Raman Diffusion-Ordered Spectroscopy

Robert W. Schmidt; Giulia Giubertoni; Federico Caporaletti; Paul Kolpakov; Noushine Shahidzadeh; Freek Ariese; Sander Woutersen

doi:10.1021/acs.jpca.3c03232

Raman Diffusion-Ordered Spectroscopy

Robert W. Schmidt, Giulia Giubertoni^*, Federico Caporaletti, Paul Kolpakov, Noushine Shahidzadeh, Freek Ariese, Sander Woutersen^*

^*Corresponding author for this work

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

Abstract

The Stokes-Einstein relation, which relates the diffusion coefficient of a molecule to its hydrodynamic radius, is commonly used to determine molecular sizes in chemical analysis methods. Here, we combine the size sensitivity of such diffusion-based methods with the structure sensitivity of Raman spectroscopy by performing Raman diffusion-ordered spectroscopy (Raman-DOSY). The core of the Raman-DOSY setup is a flow cell with a Y-shaped channel containing two inlets: one for the sample solution and one for the pure solvent. The two liquids are injected at the same flow rate, giving rise to two parallel laminar flows in the channel. After the flow stops, the solute molecules diffuse from the solution-filled half of the channel into the solvent-filled half at a rate determined by their hydrodynamic radius. The arrival of the solute molecules in the solvent-filled half of the channel is recorded in a spectrally resolved manner by Raman microspectroscopy. From the time series of Raman spectra, a two-dimensional Raman-DOSY spectrum is obtained, which has the Raman frequency on one axis and the diffusion coefficient (or equivalently, hydrodynamic radius) on the other. In this way, Raman-DOSY spectrally resolves overlapping Raman peaks arising from molecules of different sizes. We demonstrate Raman-DOSY on samples containing up to three compounds and derive the diffusion coefficients of small molecules, proteins, and supramolecules (micelles), illustrating the versatility of Raman-DOSY. Raman-DOSY is label-free and does not require deuterated solvents and can thus be applied to samples and matrices that might be difficult to investigate with other diffusion-based spectroscopy methods.

Original language	English
Pages (from-to)	7638-7645
Number of pages	8
Journal	The Journal of Physical Chemistry A
Volume	127
Issue number	36
Early online date	1 Sept 2023
DOIs	https://doi.org/10.1021/acs.jpca.3c03232
Publication status	Published - 14 Sept 2023

Bibliographical note

Funding Information:
The authors thank the Vrije Universiteit Amsterdam HPC Counsel for access to the BAZIS Computer Cluster. This research received funding from The Netherlands Organization for Scientific Research (NWO) in the framework of the ENW PPP Fund for the top sectors (Grant 741.018.202 “Soft Advanced Materials”) and from the Ministry of Economic Affairs in the framework of the “PPS-Toeslagregeling”. FC is a chargé de recherches of the Fonds de la Recherche Scientifique (FNRS). GG is supported by the Netherlands Organization for Scientific Research (NWO) under project number VI.Veni.212.240.

Publisher Copyright:
© 2023 The Authors. Published by American Chemical Society

Funding

The authors thank the Vrije Universiteit Amsterdam HPC Counsel for access to the BAZIS Computer Cluster. This research received funding from The Netherlands Organization for Scientific Research (NWO) in the framework of the ENW PPP Fund for the top sectors (Grant 741.018.202 “Soft Advanced Materials”) and from the Ministry of Economic Affairs in the framework of the “PPS-Toeslagregeling”. FC is a chargé de recherches of the Fonds de la Recherche Scientifique (FNRS). GG is supported by the Netherlands Organization for Scientific Research (NWO) under project number VI.Veni.212.240.

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title = "Raman Diffusion-Ordered Spectroscopy",

abstract = "The Stokes-Einstein relation, which relates the diffusion coefficient of a molecule to its hydrodynamic radius, is commonly used to determine molecular sizes in chemical analysis methods. Here, we combine the size sensitivity of such diffusion-based methods with the structure sensitivity of Raman spectroscopy by performing Raman diffusion-ordered spectroscopy (Raman-DOSY). The core of the Raman-DOSY setup is a flow cell with a Y-shaped channel containing two inlets: one for the sample solution and one for the pure solvent. The two liquids are injected at the same flow rate, giving rise to two parallel laminar flows in the channel. After the flow stops, the solute molecules diffuse from the solution-filled half of the channel into the solvent-filled half at a rate determined by their hydrodynamic radius. The arrival of the solute molecules in the solvent-filled half of the channel is recorded in a spectrally resolved manner by Raman microspectroscopy. From the time series of Raman spectra, a two-dimensional Raman-DOSY spectrum is obtained, which has the Raman frequency on one axis and the diffusion coefficient (or equivalently, hydrodynamic radius) on the other. In this way, Raman-DOSY spectrally resolves overlapping Raman peaks arising from molecules of different sizes. We demonstrate Raman-DOSY on samples containing up to three compounds and derive the diffusion coefficients of small molecules, proteins, and supramolecules (micelles), illustrating the versatility of Raman-DOSY. Raman-DOSY is label-free and does not require deuterated solvents and can thus be applied to samples and matrices that might be difficult to investigate with other diffusion-based spectroscopy methods.",

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note = "Funding Information: The authors thank the Vrije Universiteit Amsterdam HPC Counsel for access to the BAZIS Computer Cluster. This research received funding from The Netherlands Organization for Scientific Research (NWO) in the framework of the ENW PPP Fund for the top sectors (Grant 741.018.202 “Soft Advanced Materials”) and from the Ministry of Economic Affairs in the framework of the “PPS-Toeslagregeling”. FC is a charg{\'e} de recherches of the Fonds de la Recherche Scientifique (FNRS). GG is supported by the Netherlands Organization for Scientific Research (NWO) under project number VI.Veni.212.240. Publisher Copyright: {\textcopyright} 2023 The Authors. Published by American Chemical Society",

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doi = "10.1021/acs.jpca.3c03232",

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AU - Schmidt, Robert W.

AU - Giubertoni, Giulia

AU - Caporaletti, Federico

AU - Kolpakov, Paul

AU - Shahidzadeh, Noushine

AU - Ariese, Freek

AU - Woutersen, Sander

N1 - Funding Information: The authors thank the Vrije Universiteit Amsterdam HPC Counsel for access to the BAZIS Computer Cluster. This research received funding from The Netherlands Organization for Scientific Research (NWO) in the framework of the ENW PPP Fund for the top sectors (Grant 741.018.202 “Soft Advanced Materials”) and from the Ministry of Economic Affairs in the framework of the “PPS-Toeslagregeling”. FC is a chargé de recherches of the Fonds de la Recherche Scientifique (FNRS). GG is supported by the Netherlands Organization for Scientific Research (NWO) under project number VI.Veni.212.240. Publisher Copyright: © 2023 The Authors. Published by American Chemical Society

PY - 2023/9/14

Y1 - 2023/9/14

N2 - The Stokes-Einstein relation, which relates the diffusion coefficient of a molecule to its hydrodynamic radius, is commonly used to determine molecular sizes in chemical analysis methods. Here, we combine the size sensitivity of such diffusion-based methods with the structure sensitivity of Raman spectroscopy by performing Raman diffusion-ordered spectroscopy (Raman-DOSY). The core of the Raman-DOSY setup is a flow cell with a Y-shaped channel containing two inlets: one for the sample solution and one for the pure solvent. The two liquids are injected at the same flow rate, giving rise to two parallel laminar flows in the channel. After the flow stops, the solute molecules diffuse from the solution-filled half of the channel into the solvent-filled half at a rate determined by their hydrodynamic radius. The arrival of the solute molecules in the solvent-filled half of the channel is recorded in a spectrally resolved manner by Raman microspectroscopy. From the time series of Raman spectra, a two-dimensional Raman-DOSY spectrum is obtained, which has the Raman frequency on one axis and the diffusion coefficient (or equivalently, hydrodynamic radius) on the other. In this way, Raman-DOSY spectrally resolves overlapping Raman peaks arising from molecules of different sizes. We demonstrate Raman-DOSY on samples containing up to three compounds and derive the diffusion coefficients of small molecules, proteins, and supramolecules (micelles), illustrating the versatility of Raman-DOSY. Raman-DOSY is label-free and does not require deuterated solvents and can thus be applied to samples and matrices that might be difficult to investigate with other diffusion-based spectroscopy methods.

AB - The Stokes-Einstein relation, which relates the diffusion coefficient of a molecule to its hydrodynamic radius, is commonly used to determine molecular sizes in chemical analysis methods. Here, we combine the size sensitivity of such diffusion-based methods with the structure sensitivity of Raman spectroscopy by performing Raman diffusion-ordered spectroscopy (Raman-DOSY). The core of the Raman-DOSY setup is a flow cell with a Y-shaped channel containing two inlets: one for the sample solution and one for the pure solvent. The two liquids are injected at the same flow rate, giving rise to two parallel laminar flows in the channel. After the flow stops, the solute molecules diffuse from the solution-filled half of the channel into the solvent-filled half at a rate determined by their hydrodynamic radius. The arrival of the solute molecules in the solvent-filled half of the channel is recorded in a spectrally resolved manner by Raman microspectroscopy. From the time series of Raman spectra, a two-dimensional Raman-DOSY spectrum is obtained, which has the Raman frequency on one axis and the diffusion coefficient (or equivalently, hydrodynamic radius) on the other. In this way, Raman-DOSY spectrally resolves overlapping Raman peaks arising from molecules of different sizes. We demonstrate Raman-DOSY on samples containing up to three compounds and derive the diffusion coefficients of small molecules, proteins, and supramolecules (micelles), illustrating the versatility of Raman-DOSY. Raman-DOSY is label-free and does not require deuterated solvents and can thus be applied to samples and matrices that might be difficult to investigate with other diffusion-based spectroscopy methods.

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JO - The Journal of Physical Chemistry A

JF - The Journal of Physical Chemistry A

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ER -

Raman Diffusion-Ordered Spectroscopy

Abstract

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