Quartz crystal microbalance with dissipation monitoring
February 15, 2024
Within surface science, a quartz crystal microbalance with dissipation monitoring (QCM-D) is a type of quartz crystal microbalance (QCM) based on the ring-down technique. It is used in interfacial acoustic sensing. Its most common application is the determination of a film thickness in a liquid environment (such as the thickness of an adsorbed protein layer). It can be used to investigate further properties of the sample, most notably the layer's softness.
Methodedit
Ring-down as a method to interrogate acoustic resonators was established in 1954.[1] In the context of the QCM, it was described by Hirao et al.[2] and Rodahl et al.[3] The active component of a QCM is a thin quartz crystal disk sandwiched between a pair of electrodes.[4] The application of an AC voltage over the electrodes causes the crystal to oscillate at its acoustic resonance frequency. When the AC voltage is turned off, the oscillation decays exponentially ("rings down"). This decay is recorded and the resonance frequency (f) and the energy dissipation factor (D) are extracted. D is defined as the loss of energy per oscillation period divided by the total energy stored in the system. D is equal to the resonance bandwidth divided by the resonance frequency. Other QCM instruments determine the bandwidth from the conductance spectra. Being a QCM, the QCM-D works in real-time, does not need labeling, and is surface-sensitive. Current QCM-D equipment enables measuring of more than 200 data points per second.
Changes in the resonance frequency (Δf) are primarily related to mass uptake or release at the sensor surface. When employed as a mass sensor, the instrument has a sensitivity of about 0.5 ng/cm2 according to the manufacturer. Changes in the dissipation factor (ΔD) are primarily related to the viscoelasticity (softness).[5] The softness, in turn, often is related to structural changes of the film adhering at the sensor surface.
Mass sensoredit
When operated as a mass sensor, the QCM-D is often used to study molecular adsorption/desorption and binding kinetics to various types of surfaces. In contrast to optical techniques such as surface plasmon resonance (SPR) spectroscopy, ellipsometry, or dual polarisation interferometry, the QCM determines the mass of the adsorbed film including trapped solvent. Comparison of the "acoustic thickness" as determined with the QCM and the "optical thickness" as determined by any of the optical techniques therefore allows to estimate the degree of swelling of the film in the ambient liquid.[6] The difference in dry and wet mass measured by QCM-D and MP-SPR is more significant in highly hydrated layers as can be seen in.[7][8][9]
Since the softness of the sample is affected by a large variety of parameters, the QCM-D is useful for studying molecular interactions with surfaces as well as interactions between molecules. The QCM-D is commonly used in the fields of biomaterials, cell adhesion, drug discovery, materials science, and biophysics. Other typical applications are characterizing viscoelastic films, conformational changes of deposited macromolecules, build-up of polyelectrolyte multilayers, and degradation or corrosion of films and coatings.
Referencesedit
^Sittel, Karl; Rouse, II, Prince E.; Bailey, Emerson D. (1954). "Method for Determining the Viscoelastic Properties of Dilute Polymer Solutions at Audio-Frequencies". Journal of Applied Physics. 25 (10): 1312–1320. Bibcode:1954JAP....25.1312S. doi:10.1063/1.1721552.
^Hirao, Masahiko; Ogi, Hirotsugu; Fukuoka, Hidekazu (1993). "Resonance Emat system for acoustoelastic stress measurement in sheet metals". Review of Scientific Instruments. 64 (11): 3198–3205. Bibcode:1993RScI...64.3198H. doi:10.1063/1.1144328. hdl:11094/3191.
^Rodahl, Michael; Kasemo, Bengt Herbert (1998-06-04) [May 1996]. "A simple setup to simultaneously measure the resonant frequency and the absolute dissipation factor of a quartz crystal microbalance". Review of Scientific Instruments. 67 (9): 3238–3241. Bibcode:1996RScI...67.3238R. doi:10.1063/1.1147494.
^Johannsmann, Diethelm (2007). "Studies of Viscoelasticity with the QCM". In Steinem, Claudia; Janshoff, Andreas (eds.). Piezoelectric Sensors. Springer Series on Chemical Sensors and Biosensors. Vol. 5. Berlin / Heidelberg: Springer-Verlag (published 2006-09-08). pp. 49–109. doi:10.1007/5346_024. ISBN978-3-540-36567-9. ISSN 1612-7617.
^Johannsmann, Diethelm (2008). "Viscoelastic, mechanical, and dielectric measurements on complex samples with the quartz crystal microbalance". Physical Chemistry Chemical Physics. 10 (31): 4516–4534. Bibcode:2008PCCP...10.4516J. doi:10.1039/b803960g. PMID 18665301.
^Plunkett, Mark A.; Wang, Zhehui; Rutland, Mark W.; Johannsmann, Diethelm (2003). "Adsorption of pNIPAM layers on hydrophobic gold surfaces, measured in situ by QCM and SPR". Langmuir. 19 (17): 6837–6844. doi:10.1021/la034281a.
^Vuoriluoto, Maija; Orelma, Hannes; Johansson, Leena-Sisko; Zhu, Baolei; Poutanen, Mikko; Walther, Andreas; Laine, Janne; Rojas, Orlando J. (10 December 2015). "Effect of Molecular Architecture of PDMAEMA–POEGMA Random and Block Copolymers on Their Adsorption on Regenerated and Anionic Nanocelluloses and Evidence of Interfacial Water Expulsion". The Journal of Physical Chemistry B. 119 (49): 15275–15286. doi:10.1021/acs.jpcb.5b07628. PMID 26560798.
^Mohan, Tamilselvan; Niegelhell, Katrin; Zarth, Cíntia Salomão Pinto; Kargl, Rupert; Köstler, Stefan; Ribitsch, Volker; Heinze, Thomas; Spirk, Stefan; Stana-Kleinschek, Karin (10 November 2014). "Triggering Protein Adsorption on Tailored Cationic Cellulose Surfaces". Biomacromolecules. 15 (11): 3931–3941. doi:10.1021/bm500997s. PMID 25233035.
^Emilsson, Gustav; Schoch, Rafael L.; Feuz, Laurent; Höök, Fredrik; Lim, Roderick Y. H.; Dahlin, Andreas B. (15 April 2015). "Strongly Stretched Protein Resistant Poly(ethylene glycol) Brushes Prepared by Grafting-To". ACS Applied Materials & Interfaces. 7 (14): 7505–7515. doi:10.1021/acsami.5b01590. PMID 25812004.
February 15, 2024
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Within surface science a quartz crystal microbalance with dissipation monitoring QCM D is a type of quartz crystal microbalance QCM based on the ring down technique It is used in interfacial acoustic sensing Its most common application is the determination of a film thickness in a liquid environment such as the thickness of an adsorbed protein layer It can be used to investigate further properties of the sample most notably the layer s softness Method editRing down as a method to interrogate acoustic resonators was established in 1954 1 In the context of the QCM it was described by Hirao et al 2 and Rodahl et al 3 The active component of a QCM is a thin quartz crystal disk sandwiched between a pair of electrodes 4 The application of an AC voltage over the electrodes causes the crystal to oscillate at its acoustic resonance frequency When the AC voltage is turned off the oscillation decays exponentially rings down This decay is recorded and the resonance frequency f and the energy dissipation factor D are extracted D is defined as the loss of energy per oscillation period divided by the total energy stored in the system D is equal to the resonance bandwidth divided by the resonance frequency Other QCM instruments determine the bandwidth from the conductance spectra Being a QCM the QCM D works in real time does not need labeling and is surface sensitive Current QCM D equipment enables measuring of more than 200 data points per second Changes in the resonance frequency Df are primarily related to mass uptake or release at the sensor surface When employed as a mass sensor the instrument has a sensitivity of about 0 5 ng cm2 according to the manufacturer Changes in the dissipation factor DD are primarily related to the viscoelasticity softness 5 The softness in turn often is related to structural changes of the film adhering at the sensor surface Mass sensor editWhen operated as a mass sensor the QCM D is often used to study molecular adsorption desorption and binding kinetics to various types of surfaces In contrast to optical techniques such as surface plasmon resonance SPR spectroscopy ellipsometry or dual polarisation interferometry the QCM determines the mass of the adsorbed film including trapped solvent Comparison of the acoustic thickness as determined with the QCM and the optical thickness as determined by any of the optical techniques therefore allows to estimate the degree of swelling of the film in the ambient liquid 6 The difference in dry and wet mass measured by QCM D and MP SPR is more significant in highly hydrated layers as can be seen in 7 8 9 Since the softness of the sample is affected by a large variety of parameters the QCM D is useful for studying molecular interactions with surfaces as well as interactions between molecules The QCM D is commonly used in the fields of biomaterials cell adhesion drug discovery materials science and biophysics Other typical applications are characterizing viscoelastic films conformational changes of deposited macromolecules build up of polyelectrolyte multilayers and degradation or corrosion of films and coatings References edit Sittel Karl Rouse II Prince E Bailey Emerson D 1954 Method for Determining the Viscoelastic Properties of Dilute Polymer Solutions at Audio Frequencies Journal of Applied Physics 25 10 1312 1320 Bibcode 1954JAP 25 1312S doi 10 1063 1 1721552 Hirao Masahiko Ogi Hirotsugu Fukuoka Hidekazu 1993 Resonance Emat system for acoustoelastic stress measurement in sheet metals Review of Scientific Instruments 64 11 3198 3205 Bibcode 1993RScI 64 3198H doi 10 1063 1 1144328 hdl 11094 3191 Rodahl Michael Kasemo Bengt Herbert 1998 06 04 May 1996 A simple setup to simultaneously measure the resonant frequency and the absolute dissipation factor of a quartz crystal microbalance Review of Scientific Instruments 67 9 3238 3241 Bibcode 1996RScI 67 3238R doi 10 1063 1 1147494 Johannsmann Diethelm 2007 Studies of Viscoelasticity with the QCM In Steinem Claudia Janshoff Andreas eds Piezoelectric Sensors Springer Series on Chemical Sensors and Biosensors Vol 5 Berlin Heidelberg Springer Verlag published 2006 09 08 pp 49 109 doi 10 1007 5346 024 ISBN 978 3 540 36567 9 ISSN 1612 7617 Johannsmann Diethelm 2008 Viscoelastic mechanical and dielectric measurements on complex samples with the quartz crystal microbalance Physical Chemistry Chemical Physics 10 31 4516 4534 Bibcode 2008PCCP 10 4516J doi 10 1039 b803960g PMID 18665301 Plunkett Mark A Wang Zhehui Rutland Mark W Johannsmann Diethelm 2003 Adsorption of pNIPAM layers on hydrophobic gold surfaces measured in situ by QCM and SPR Langmuir 19 17 6837 6844 doi 10 1021 la034281a Vuoriluoto Maija Orelma Hannes Johansson Leena Sisko Zhu Baolei Poutanen Mikko Walther Andreas Laine Janne Rojas Orlando J 10 December 2015 Effect of Molecular Architecture of PDMAEMA POEGMA Random and Block Copolymers on Their Adsorption on Regenerated and Anionic Nanocelluloses and Evidence of Interfacial Water Expulsion The Journal of Physical Chemistry B 119 49 15275 15286 doi 10 1021 acs jpcb 5b07628 PMID 26560798 Mohan Tamilselvan Niegelhell Katrin Zarth Cintia Salomao Pinto Kargl Rupert Kostler Stefan Ribitsch Volker Heinze Thomas Spirk Stefan Stana Kleinschek Karin 10 November 2014 Triggering Protein Adsorption on Tailored Cationic Cellulose Surfaces Biomacromolecules 15 11 3931 3941 doi 10 1021 bm500997s PMID 25233035 Emilsson Gustav Schoch Rafael L Feuz Laurent Hook Fredrik Lim Roderick Y H Dahlin Andreas B 15 April 2015 Strongly Stretched Protein Resistant Poly ethylene glycol Brushes Prepared by Grafting To ACS Applied Materials amp Interfaces 7 14 7505 7515 doi 10 1021 acsami 5b01590 PMID 25812004 Retrieved from https en wikipedia org w index php title Quartz crystal microbalance with dissipation monitoring amp oldid 1173561974, wikipedia, wiki, book, books, library,
