Hydrogen Detection Using a Single Palladium Nano-Aperture on a Fiber Tip

McKeown, Steven J.; Goddard, Lynford L.

doi:10.1007/978-3-319-06998-2_9

Cited by 3 publications

(2 citation statements)

References 63 publications

(69 reference statements)

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“…177,178 Nanoapertures have been integrated with fiber optic to be used is as hydrogen sensors. 179 Furthermore fiber probe devices could be used as in situ biological sensors for detecting within cells. Tapered fibers with a nanoaperture in the metalized tip can be inserted into a cell and used to detect disease markers or track specific particles.…”

Section: Fiber Optic Nanoaperture Trapsmentioning

confidence: 99%

Label-free free-solution nanoaperture optical tweezers for single molecule protein studies

Balushi

Kotnala

Wheaton

et al. 2015

Analyst

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Nanoaperture optical tweezers are emerging as useful label-free, free-solution tools for the detection and identification of biological molecules and their interactions at the single molecule level. Nanoaperture optical tweezers provide a low-cost, scalable, straight-forward, high-speed and highly sensitive (SNR ∼ 33) platform to observe real-time dynamics and to quantify binding kinetics of protein-small molecule interactions without the need to use tethers or labeling. Such nanoaperture-based optical tweezers, which are 1000 times more efficient than conventional optical tweezers, have been used to trap and isolate single DNA molecules and to study proteins like p53, which has been claimed to be in mutant form for 75% of human cancers. More recently, nanoaperture optical tweezers have been used to probe the low-frequency (in the single digit wavenumber range) Raman active modes of single nanoparticles and proteins. Here we review recent developments in the field of nanoaperture optical tweezers and how they have been applied to protein-antibody interactions, protein-small molecule interactions including single molecule binding kinetics, and protein-DNA interactions. In addition, recent works on the integration of nanoaperture optical tweezers at the tip of optical fiber and in microfluidic environments are presented.

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Section: Fiber Optic Nanoaperture Trapsmentioning

confidence: 99%

Label-free free-solution nanoaperture optical tweezers for single molecule protein studies

Balushi

Kotnala

Wheaton

et al. 2015

Analyst

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“…However, these devices require complicated fabrication processes and have high production costs. Optical gas sensors [13][14][15][16][17][18][19][20][21] not only overcome these disadvantages but also have other unique advantages, such as negligible electrical interference, no risk of ignition from an electrical spark, and the ability to work at high temperatures or in harsh environments.…”

Section: Introductionmentioning

confidence: 99%

Realization of palladium-based optomechanical cantilever hydrogen sensor

McKeown

Wang

et al. 2017

Microsyst Nanoeng

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Hydrogen has attracted attention as an alternative fuel source and as an energy storage medium. However, the flammability of hydrogen at low concentrations makes it a safety concern. Thus, gas concentration measurements are a vital safety issue. Here we present the experimental realization of a palladium thin film cantilever optomechanical hydrogen gas sensor. We measured the instantaneous shape of the cantilever to nanometer-level accuracy using diffraction phase microscopy. Thus, we were able to quantify changes in the curvature of the cantilever as a function of hydrogen concentration and observed that the sensor's minimum detection limit was well below the 250 p.p.m. limit of our test equipment. Using the change in curvature versus the hydrogen curve for calibration, we accurately determined the hydrogen concentrations for a random sequence of exposures. In addition, we calculated the change in film stress as a function of hydrogen concentration and observed a greater sensitivity at lower concentrations.Keywords: hydrogen detection; imaging and sensing; interference microscopy; optomechanics; optical sensors; surface dynamics INTRODUCTIONHydrogen has always been viewed as a promising alternative to fossil fuels, and it can also function as an effective energy storage medium for intermittent energy sources. In addition, hydrogen is used in a range of other industries, including chemical production, metal refining, and food processing. A major safety concern with hydrogen is combustibility. Therefore, early leak detection and concentration determination of hydrogen have been areas of intense research 1-3 . There are various types of hydrogen sensors that use a wide range of detection mechanisms. Lundström et al. 4 proposed metal oxide semiconductor (MOS)-type hydrogen sensors 5 . However, MOS sensors suffer from drawbacks such as premature saturation of detectable hydrogen concentrations and low sensitivity. Other MOS-based devices have been used as hydrogen sensors, such as MOS field-effect transistors (FETs) 6,7 , high electron mobility transistors [8][9][10] , and Schottky diode-type FETs 11,12 . However, these devices require complicated fabrication processes and have high production costs. Optical gas sensors 13-21 not only overcome these disadvantages but also have other unique advantages, such as negligible electrical interference, no risk of ignition from an electrical spark, and the ability to work at high temperatures or in harsh environments.Palladium (Pd) can absorb up to 900 times its own weight in hydrogen gas at room temperature 22 . Compared with platinum 23 , Pd film is more popular because of its lower cost. Pd alloys with Ag, Au, Ni, and WO 3 have also been studied 24-29 because of their improved response time 24,25,27 , sensitivity 28,29 , and durability 26 as a sensing material. The alloys can avoid blistering effects 26 and the α to β phase transition at higher hydrogen concentrations 25,27 .

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Reflective Palladium Nanoapertures on Fiber for Wide Dynamic Range Hydrogen Sensing

McKeown

Goddard

2017

IEEE J. Select. Topics Quantum Electron.

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Hydrogen Detection Using a Single Palladium Nano-Aperture on a Fiber Tip

Cited by 3 publications

References 63 publications

Label-free free-solution nanoaperture optical tweezers for single molecule protein studies

Label-free free-solution nanoaperture optical tweezers for single molecule protein studies

Realization of palladium-based optomechanical cantilever hydrogen sensor

Reflective Palladium Nanoapertures on Fiber for Wide Dynamic Range Hydrogen Sensing

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