Radiative cooling of the deprotonated cyan fluorescent protein chromophore anion

James Flotte de Pouzols; Arun Subramani; Eleanor K. Ashworth; James N. Bull; Henrik Cederquist; Jordan Dezalay; Nanna Holmgaard List; Paul Martini; José E. Navarro Navarrete; Henning T. Schmidt; Henning Zettergren; Boxing Zhu; Mark H. Stockett

doi:10.1103/PhysRevA.111.043112

Radiative cooling of the deprotonated cyan fluorescent protein chromophore anion

James Flotte de Pouzols
, Arun Subramani
, Eleanor K. Ashworth
, James N. Bull
, Henrik Cederquist
, Jordan Dezalay
, Nanna Holmgaard List
, Paul Martini
, José E. Navarro Navarrete
, Henning T. Schmidt
, Henning Zettergren
, Boxing Zhu
, Mark H. Stockett

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

2 Citations (Scopus)

22 Downloads (Pure)

Abstract

An electrospray ion source has been coupled to a cryogenic electrostatic ion-beam storage ring to enable experimental studies of the fundamental properties of biomolecular ions and their reactions in the gas phase on longer timescales than with previous instruments. Using this equipment, we have measured the vibrational radiative cooling rate of the deprotonated anion of the chromophore of the cyan fluorescent protein, a color-shifted mutant of the iconic green fluorescent protein. Time-resolved dissociation rates of collisionally activated ions are first measured to benchmark a model of the dissociation rate coefficient. Storage time-dependent laser-induced dissociation rates are then measured to probe the evolution of the internal energy distribution of the stored ion ensemble. We find that significant heating of the electrosprayed ions occurs upon their extraction from the ion source, and that the radiative cooling rate is consistent with the prediction of a simple harmonic cascade model of vibrational relaxation.

Original language	English
Article number	043112
Journal	Physical Review A
Volume	111
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevA.111.043112
Publication status	Published - 18 Apr 2025

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Cite this

Flotte de Pouzols, J., Subramani, A., Ashworth, E. K., Bull, J. N., Cederquist, H., Dezalay, J., List, N. H., Martini, P., Navarrete, J. E. N., Schmidt, H. T., Zettergren, H., Zhu, B., & Stockett, M. H. (2025). Radiative cooling of the deprotonated cyan fluorescent protein chromophore anion. Physical Review A, 111(4), Article 043112. https://doi.org/10.1103/PhysRevA.111.043112

@article{e9b4ca721c2e4d0f8051a56a959e6fc9,

title = "Radiative cooling of the deprotonated cyan fluorescent protein chromophore anion",

abstract = "An electrospray ion source has been coupled to a cryogenic electrostatic ion-beam storage ring to enable experimental studies of the fundamental properties of biomolecular ions and their reactions in the gas phase on longer timescales than with previous instruments. Using this equipment, we have measured the vibrational radiative cooling rate of the deprotonated anion of the chromophore of the cyan fluorescent protein, a color-shifted mutant of the iconic green fluorescent protein. Time-resolved dissociation rates of collisionally activated ions are first measured to benchmark a model of the dissociation rate coefficient. Storage time-dependent laser-induced dissociation rates are then measured to probe the evolution of the internal energy distribution of the stored ion ensemble. We find that significant heating of the electrosprayed ions occurs upon their extraction from the ion source, and that the radiative cooling rate is consistent with the prediction of a simple harmonic cascade model of vibrational relaxation.",

author = "\{Flotte de Pouzols\}, James and Arun Subramani and Ashworth, \{Eleanor K.\} and Bull, \{James N.\} and Henrik Cederquist and Jordan Dezalay and List, \{Nanna Holmgaard\} and Paul Martini and Navarrete, \{Jos{\'e} E. Navarro\} and Schmidt, \{Henning T.\} and Henning Zettergren and Boxing Zhu and Stockett, \{Mark H.\}",

note = "Funding information: This work was supported by Swedish Research Council Grants No. 2016-03675 (M.H.S.), No. 2018-04092 (H.T.S.), No. 2023-03833 (H.C.), No. 2020-03437 (H.Z.), Knut and Alice Wallenberg Foundation Grant No. 2018.0028 (H.C., H.T.S., and H.Z.), EPSRC Grant No. EP/W018691 (J.N.B.), Olle Engkvist Foundation Grant No. 200-575 (M.H.S.), and Swedish Foundation for International Collaboration in Research and Higher Education (STINT) Grant No. PT2017-7328 (J.N.B. and M.H.S.). We acknowledge the DESIREE infrastructure for the provision of facilities and experimental support, and we thank the operators and technical staff for their invaluable assistance. The DESIREE infrastructure receives funding from the Swedish Research Council under Grants No. 2021-00155 and No. 2023-00170. This article is based upon work from COST Action CA21126–Carbon molecular nanostructures in space (NanoSpace), supported by COST (European Cooperation in Science and Technology).",

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doi = "10.1103/PhysRevA.111.043112",

language = "English",

volume = "111",

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T1 - Radiative cooling of the deprotonated cyan fluorescent protein chromophore anion

AU - Flotte de Pouzols, James

AU - Subramani, Arun

AU - Ashworth, Eleanor K.

AU - Bull, James N.

AU - Cederquist, Henrik

AU - Dezalay, Jordan

AU - List, Nanna Holmgaard

AU - Martini, Paul

AU - Navarrete, José E. Navarro

AU - Schmidt, Henning T.

AU - Zettergren, Henning

AU - Zhu, Boxing

AU - Stockett, Mark H.

N1 - Funding information: This work was supported by Swedish Research Council Grants No. 2016-03675 (M.H.S.), No. 2018-04092 (H.T.S.), No. 2023-03833 (H.C.), No. 2020-03437 (H.Z.), Knut and Alice Wallenberg Foundation Grant No. 2018.0028 (H.C., H.T.S., and H.Z.), EPSRC Grant No. EP/W018691 (J.N.B.), Olle Engkvist Foundation Grant No. 200-575 (M.H.S.), and Swedish Foundation for International Collaboration in Research and Higher Education (STINT) Grant No. PT2017-7328 (J.N.B. and M.H.S.). We acknowledge the DESIREE infrastructure for the provision of facilities and experimental support, and we thank the operators and technical staff for their invaluable assistance. The DESIREE infrastructure receives funding from the Swedish Research Council under Grants No. 2021-00155 and No. 2023-00170. This article is based upon work from COST Action CA21126–Carbon molecular nanostructures in space (NanoSpace), supported by COST (European Cooperation in Science and Technology).

PY - 2025/4/18

Y1 - 2025/4/18

N2 - An electrospray ion source has been coupled to a cryogenic electrostatic ion-beam storage ring to enable experimental studies of the fundamental properties of biomolecular ions and their reactions in the gas phase on longer timescales than with previous instruments. Using this equipment, we have measured the vibrational radiative cooling rate of the deprotonated anion of the chromophore of the cyan fluorescent protein, a color-shifted mutant of the iconic green fluorescent protein. Time-resolved dissociation rates of collisionally activated ions are first measured to benchmark a model of the dissociation rate coefficient. Storage time-dependent laser-induced dissociation rates are then measured to probe the evolution of the internal energy distribution of the stored ion ensemble. We find that significant heating of the electrosprayed ions occurs upon their extraction from the ion source, and that the radiative cooling rate is consistent with the prediction of a simple harmonic cascade model of vibrational relaxation.

AB - An electrospray ion source has been coupled to a cryogenic electrostatic ion-beam storage ring to enable experimental studies of the fundamental properties of biomolecular ions and their reactions in the gas phase on longer timescales than with previous instruments. Using this equipment, we have measured the vibrational radiative cooling rate of the deprotonated anion of the chromophore of the cyan fluorescent protein, a color-shifted mutant of the iconic green fluorescent protein. Time-resolved dissociation rates of collisionally activated ions are first measured to benchmark a model of the dissociation rate coefficient. Storage time-dependent laser-induced dissociation rates are then measured to probe the evolution of the internal energy distribution of the stored ion ensemble. We find that significant heating of the electrosprayed ions occurs upon their extraction from the ion source, and that the radiative cooling rate is consistent with the prediction of a simple harmonic cascade model of vibrational relaxation.

U2 - 10.1103/PhysRevA.111.043112

DO - 10.1103/PhysRevA.111.043112

M3 - Article

SN - 1050-2947

VL - 111

JO - Physical Review A

JF - Physical Review A

IS - 4

M1 - 043112

ER -