Quantitative Raman spectroelectrochemistry using silver screen-printed electrodes

Martín‐Yerga, Daniel; Pérez-Junquera, Alejandro; González‐García, María Begoña; Perales-Rondón, Juan V.; Heras, Aránzazu; Colina, Álvaro; Hernández‐Santos, David; Fanjul‐Bolado, Pablo

doi:10.1016/j.electacta.2018.01.060

Cited by 61 publications

(58 citation statements)

References 57 publications

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“…It must be noted that a confocal micro‐Raman is not always needed. In fact, the use of low‐resolution Raman spectrometers has demonstrated to be suitable in the study of different interfacial systems . Thus, the use of low‐resolution Raman spectrometers coupled with Raman probes with a relatively low magnification allows us to sample non‐perfect flat surfaces.…”

Section: Spectroelectrochemistrymentioning

confidence: 99%

“…Thus, the use of low‐resolution Raman spectrometers coupled with Raman probes with a relatively low magnification allows us to sample non‐perfect flat surfaces. Moreover, measurements can be performed without a flat optical window, ensuring a good focus of the laser beam and obtaining good results, with the experiment being performed just in a few‐microliters solution drop . New Raman‐SEC instruments, Figure , are similar in size with the UV/VIS‐SEC equipment shown in Figure .…”

Section: Spectroelectrochemistrymentioning

confidence: 99%

“…In fact, the use of low-resolution Raman spectrometers has demonstrated to be suitable in the study of different interfacial systems. [73][74][75] Thus, the use of lowresolution Raman spectrometers coupled with Raman probes with a relatively low magnification allows us to sample nonperfect flat surfaces. Moreover, measurements can be performed without a flat optical window, ensuring a good focus of the laser beam and obtaining good results, with the experiment being performed just in a few-microliters solution drop.…”

Section: Raman-sec Optical Configurations and Cellsmentioning

confidence: 99%

“…Moreover, measurements can be performed without a flat optical window, ensuring a good focus of the laser beam and obtaining good results, with the experiment being performed just in a few-microliters solution drop. [73][74][75] New Raman-SEC instruments, Figure 7, are similar in size with the UV/VIS-SEC equipment shown in Figure 6. Additionally, Raman-SEC cells can be simplified by using Raman probes, with the type of experimental setup being comparable to the setups used for PL-SEC.…”

Section: Raman-sec Optical Configurations and Cellsmentioning

confidence: 99%

“…Picture of the instrumentation employed for Raman spectroelectrochemistry with screen-printed electrodes. Reprinted from Ref [74]…”

mentioning

confidence: 99%

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Spectroelectrochemistry of Quantum Dots

Garoz‐Ruiz

Perales-Rondón

Heras

et al. 2019

Israel Journal of Chemistry

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Spectroelectrochemistry (SEC) is a set of techniques with many advantages in the study and characterization of materials. Although SEC has not yet been widely used to study quantum dots (QDs), the information extracted from SEC experiments about these nanostructures is very useful. Most of the works that use SEC to study QDs are high‐quality pieces of research. This review intends to show how to perform SEC in an easy way and what information can be obtained using these techniques. Most of the examples shown in this review are related to semiconductor and carbon QDs. After a brief introduction, some optoelectronic properties of QDs and the main SEC techniques are described. The capabilities of SEC for the study of QDs are illustrated with examples extracted from literature. Finally, the needs of SEC to become a user‐friendly technique and its evolution to become more powerful are commented in the last section of the review.

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Section: Spectroelectrochemistrymentioning

confidence: 99%

Section: Spectroelectrochemistrymentioning

confidence: 99%

Section: Raman-sec Optical Configurations and Cellsmentioning

confidence: 99%

Section: Raman-sec Optical Configurations and Cellsmentioning

confidence: 99%

“…Picture of the instrumentation employed for Raman spectroelectrochemistry with screen-printed electrodes. Reprinted from Ref [74]…”

mentioning

confidence: 99%

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Spectroelectrochemistry of Quantum Dots

Garoz‐Ruiz

Perales-Rondón

Heras

et al. 2019

Israel Journal of Chemistry

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University experiments on the absorption spectroelectrochemistry and the surface‐enhanced Raman effect of methylviogen on a gold electrode

Habekost

2022

Chemkon

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Redoxreaktionen auf Goldsiebdruckelektroden (SPE) können elektrochemisch mit zyklischer Voltammetrie (Cyclovoltammetrie, CV) und spektroskopisch mit der optischen und der Ramanspektroskopie gemessen werden. Die Kombination aus CV und optischer oder Raman Spektroskopie, die sog. Absorpto‐ oder Ramanvoltammetrie, bietet neben elektrochemischen Informationen über Redoxreaktionen an Elektroden auch Informationen über die Änderung der optischen und Schwingungseigenschaften der beteiligten Stoffe. Der didaktische Hintergrund der Arbeit ist die Hypothese, dass die Kombination der beiden unterschiedlichen Gebiete der physikalischen Chemie dazu beitragen kann, Elektrodenreaktionen besser zu verstehen. Die Ramanspektroskopie ist eine leistungsfähige Technik zum Nachweis von sehr geringen Konzentrationen des Analyten auf Elektroden (im Bereich von Picomol), wenn diese durch elektrochemische Maßnahmen oder durch Verwendung von entsprechenden Nanoteilchen modifiziert werden. Eine einfache elektrochemische in‐situ Modifikation führt zum oberflächenverstärkten Ramaneffekt (EC‐SERS). Damit können chemische Reaktionen anhand der Änderung von Schwingungszuständen charakterisiert werden, ohne die manchmal langwierige Herstellung von Metall‐Nanopartikeln als Substrat für SERS.

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In situ Activation of Thick‐film Disposable Copper Electrodes for Sensitive Detection of Malachite Green Using Electrochemical Surface‐enhanced Raman Scattering (EC‐SERS)

et al. 2018

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In this work, disposable thick‐film copper electrodes were used for the detection of malachite green by Electrochemical Surface‐Enhanced Raman Spectroscopy (EC‐SERS). In situ real‐time SERS detection of malachite green was performed during the activation of copper electrodes by voltammetry. This time‐resolved method allowed to find dynamically the optimal potential where the detection sensitivity is increased. Scanning electron microscopy images showed that the generation of new fresh copper nanoparticles are responsible to produce the SERS enhancement. A fast decrease of the SERS signal was observed when the potential was shifted from the optimal potential, which could be due to surface changes on the copper electrode. This fact demonstrates the importance of recording the SERS signal in situ and dynamically to obtain the most sensitive method. The combination of in situ time‐resolved EC‐SERS with disposable, cost‐effective screen‐printed electrodes leads to a very appropriate method for the sensitive and fast detection of malachite green.

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Quantitative Raman spectroelectrochemistry using silver screen-printed electrodes

Cited by 61 publications

References 57 publications

Spectroelectrochemistry of Quantum Dots

Spectroelectrochemistry of Quantum Dots

University experiments on the absorption spectroelectrochemistry and the surface‐enhanced Raman effect of methylviogen on a gold electrode

In situ Activation of Thick‐film Disposable Copper Electrodes for Sensitive Detection of Malachite Green Using Electrochemical Surface‐enhanced Raman Scattering (EC‐SERS)

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