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Abstract

We present a dual-amplifier laser system for time-resolved multiple-probe infrared (IR) spectroscopy based on the ytterbium potassium gadolinium tungstate (Yb:KGW) laser medium. Comparisons are made between the ytterbium-based technology and titanium sapphire laser systems for time-resolved IR spectroscopy measurements. The 100 kHz probing system provides new capability in time-resolved multiple-probe experiments, as more information is obtained from samples in a single experiment through multiple-probing. This method uses the high repetition-rate probe pulses to repeatedly measure spectra at 10 µs intervals following excitation allowing extended timescales to be measured routinely along with ultrafast data. Results are presented showing the measurement of molecular dynamics over >10 orders of magnitude in timescale, out to 20 ms, with an experimental time response of <200 fs. The power of multiple-probing is explored through principal component analysis of repeating probe measurements as a novel method for removing noise and measurement artifacts.

Keywords

Ultrafast Time-resolved Mid-infrared (Mid-IR)Laser Spectroscopy Multiple-probing

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References

Greetham

G.M.

Sole

Clark

I.P.

Parker

A.W.

Pollard

M.R.

Towrie

“Time-resolved Multiple Probe Spectroscopy”. Rev. Sci. Instrum 2012; 83(10): 103107.

Wood

C.J.

Cheng

Clark

C.A.

Horvath

Clark

I.P.

Hamilton

M.L.

Towrie

George

M.W.

Sun

L.C.

Yang

X.C.

Gibson

E.A.

“Red-Absorbing Cationic Acceptor Dyes for Photocathodes in Tandem Solar Cells”. J. Phys. Chem. C 2014; 118(30): 16536–16546.

van der Salm

Fraser

M.G.

Horvath

Turner

J.O.

Greetham

G.M.

Clark

I.P.

Towrie

Lucas

N.T.

George

M.W.

Gordon

K.C.

“Dual Charge-Transfer in Rhenium(I) Thioether Substituted Hexaazanaphthalene Complexes”. Inorg. Chem 2014; 53(24): 13049–13060.

Lukacs

Haigney

Brust

Addison

Towrie

Greetham

G.M.

Jones

G.A.

Miyawaki

Tonge

P.J.

Meech

S.R.

“Protein Photochromism Observed by Ultrafast Vibrational Spectroscopy”. J. Phys. Chem. B 2013; 117(40): 11954–11959.

Brust

Lukacs

Haigney

Addison

Gil

Towrie

Clark

I.P.

Greetham

G.M.

Tonge

P.J.

Meech

S.R.

“Proteins in Action: Femtosecond to Millisecond Structural Dynamics of a Photoactive Flavoprotein”. J. Am. Chem. Soc 2013; 135(43): 16168–16174.

Russell

H.J.

Hardman

S.J.O.

Heyes

D.J.

Hough

M.A.

Greetham

G.M.

Towrie

Hay

Scrutton

N.S.

“Modulation of Ligand-heme Reactivity by Binding Pocket Residues Demonstrated in Cytochrome c' over the Femtosecond-second Temporal Range”. FEBS J 2013; 280(23): 6070–6082.

Hauck

A.F.E.

Hardman

S.J.O.

Kutta

R.J.

Greetham

G.M.

Heyes

D.J.

Scrutton

N.S.

“The Photoinitiated Reaction Pathway of Full-length Cyanobacteriochrome Tlr0924 Monitored Over 12 Orders of Magnitude”. J. Biol. Chem 2014; 289(25): 17747–17757.

Hardman

S.J.O.

Hauck

A.F.E.

Clark

I.P.

Heyes

D.J.

Scrutton

N.S.

“Comprehensive Analysis of the Green-to-Blue Photoconversion of Full-Length Cyanobacteriochrome Tlr0924”. Biophys. J 2014; 107(9): 2195–2203.

Heyes

D.J.

Hardman

S.J.O.

Hedison

T.M.

Hoeven

Greetham

G.M.

Towrie

Scrutton

N.S.

“Excited-State Charge Separation in the Photochemical Mechanism of the Light-Driven Enzyme Protochlorophyllide Oxidoreductase”. Angew. Chem. Int. Ed. Engl 2015; 54(5): 1512–1515.

10.

Laptenok

S.P.

Lukacs

Gil

Brust

Sazanovich

I.V.

Greetham

G.M.

Tonge

P.J.

Meech

S.R.

“Complete Proton Transfer Cycle in GFP and Its T203V and S205V Mutants”. Angew. Chem. Int. Ed. Engl 2015; 54(32): 9303–9307.

11.

Liu

Nees

Mourou

Biswal

Spuhler

G.J.

Keller

Kuleshov

N.V.

“Yb:KGd(WO₄)₂ Chirped-pulse Regenerative Amplifiers”. Opt. Commun 2002; 203(3–6): 315–321.

12.

Schnedermann

Liebel

Kukura

“Mode-Specificity of Vibrationally Coherent Internal Conversion in Rhodopsin during the Primary Visual Event”. J. Am. Chem. Soc 2015; 137(8): 2886–2891.

13.

Antipenkov

Varanavicius

Zaukevicius

Piskarskas

A.P.

“Femtosecond Yb:KGW MOPA Driven Broadband NOPA as a Frontend for TW Few-cycle Pulse Systems”. Opt. Express 2011; 19(4): 3519–3524.

14.

Bradler

Homann

Riedle

“Broadband Difference Frequency Mixing Between Visible and Near-infrared Pulses for Few-cycle Pulse Generation with Stable Carrier-envelope Phase”. Appl. Phys. B: Laser. Opt 2013; 113(1): 19–25.

15.

Bredenbeck

Helbing

Hamm

“Continuous Scanning from Picoseconds to Microseconds in Time Resolved Linear and Nonlinear Spectroscopy”. Rev. Sci. Instrum 2004; 75(11): 4462–4466.

16.

Greetham

G.M.

Burgos

Cao

Q.A.

Clark

I.P.

Codd

P.S.

Farrow

R.C.

George

M.W.

Kogimtzis

Matousek

Parker

A.W.

Pollard

M.R.

Robinson

D.A.

Xin

Z.J.

Towrie

“ULTRA: A Unique Instrument for Time-Resolved Spectroscopy”. Appl. Spectrosc 2010; 64(12): 1311–1319.

17.

Hanson-Heine

M.W.D.

Wriglesworth

Uroos

Calladine

J.A.

Murphy

T.S.

Hamilton

Clark

I.P.

Towrie

Dowden

Besley

N.A.

George

M.W.

“Calculating Singlet Excited States: Comparison with Fast Time-resolved Infrared Spectroscopy of Coumarins”. J. Chem. Phys 2015; 142(15): 154119.

18.

Rini

Holm

A.K.

Nibbering

E.T.J.

Fidder

“Ultrafast UV-mid-IR Investigation of the Ring Opening Reaction of a Photochromic Spiropyran”. J. Am. Chem. Soc 2003; 125(10): 3028–3034.

A 100 kHz Time-Resolved Multiple-Probe Femtosecond to Second Infrared Absorption Spectrometer

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