction on the required steps before photonic-enhanced upconverters will see the light of day.The thesis concludes with an assessment of the developed rate-equation model through a comparison of measured and calculated external upconversion quantum yields with outstanding agreement assuming similar absorption strength, as reported in the literature. The assumption of an average energy-transfer rate in the rate-equation model is corroborated through calculation showing a strong coupling of the erbium ions. Lastly, an experiment is proposed for further investigations of the crucial upconversion parameter -- the energy-transfer rate.

KW - upconversion

KW - luminescent rare-earth ions

KW - improving silicon-based photovoltaics

M3 - Ph.D. thesis

BT - Photon upconversion in trivalent erbium ions

PB - Århus Universitet

CY - Aarhus

ER -

Photon upconversion in trivalent erbium ions

Abstract

Research output

Analytical model for the intensity dependence of 1500 nm to 980 nm upconversion in Er 3+: A new tool for material characterization

Upconversion luminescence from magnetron-sputtered Er3+-doped TiO2 films: Influence of deposition- and annealing temperatures and correlation to decay times

Cite this

Analytical model for the intensity dependence of 1500 nm to 980 nm upconversion in Er ³⁺: A new tool for material characterization