Ligand-field symmetry effects in Fe(II) polypyridyl compounds probed by transient X-ray absorption spectroscopy

Hana Cho; Matthew L. Strader; Kiryong Hong; Lindsey Jamula; Eric M. Gullikson; Tae Kyu Kim; Frank M. F. de Groot; James K. McCusker; Robert W. Schoenlein; Nils Huse

doi:10.1039/c2fd20040f

Ligand-field symmetry effects in Fe(II) polypyridyl compounds probed by transient X-ray absorption spectroscopy

Hana Cho, Matthew L. Strader, Kiryong Hong, Lindsey Jamula, Eric M. Gullikson, Tae Kyu Kim^*, Frank M. F. de Groot, James K. McCusker, Robert W. Schoenlein, Nils Huse

^*Corresponding author for this work

Sub Inorganic Chemistry and Catalysis

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

Abstract

Ultrafast excited-state evolution in polypyridyl Fe(II) complexes is of fundamental interest for understanding the origins of the sub-ps spin-state changes that occur upon photoexcitation of this class of compounds as well as for the potential impact such ultrafast dynamics have on incorporation of these compounds in solar energy conversion schemes or switchable optical storage technologies. We have demonstrated that ground-state and, more importantly, ultrafast time-resolved X-ray absorption methods can offer unique insights into the interplay between electronic and geometric structure that underpins the photo-induced dynamics of this class of compounds. The present contribution examines in greater detail how the symmetry of the ligand field surrounding the metal ion can be probed using these X-ray techniques. In particular, we show that steady-state K-edge spectroscopy of the nearest-neighbour nitrogen atoms reveals the characteristic chemical environment of the respective ligands and suggests an interesting target for future charge-transfer femtosecond and attosecond spectroscopy in the X-ray water window.

Original language	English
Pages (from-to)	463-474
Number of pages	12
Journal	Faraday discussions
Volume	157
DOIs	https://doi.org/10.1039/c2fd20040f
Publication status	Published - 2012

Funding

This work was supported by the Director, Office of Science, Office of Basic Energy Sciences, the Chemical Sciences, Geosciences, and Biosciences Division under the Department of Energy, Contract No. DE-AC02-05CH11231 (N.H., H. C., and R. W. S.) and Grant No. DE-FG02-01ER15282 (J.K.M.), as well as the National Research Foundation of Korea (NRF) funded by the Korea government (Grant No. 2009-0068446, 2010-0006570, and 2007-0056330), MEST, PAL, and the Korean XFEL project (H. C., K. H., and T.K.K.).

Keywords

INDUCED SPIN-CROSSOVER
ANISOTROPIC DIELECTRICS
STATE INTERCONVERSION
ELECTRONIC-STRUCTURE
FERROUS COMPLEXES
EXCITED-STATES
DYNAMICS
IRON(II)
SUBPICOSECOND
MODEL

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C2fd20040f[1]
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title = "Ligand-field symmetry effects in Fe(II) polypyridyl compounds probed by transient X-ray absorption spectroscopy",

abstract = "Ultrafast excited-state evolution in polypyridyl Fe(II) complexes is of fundamental interest for understanding the origins of the sub-ps spin-state changes that occur upon photoexcitation of this class of compounds as well as for the potential impact such ultrafast dynamics have on incorporation of these compounds in solar energy conversion schemes or switchable optical storage technologies. We have demonstrated that ground-state and, more importantly, ultrafast time-resolved X-ray absorption methods can offer unique insights into the interplay between electronic and geometric structure that underpins the photo-induced dynamics of this class of compounds. The present contribution examines in greater detail how the symmetry of the ligand field surrounding the metal ion can be probed using these X-ray techniques. In particular, we show that steady-state K-edge spectroscopy of the nearest-neighbour nitrogen atoms reveals the characteristic chemical environment of the respective ligands and suggests an interesting target for future charge-transfer femtosecond and attosecond spectroscopy in the X-ray water window.",

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author = "Hana Cho and Strader, {Matthew L.} and Kiryong Hong and Lindsey Jamula and Gullikson, {Eric M.} and Kim, {Tae Kyu} and {de Groot}, {Frank M. F.} and McCusker, {James K.} and Schoenlein, {Robert W.} and Nils Huse",

year = "2012",

doi = "10.1039/c2fd20040f",

language = "English",

volume = "157",

pages = "463--474",

journal = "Faraday discussions",

issn = "1359-6640",

publisher = "Royal Society of Chemistry",

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AU - Cho, Hana

AU - Strader, Matthew L.

AU - Hong, Kiryong

AU - Jamula, Lindsey

AU - Gullikson, Eric M.

AU - Kim, Tae Kyu

AU - de Groot, Frank M. F.

AU - McCusker, James K.

AU - Schoenlein, Robert W.

AU - Huse, Nils

PY - 2012

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N2 - Ultrafast excited-state evolution in polypyridyl Fe(II) complexes is of fundamental interest for understanding the origins of the sub-ps spin-state changes that occur upon photoexcitation of this class of compounds as well as for the potential impact such ultrafast dynamics have on incorporation of these compounds in solar energy conversion schemes or switchable optical storage technologies. We have demonstrated that ground-state and, more importantly, ultrafast time-resolved X-ray absorption methods can offer unique insights into the interplay between electronic and geometric structure that underpins the photo-induced dynamics of this class of compounds. The present contribution examines in greater detail how the symmetry of the ligand field surrounding the metal ion can be probed using these X-ray techniques. In particular, we show that steady-state K-edge spectroscopy of the nearest-neighbour nitrogen atoms reveals the characteristic chemical environment of the respective ligands and suggests an interesting target for future charge-transfer femtosecond and attosecond spectroscopy in the X-ray water window.

AB - Ultrafast excited-state evolution in polypyridyl Fe(II) complexes is of fundamental interest for understanding the origins of the sub-ps spin-state changes that occur upon photoexcitation of this class of compounds as well as for the potential impact such ultrafast dynamics have on incorporation of these compounds in solar energy conversion schemes or switchable optical storage technologies. We have demonstrated that ground-state and, more importantly, ultrafast time-resolved X-ray absorption methods can offer unique insights into the interplay between electronic and geometric structure that underpins the photo-induced dynamics of this class of compounds. The present contribution examines in greater detail how the symmetry of the ligand field surrounding the metal ion can be probed using these X-ray techniques. In particular, we show that steady-state K-edge spectroscopy of the nearest-neighbour nitrogen atoms reveals the characteristic chemical environment of the respective ligands and suggests an interesting target for future charge-transfer femtosecond and attosecond spectroscopy in the X-ray water window.

KW - INDUCED SPIN-CROSSOVER

KW - ANISOTROPIC DIELECTRICS

KW - STATE INTERCONVERSION

KW - ELECTRONIC-STRUCTURE

KW - FERROUS COMPLEXES

KW - EXCITED-STATES

KW - DYNAMICS

KW - IRON(II)

KW - SUBPICOSECOND

KW - MODEL

U2 - 10.1039/c2fd20040f

DO - 10.1039/c2fd20040f

M3 - Article

SN - 1359-6640

VL - 157

SP - 463

EP - 474

JO - Faraday discussions

JF - Faraday discussions

ER -

Ligand-field symmetry effects in Fe(II) polypyridyl compounds probed by transient X-ray absorption spectroscopy

Abstract

Funding

Keywords

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