Research in Nickel/Metal Hydride Batteries 2017

Kim, Young

doi:10.3390/batteries4010009

Cited by 24 publications

(9 citation statements)

References 28 publications

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“…The lower R ct value on the laser-treated surface is attributed to the larger surface reactive area and higher catalytic ability of the LIO-Ni surface than the pristine-Ni surface. 77 The fitting results also show that the C dl value increased from 0.83 μF on the pristine-Ni electrode to 53.9 μF on the LIO-Ni electrode, which is due to the stable high surface area oxide layer on the surface of LIO-Ni, leading to greater effective electrical double layer behavior at the electrode−solution interface. The size of the semicircle at higher frequency was increased in the presence of glucose, confirming a higher charge transfer resistance, as shown in Figure 6b.…”

Section: Acs Applied Nano Materialsmentioning

confidence: 81%

Laser-Induced Mesoporous Nickel Oxide as a Highly Sensitive Nonenzymatic Glucose Sensor

Sedaghat

Piepenburg

Zareei

et al. 2020

ACS Appl. Nano Mater.

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In this paper, we present a novel laser-induced oxidation procedure for in situ formation of nickel oxide nanoporous structures directly onto the nickel surface as a highly sensitive nonenzymatic glucose sensor. The formation of mesoporous nickel oxide is confirmed by field-emission scanning electron microscopy, energy-dispersive X-ray spectroscopy, and X-ray diffraction. Electrochemical properties of the pristine and laser-induced oxidized nickel (LIO-Ni) films were studied using cyclic voltammetry and electrochemical impedance spectroscopy. The unique three-dimensional mesoporous architecture of the oxide film on the LIO-Ni electrode resulted in a dramatic enhancement in electrochemical reduction/oxidation performance with a 10-fold increase in electrocatalytic activity for nonenzymatic glucose oxidation as compared to the pristine-Ni electrode. The LIO-Ni biosensor performance was successfully examined for the amperometric detection of glucose over a wide concentration range from 5 μM to 1.1 mM with a high linear sensitivity of 5222 μA mM −1 cm −2 . The limit of detection was obtained as low as 3.31 μM with a signal-tonoise ratio of 3. Furthermore, the LIO-Ni electrode showed outstanding long-term stability, reproducibility, and high selectivity in the presence of various interfering agents including uric acid, L-ascorbic acid, acetaminophen, glutamic acid, and citric acid. The demonstrated laser-induced oxidation process can be potentially adapted to the scalable manufacturing of a wide range of other easyto-use and robust metal oxide-based sensors for nonenzymatic biosensing applications.

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Section: Acs Applied Nano Materialsmentioning

confidence: 81%

Laser-Induced Mesoporous Nickel Oxide as a Highly Sensitive Nonenzymatic Glucose Sensor

Sedaghat

Piepenburg

Zareei

et al. 2020

ACS Appl. Nano Mater.

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“…Nickel-metal hydride (Ni-MH) technology has been used in several applications such as energy storage for smart energy systems, robust battery systems which work at high temperatures, hybrid electric cars and public transport [26]. Ni-MH battery cell cross section with the main parts is shown in Fig.…”

Section: Nickel-metal Hydridementioning

confidence: 99%

Battery energy storage technologies overview

Šimić

Topić

Knežević

et al. 2021

Int. j. electr. comput. eng. syst. (Online)

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Battery technologies overview for energy storage applications in power systems is given. Lead-acid, lithium-ion, nickel-cadmium, nickel-metal hydride, sodium-sulfur and vanadium-redox flow batteries are overviewed. Description, graphical representation, advantages and disadvantages as well as technical characteristics are given for all technologies. Differences and similarities between different battery technologies are perceived. Battery technologies are considered with respect to peak shaving, load leveling, power reserve, integration of renewable energy, voltage and frequency regulation and uninterruptible power supply applications. According to technical characteristics for overviewed technologies, comparison between battery storage technologies is given through diagrams which are uniformed. Comparison is done according to specific power, specific energy, power density, energy density, power cost, energy cost, lifetime, lifetime cycles, cell voltage and battery technology efficiency.

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“…Specifically, successfully commercialized Li-ion battery (LIB) is a promising green technology to replace the conventional fossil -fuel-powered devices and they have been adapting as a potential energy source in various applications, such as electric vehicles, portable devices, mobile device technology, drones, medical devices, and advanced robotics. [31][32][33][34][35][36][37][38][39][40] The promising characteristic parameters such as high energy density, overall capacity, cyclability, and thermal/chemical stability of a commercialized secondary ion battery predominantly depend on the nature of electrodes (i.e., cathode and anode), electrolyte, and "electrode/electrolyte" interfaces. Worth mentioning that, in the total architecture of the secondary ion battery, the inert electrolyte component play a vital role in the enhancement of lifetime, safety, chemical stability, and good interface interactions with electrode materials (Figure 2).…”

Section: Introductionmentioning

confidence: 99%

Review on Microstructural and Ion‐conductivity Properties of Biodegradable Starch‐Based Solid Polymer Electrolyte Membranes

2021

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Currently, scientific developments in both the academic and industrial research communities are giving much attention towards the development of green chemistry secondary ion batteries with safety attributes. Biodegradable starch polymer-based electrolyte systems doped with different inorganic salts are gaining much attention owing to their intriguing and non-toxic nature. In this context, several research approaches have been identified for the improvement of lithium-ion conductivities at ambient temperatures, thermal and mechanical properties of starch polymer-based electrolytes. The present review provides consolidated information on chronological developments in the fabrication of different types of starch-based electrolytes (i.e., pure, blend, plasticized, and nanocomposites) and discusses microstructural, thermal, mechanical, and lithium-ion conductivity properties given lithium-ion batteries. Among all types, ionic liquids doped starch-based electrolytes demonstrated appreciable room temperature Li-ion conductivities. In parallel, a comparative study on Na + , K + , NH 4 + , Ag + , and Mg 2+ -ions conductivities in starch-based electrolytes is presented to emphasize the further research scope on the development of novel secondary ion batteries in complementing with lithium-ion batteries.

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Research in Nickel/Metal Hydride Batteries 2017

Cited by 24 publications

References 28 publications

Laser-Induced Mesoporous Nickel Oxide as a Highly Sensitive Nonenzymatic Glucose Sensor

Laser-Induced Mesoporous Nickel Oxide as a Highly Sensitive Nonenzymatic Glucose Sensor

Battery energy storage technologies overview

Review on Microstructural and Ion‐conductivity Properties of Biodegradable Starch‐Based Solid Polymer Electrolyte Membranes

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