C. B. Collins scite author profile

This feature article reviews the thermal dissipation of nanoscopic gold under radiofrequency (RF) irradiation. It also presents previously unpublished data addressing obscure aspects of this phenomenon. While applications in biology motivated initial investigation of RF heating of gold nanoparticles, recent controversy concerning whether thermal effects can be attributed to nanoscopic gold highlight the need to understand the involved mechanism or mechanisms of heating. Both the nature of the particle and the nature of the RF field influence heating. Aspects of nanoparticle chemistry and physics, including the hydrodynamic diameter of the particle, the oxidation state and related magnetism of the core, and the chemical nature of the ligand shell may all strongly influence to what extent a nanoparticle heats in an RF field. Aspects of RF include: power, frequency and antenna designs that emphasize relative strength of magnetic or electric fields, and also influence the extent to which a gold nanoparticle heats in RF. These nanoparticle and RF properties are analysed in the context of three heating mechanisms proposed to explain gold nanoparticle heating in an RF field. This article also makes a critical analysis of the existing literature in the context of the nanoparticle preparations, RF structure, and suggested mechanisms in previously reported experiments.

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Electrophoretic Mechanism of Au₂₅(SR)₁₈ Heating in Radiofrequency Fields

Collins

Tofanelli

Noblitt

et al. 2018

J. Phys. Chem. Lett.

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Gold nanoparticles in radiofrequency (RF) fields have been observed to heat. There is some debate over the mechanism of heating. Au(SR) in RF is studied for the mechanistic insights obtainable from precise synthetic control over exact charge, size, and spin for this nanoparticle. An electrophoretic mechanism can adequately account for the observed heat. This study adds a new level of understanding to gold particle heating experiments, allowing for the first time a conclusive connection between theoretical and experimentally observed heating rates.

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Practical stability of Au₂₅(SR)₁₈^−1/0/+1

et al. 2017

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Superatom electron shell and/or geometric shell filling underlies the thermodynamic stability of coinage and alkali metal clusters in both theoretical and experimental results. Factors beyond simple shell filling contribute substantially to the lifetime of ligated clusters in solution. Such factors include the nature of the solvent, the atmosphere and the steric size of the ligand shell. Here we systematically lay out a ‘practical’ stability model for ligated metal clusters, which includes both shell-closing aspects and colloidal stability aspects. Cluster decomposition may follow either fusion or fission pathways. Solvent polarity can be determinative of the decomposition pathway.

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Radiofrequency remote control of thermolysin activity

Collins

Riskowski

Ackerson

2021

Sci Rep

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The majority of biological processes are regulated by enzymes, precise control over specific enzymes could create the potential for controlling cellular processes remotely. We show that the thermophilic enzyme thermolysin can be remotely activated in 17.76 MHz radiofrequency (RF) fields when covalently attached to 6.1 nm gold coated magnetite nanoparticles. Without raising the bulk solution temperature, we observe enzyme activity as if the solution was 16 ± 2 °C warmer in RF fields—an increase in enzymatic rate of 129 ± 8%. Kinetics studies show that the activity increase of the enzyme is consistent with the induced fit of a hot enzyme with cold substrate.

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C. B. Collins

Radiofrequency heating pathways for gold nanoparticles

Electrophoretic Mechanism of Au₂₅(SR)₁₈ Heating in Radiofrequency Fields

Practical stability of Au₂₅(SR)₁₈^−1/0/+1

Radiofrequency remote control of thermolysin activity

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C. B. Collins

Radiofrequency heating pathways for gold nanoparticles

Electrophoretic Mechanism of Au25(SR)18 Heating in Radiofrequency Fields

Practical stability of Au25(SR)18−1/0/+1

Radiofrequency remote control of thermolysin activity

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Electrophoretic Mechanism of Au₂₅(SR)₁₈ Heating in Radiofrequency Fields

Practical stability of Au₂₅(SR)₁₈^−1/0/+1