Abstract:Signal intensity fluctuations are a ubiquitous characteristic of single-molecule surface-enhanced Raman scattering (SERS). In this work, we observed SERS intensity fluctuations (SIFs) from single nanoparticles fully coated with an adsorbate layer. Fluctuations from dry, fully coated nanoparticles are assigned to a dynamic molecule/metal environment wherein atomic-scale reconstructions support SERS. Using super resolution imaging techniques, we were able to pinpoint the positions of the fluctuations with subpar… Show more
“…Strong SERS intensity fluctuations (SIFs) have been reported for single metallic nanoparticles fully coated by a molecular probe. 18,19 Figure 1 presents similar observations from a common SERS substrate consisting of spherical silver nanoparticles deposited on a gold surface (System 1). Figure 1.High-speed SERS with Ag nanoparticle clusters on Au film.…”
Section: Resultsmentioning
confidence: 55%
“…The typical maximum acquisition rate for these systems is one spectrum every ∼100 ms (10 Hz) and SIFs have been observed in those conditions even from fully coated surfaces. 18 Interestingly, the fluctuations become even more evident when the acquisition time is decreased further, into the μs time scale. 19 For instance, using an acquisition rate of 800 Hz, enabled by an AiryScan (Zeiss) detector, it was possible to observe strong SIFs from fully covered single nanoparticles.…”
Section: Introductionmentioning
confidence: 99%
“…Beyond spatial confinement and control of surface concentration, another parameter that can be explored to reveal SIFs is the acquisition time. 18,19 Individual SIFs might be observed from experiments where several hotspots covered by a monolayer are simultaneously illuminated, as long as the acquisition time is very short. However, SERS experiments are commonly performed using spectrometers connected to either charge-coupled devices (CCDs) or complementary metal oxide semiconductor (CMOS) cameras.…”
Section: Introductionmentioning
confidence: 99%
“…The sub-ms experiments were realized using photomultiplier tubes (PMTs), rather than CCDs and CMOS cameras, which allowed faster acquisition time with single-photon sensitivity. 18,19 On the other hand, the PMT detection system did not have the spectral resolution to define individual vibrational features, which is a drawback of the technique. In any case, the fast SIFs observed from various hotspots even when the surface was completely covered by a molecular layer reveals new dynamical SERS effects on the microsecond scale that have not yet been fully explored.…”
Section: Introductionmentioning
confidence: 99%
“…All the experiments reporting high speed SIFs have so far 18,19 been realized only using silver nanoshells. Therefore, it is not clear if those types of high-speed intensity fluctuations are in fact a fundamental characteristic of SERS or if the phenomenon is specific for that nanoparticle substrate.…”
The observation of single molecule events using surface-enhanced Raman scattering (SERS) is a well-established phenomenon. These events are characterized by strong fluctuations in SERS intensities. High-speed SERS intensity fluctuations (in the microsecond time scale) have been reported for experiments involving single metallic particles. In this work, the high-speed SERS behavior of six different types of nanostructured metal systems (Ag nanoshells, Ag nanostars, Ag aggregated spheres, Au aggregated spheres, particle-on-mirror, and Ag deposited on microspheres) was investigated. All systems demonstrated high-speed SERS intensity fluctuations. Statistical analysis of the duration of the SERS fluctuations yielded tailed distributions with average event durations around 100 μs. Although the characteristics of the fluctuations seem to be random, the results suggest interesting differences between the system that might be associated with the strength distribution and density of the localized SERS hotspots. For instance, systems with more localized fields, such as nanostars, present faster fluctuation bursts compared to metallic aggregates that support spread-out fields. The results presented here appear to confirm that high-speed SERS intensity fluctuations are a fundamental characteristic of the SERS effect.
“…Strong SERS intensity fluctuations (SIFs) have been reported for single metallic nanoparticles fully coated by a molecular probe. 18,19 Figure 1 presents similar observations from a common SERS substrate consisting of spherical silver nanoparticles deposited on a gold surface (System 1). Figure 1.High-speed SERS with Ag nanoparticle clusters on Au film.…”
Section: Resultsmentioning
confidence: 55%
“…The typical maximum acquisition rate for these systems is one spectrum every ∼100 ms (10 Hz) and SIFs have been observed in those conditions even from fully coated surfaces. 18 Interestingly, the fluctuations become even more evident when the acquisition time is decreased further, into the μs time scale. 19 For instance, using an acquisition rate of 800 Hz, enabled by an AiryScan (Zeiss) detector, it was possible to observe strong SIFs from fully covered single nanoparticles.…”
Section: Introductionmentioning
confidence: 99%
“…Beyond spatial confinement and control of surface concentration, another parameter that can be explored to reveal SIFs is the acquisition time. 18,19 Individual SIFs might be observed from experiments where several hotspots covered by a monolayer are simultaneously illuminated, as long as the acquisition time is very short. However, SERS experiments are commonly performed using spectrometers connected to either charge-coupled devices (CCDs) or complementary metal oxide semiconductor (CMOS) cameras.…”
Section: Introductionmentioning
confidence: 99%
“…The sub-ms experiments were realized using photomultiplier tubes (PMTs), rather than CCDs and CMOS cameras, which allowed faster acquisition time with single-photon sensitivity. 18,19 On the other hand, the PMT detection system did not have the spectral resolution to define individual vibrational features, which is a drawback of the technique. In any case, the fast SIFs observed from various hotspots even when the surface was completely covered by a molecular layer reveals new dynamical SERS effects on the microsecond scale that have not yet been fully explored.…”
Section: Introductionmentioning
confidence: 99%
“…All the experiments reporting high speed SIFs have so far 18,19 been realized only using silver nanoshells. Therefore, it is not clear if those types of high-speed intensity fluctuations are in fact a fundamental characteristic of SERS or if the phenomenon is specific for that nanoparticle substrate.…”
The observation of single molecule events using surface-enhanced Raman scattering (SERS) is a well-established phenomenon. These events are characterized by strong fluctuations in SERS intensities. High-speed SERS intensity fluctuations (in the microsecond time scale) have been reported for experiments involving single metallic particles. In this work, the high-speed SERS behavior of six different types of nanostructured metal systems (Ag nanoshells, Ag nanostars, Ag aggregated spheres, Au aggregated spheres, particle-on-mirror, and Ag deposited on microspheres) was investigated. All systems demonstrated high-speed SERS intensity fluctuations. Statistical analysis of the duration of the SERS fluctuations yielded tailed distributions with average event durations around 100 μs. Although the characteristics of the fluctuations seem to be random, the results suggest interesting differences between the system that might be associated with the strength distribution and density of the localized SERS hotspots. For instance, systems with more localized fields, such as nanostars, present faster fluctuation bursts compared to metallic aggregates that support spread-out fields. The results presented here appear to confirm that high-speed SERS intensity fluctuations are a fundamental characteristic of the SERS effect.
With the advent of nanofabrication techniques, plasmonic nanoparticles (PNPs) have been widely applied in various research fields ranging from photocatalysis to chemical and bio‐sensing. PNPs efficiently convert chemical or physical stimuli in their local environment into optical signals. PNPs also have excellent properties, including good biocompatibility, large surfaces for the attachment of biomolecules, tunable optical properties, strong and stable scattering light, and good conductivity. Thus, single optical biosensors with plasmonic properties enable a broad range of uses of optical imaging techniques in biological sensing and imaging with high spatial and temporal resolution. This work provides a comprehensive overview on the optical properties of single PNPs, the description of five types of commonly used optical imaging techniques, including surface plasmon resonance (SPR) microscopy, surface‐enhanced Raman scattering (SERS) technique, differential interference contrast (DIC) microscopy, total internal reflection scattering (TIRS) microscopy, and dark‐field microscopy (DFM) technique, with an emphasis on their single plasmonic nanoprobes and mechanisms for applications in biological imaging and sensing, as well as the challenges and future trends of these fields.
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