Conductivity-based detection techniques in nanofluidic devices

Harms, Zachary D.; Haywood, Daniel G.; Kneller, Andrew R.; Jacobson, Stephen C.

doi:10.1039/c5an00075k

Cited by 25 publications

(27 citation statements)

References 173 publications

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“…24,113,[217][218][219][220][221] Passage of an analyte through the nanopore can generate a perturbation in the measured current that arises from physical displacement of solution ions by the analyte and from more complex interactions between charges in solution and on the surface of the analyte and nanopore. 24,28,52,[221][222][223] It is convenient to generically refer to the current perturbations as ''blockages,'' although analyte properties and sensing conditions may lead even to current enhancements. 221 With suitable nanopore and experimental design, the measured current perturbation generates a signal from a single molecule at a time that can be used for chemical identification or profiling.…”

Section: Nanofluidic Sample Cellsmentioning

confidence: 99%

“…The insulating, impermeable SiN x thus acts as a physical barrier and as a support for the channel through which ions and molecules can pass under the influence of an electric field or other suitable driving force. [21][22][23][24][25][26][27][28][29][211][212][213][214][215][216] The most common sensing configuration is the so-called resistive-pulse sensing mode (Fig. 10).…”

Section: Nanofluidic Sample Cellsmentioning

confidence: 99%

“…The use of silicon nitride windows in creating sample cells and chambers has become increasingly prevalent, as has their use as sample supports; their use as a platform to host structural elements such as nanofluidic channels is a relatively new area of application and investigation. [16][17][18][19][20][21][22][23][24][25][26][27][28][29] Two particularly compelling uses of thin-film windows are shown in Fig. 1 and Fig.…”

Section: Introductionmentioning

confidence: 99%

“…[21][22][23][24][25][26][27][28][29] Extension of this single pore design to many pores allows the same thin-film platform to function as a high-throughput filter, with implications also for nanoplasmonics. 60,61 There are excellent reviews focusing on these two particular implementations alone, [21][22][23][24][25][26][27][28][29]38,40 and a recent book chapter reviewing both in a unifying context of nanofluidics. 20 We hope the present review will encourage an appreciation of the breadth of application of even an ostensibly prosaic free-standing thin-film structure across a host of spectroscopy, microscopy, and sensing techniques.…”

Section: Introductionmentioning

confidence: 99%

“…[17][18][19] Thin films with suitable properties and structures can also be used in a more active role in experimental studies: a $10 nm diameter channel through a < 100 nm thick thin film-a so-called nanopore-is the basis for a wide range of single molecule sensing and manipulation methods that emerge from the passage of a molecule into, or through, the nanofluidic channel. [20][21][22][23][24][25][26][27][28][29] Figure 1 offers two illustrations to illuminate the rich scope of experimental configurations and possibilities using just these two platforms. We will frame our discussion of the interplay between thin-film design-composition and structureand application by using these two quite different implementations: a sample cell with thin-film windows bracketing a nanofluidic channel; and a nanopore single molecule sensor platform where the robust thin film supports a nanofluidic through-channel.…”

Section: Introductionmentioning

confidence: 99%

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Through a Window, Brightly: A Review of Selected Nanofabricated Thin-Film Platforms for Spectroscopy, Imaging, and Detection

Dwyer

Harb

2017

Appl Spectrosc

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We present a review of the use of selected nanofabricated thin films to deliver a host of capabilities and insights spanning bioanalytical and biophysical chemistry, materials science, and fundamental molecular-level research. We discuss approaches where thin films have been vital, enabling experimental studies using a variety of optical spectroscopies across the visible and infrared spectral range, electron microscopies, and related techniques such as electron energy loss spectroscopy, X-ray photoelectron spectroscopy, and single molecule sensing. We anchor this broad discussion by highlighting two particularly exciting exemplars: a thin-walled nanofluidic sample cell concept that has advanced the discovery horizons of ultrafast spectroscopy and of electron microscopy investigations of in-liquid samples; and a unique class of thin-film-based nanofluidic devices, designed around a nanopore, with expansive prospects for single molecule sensing. Free-standing, low-stress silicon nitride membranes are a canonical structural element for these applications, and we elucidate the fabrication and resulting features-including mechanical stability, optical properties, X-ray and electron scattering properties, and chemical natureof this material in this format. We also outline design and performance principles and include a discussion of underlying material preparations and properties suitable for understanding the use of alternative thin-film materials such as graphene.

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Section: Nanofluidic Sample Cellsmentioning

confidence: 99%

Section: Nanofluidic Sample Cellsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Through a Window, Brightly: A Review of Selected Nanofabricated Thin-Film Platforms for Spectroscopy, Imaging, and Detection

Dwyer

Harb

2017

Appl Spectrosc

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Nanofluidics: A New Arena for Materials Science

2017

Advanced Materials

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A significant growth of research in nanofluidics is achieved over the past decade, but the field is still facing considerable challenges toward the transition from the current physics-centered stage to the next application-oriented stage. Many of these challenges are associated with materials science, so the field of nanofluidics offers great opportunities for materials scientists to exploit. In addition, the use of unusual effects and ultrasmall confined spaces of well-defined nanofluidic environments would offer new mechanisms and technologies to manipulate nanoscale objects as well as to synthesize novel nanomaterials in the liquid phase. Therefore, nanofluidics will be a new arena for materials science. In the past few years, burgeoning progress has been made toward this trend, as overviewed in this article, including materials and methods for fabricating nanofluidic devices, nanofluidics with functionalized surfaces and functional material components, as well as nanofluidics for manipulating nanoscale materials and fabricating new nanomaterials. Many critical challenges as well as fantastic opportunities in this arena lie ahead. Some of those, which are of particular interest, are also discussed.

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Conductance‐based profiling of nanopores: Accommodating fabrication irregularities

et al. 2017

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Solid-state nanopores are nanoscale channels through otherwise impermeable membranes. Single molecules or particles can be passed through electrolyte-filled nanopores by, e.g. electrophoresis, and then detected through the resulting physical displacement of ions within the nanopore. Nanopore size, shape, and surface chemistry must be carefully controlled, and on extremely challenging <10 nm-length scales. We previously developed a framework to characterize nanopores from the time-dependent changes in their conductance as they are being formed through solution-phase nanofabrication processes with the appeal of ease and accessibility. We revisited this simulation work, confirmed the suitability of the basic conductance equation using the results of time-dependent experimental conductance measurements during nanopore fabrication by Yanagi et al., and then deliberately relaxed the model constraints to allow for (i) the presence of defects; and (ii) the formation of two small pores instead of one larger one. Our simulations demonstrated that the time-dependent conductance formalism supports the detection and characterization of defects, as well as the determination of pore number, but with implementation performance depending on the measurement context and results. In some cases, the ability to discriminate numerically between the correct and incorrect nanopore profiles was slight, but with accompanying differences in candidate nanopore dimensions that could yield to post-fabrication conductance profiling, or be used as convenient uncertainty bounds. Time-dependent nanopore conductance thus offers insight into nanopore structure and function, even in the presence of fabrication defects.

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Conductivity-based detection techniques in nanofluidic devices

Cited by 25 publications

References 173 publications

Through a Window, Brightly: A Review of Selected Nanofabricated Thin-Film Platforms for Spectroscopy, Imaging, and Detection

Through a Window, Brightly: A Review of Selected Nanofabricated Thin-Film Platforms for Spectroscopy, Imaging, and Detection

Nanofluidics: A New Arena for Materials Science

Conductance‐based profiling of nanopores: Accommodating fabrication irregularities

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