Zobrazeno 1 - 10
of 87
pro vyhledávání: '"Amirkianoosh Kiani"'
Publikováno v:
Heliyon, Vol 10, Iss 17, Pp e37188- (2024)
The escalating demand for green hydrogen (H2) as a sustainable energy carrier has attracted intensive research into efficient water electrolysis methods. Promising candidates have emerged as binder-less metal electrodes, which enhance electrochemical
Externí odkaz:
https://doaj.org/article/31eca8b034fe4ed3b59404ce289661d4
Publikováno v:
Scientific Reports, Vol 13, Iss 1, Pp 1-14 (2023)
Abstract Developing a cost-effective pseudocapacitor electrode manufacturing process incorporating binder-free, green synthesis methods and single-step fabrication is crucial in advancing supercapacitor research. This study aims to address this press
Externí odkaz:
https://doaj.org/article/badaf3c6200d420c927ad345a5844ee0
Autor:
Kavian Khosravinia, Amirkianoosh Kiani
Publikováno v:
STAR Protocols, Vol 4, Iss 3, Pp 102469- (2023)
Summary: Ultra-short laser pulses for in situ nanostructure generation (ULPING) enable the production of high-performance capacitive electrodes for pseudocapacitors, opening avenues for optimal electrode design. Here, we present a protocol for fabric
Externí odkaz:
https://doaj.org/article/aa7e54e91db14cff887abda5c9c9eb10
Publikováno v:
Micromachines, Vol 15, Iss 3, p 347 (2024)
Gallium oxide (Ga2O3) is a promising material for high-power semiconductor applications due to its wide band gap and high breakdown voltage. However, the current methods for fabricating Ga2O3 nanostructures have several disadvantages, including their
Externí odkaz:
https://doaj.org/article/2293e8ffddd04c9d9428f7ab7f063191
Autor:
Kavian Khosravinia, Amirkianoosh Kiani
Publikováno v:
iScience, Vol 26, Iss 4, Pp 106438- (2023)
Summary: Pseudocapacitors outperform lithium-ion batteries in terms of charging rate and power density. However, their electrode manufacturing procedures are prolonged and environmentally unfriendly, posing a research challenge. To address this issue
Externí odkaz:
https://doaj.org/article/001e8062fee5468daa4d5607cea1708a
Autor:
Shreeniket Joshi, Amirkianoosh Kiani
Publikováno v:
Opto-Electronic Advances, Vol 4, Iss 10, Pp 1-13 (2021)
The aim of this study is to develop a reliable method to determine optical constants for 3D-nanonetwork Si thin films manufactured using a pulsed-laser ablation technique that can be applied to other materials synthesized by this technique. An analyt
Externí odkaz:
https://doaj.org/article/6245394f395241d0a9cab1f2f2fb20c4
Autor:
Chirag Paladiya, Amirkianoosh Kiani
Publikováno v:
Results in Physics, Vol 12, Iss , Pp 1319-1328 (2019)
Considering abundance of silicon on earth with its known acceptance in semiconductor industries and increasing applications of nano porous thin films in various sensors, electrical circuits, new generation batteries, and capacitors, it is essential t
Externí odkaz:
https://doaj.org/article/2790ed7047e745069b35cf921de613dd
Publikováno v:
Energies, Vol 15, Iss 16, p 6005 (2022)
Silicon is one of the most used semiconductor materials around the world. This research was conducted on silicon to improve its opto-electrical properties including bandgap and optical conductivity using direct ultrafast pulsed nanostructure formatio
Externí odkaz:
https://doaj.org/article/a01bc98b2715445d843d674ebe7ed958
Publikováno v:
Nanomaterials, Vol 12, Iss 12, p 2061 (2022)
Gallium oxide, as an emerging semiconductor, has attracted a lot of attention among researchers due to its high band gap (4.8 eV) and a high critical field with the value of 8 MV/cm. This paper presents a review on different chemical and physical tec
Externí odkaz:
https://doaj.org/article/3b18b38a4323493c99e0e1d32129886f
Publikováno v:
Sensing and Bio-Sensing Research, Vol 30, Iss , Pp 100385- (2020)
In this study, selective optical properties of Si/SiO2 thin films and their dependence on heat treatment were investigated. Samples were synthesized by pulsed-laser ablation deposition of c-Si on glass substrates and annealed at different temperature
Externí odkaz:
https://doaj.org/article/a255afce53ad4c269c0e2133696537c5