Prediction of Limits of Solar‐to‐Hydrogen Efficiency from Polarization Curves of the Electrochemical Cells

A considerable photo-current enhancement was found at the Cu/p-Cu2O/rGO-electrolyte interface in a photo-electrochemical cell with compared to that of Cu/p-Cu2O-electrolyte interface. The reason for the photo-current enhancement may be due to the efficient charge separation process provided at Cu/p-Cu2O/rGO-electrolyte interface. Here rGO (reduced graphene oxide) acts as an electron acceptor for the photo-generated charge carriers as it readily accept electrons from the conduction band of p-Cu2O. rGO was synthesized using electro-phoretic deposition (EPD) technique. Fabricated samples were characterized using diffuse reflectance spectra, photo-current action spectra and the time development of the photocurrent of photo-electrochemical cells.

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Effect of various cations on the initial rate of formation of peroxodisulphates

Collection of Czechoslovak Chemical Communications ◽

10.1135/cccc19802272 ◽

1980 ◽

Vol 45 (8) ◽

pp. 2272-2282 ◽

Cited By ~ 4

Author(s):

Jan Balej ◽

Martin Kadeřávek

Keyword(s):

Sulphuric Acid ◽

Oxygen Evolution ◽

Anodic Polarization ◽

Initial Rate ◽

Degree Of Conversion ◽

Polarization Curves ◽

Mixed Solutions ◽

Low Degree ◽

Partial Polarization

Preparation of peroxodisulphates by electrolysis of mixed solutions of sulphuric acid and various sulphates was studied at low degree of conversion; the partial polarization curves of peroxodisulphate formation and of oxygen evolution obtained from the overall anodic polarization curves and current yields of the principal anodic processes were examined. The mechanism of the effect of various cations on the rate of anodic formation of peroxodisulfates is discussed.

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Evaluation of an Inquiry-Based Virtual Lab for Junior High School Science Classes

Journal of Educational Computing Research ◽

10.1177/07356331211001579 ◽

2021 ◽

pp. 073563312110015

Author(s):

Ting-Ling Lai ◽

You-Sheng Lin ◽

Chi-Yin Chou ◽

Hsiu-Ping Yueh

Keyword(s):

High School ◽

Junior High School ◽

Junior High ◽

School Science ◽

High School Science ◽

Electrochemical Cells ◽

Head Mounted Display ◽

Science Classes ◽

Desktop Vr ◽

Experimental Group

The study aims to evaluate the effectiveness of an inquiry-based virtual reality (VR) science lab used in junior high school science classes. The Scientific Investigation VR Lab (SIVRLAB) is designed for 9th-grade students to learn about electrochemical cells. It is situated in a guided problem-solving context, where learners need to review the concept of oxidation-reduction reactions and assemble a voltaic cell to save a robot. The SIVRLAB features several cognitive supports and guides for students to plan and record experiments and resolve the problem. It has both a head-mounted display (HMD) version and a desktop VR version. The study recruited 66 9th graders from three classes to evaluate the two versions of the SIVRLAB. The students were assigned to one of three conditions, namely, (1) using immersive HMD SIVRLAB individually, (2) using desktop SIVRLAB individually, and (3) observing one student use immersive HMD SIVRLAB. The students were briefly introduced to the concept of electrochemical cells in the first class and were instructed to use the SIVRLAB sessions in the next class. The results from knowledge pre- and post-tests, a user experience survey, and students’ reflections were collected and analyzed qualitatively. The findings revealed that students who used the desktop VR obtained the highest test scores among the three groups. However, in the follow-up physical laboratory test, the performance of the students in the original HMD VR experimental group was better than those in the desktop VR experimental group. The paper also discusses student feedback and teacher observations regarding the design and interaction with immersive VR. Lastly, the implications of the study and recommendations for future studies are presented.

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The Equilibrium Phase Formation and Thermodynamic Properties of Functional Tellurides in the Ag–Fe–Ge–Te System

Energies ◽

10.3390/en14051314 ◽

2021 ◽

Vol 14 (5) ◽

pp. 1314

Author(s):

Mykola Moroz ◽

Fiseha Tesfaye ◽

Pavlo Demchenko ◽

Myroslava Prokhorenko ◽

Nataliya Yarema ◽

...

Keyword(s):

Electromotive Force ◽

Equilibrium Phase ◽

Stoichiometric Composition ◽

Negative Electrode ◽

Electrochemical Cells ◽

Thermodynamic Quantities ◽

Positive Electrodes ◽

Gibbs Energies ◽

Buffer Region ◽

First Time

Equilibrium phase formations below 600 K in the parts Ag2Te–FeTe2–F1.12Te–Ag2Te and Ag8GeTe6–GeTe–FeTe2–AgFeTe2–Ag8GeTe6 of the Fe–Ag–Ge–Te system were established by the electromotive force (EMF) method. The positions of 3- and 4-phase regions relative to the composition of silver were applied to express the potential reactions involving the AgFeTe2, Ag2FeTe2, and Ag2FeGeTe4 compounds. The equilibrium synthesis of the set of phases was performed inside positive electrodes (PE) of the electrochemical cells: (−)Graphite ‖LE‖ Fast Ag+ conducting solid-electrolyte ‖R[Ag+]‖PE‖ Graphite(+), where LE is the left (negative) electrode, and R[Ag+] is the buffer region for the diffusion of Ag+ ions into the PE. From the observed results, thermodynamic quantities of AgFeTe2, Ag2FeTe2, and Ag2FeGeTe4 were experimentally determined for the first time. The reliability of the division of the Ag2Te–FeTe2–F1.12Te–Ag2Te and Ag8GeTe6–GeTe–FeTe2–AgFeTe2–Ag8GeTe6 phase regions was confirmed by the calculated thermodynamic quantities of AgFeTe2, Ag2FeTe2, and Ag2FeGeTe4 in equilibrium with phases in the adjacent phase regions. Particularly, the calculated Gibbs energies of Ag2FeGeTe4 in two different adjacent 4-phase regions are consistent, which also indicates that it has stoichiometric composition.

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Transition metal-catalyzed organic reactions in undivided electrochemical cells

Chemical Science ◽

10.1039/d1sc04011a ◽

2021 ◽

Author(s):

Cong Ma ◽

Ping Fang ◽

Dong Liu ◽

Ke-Jin Jiao ◽

Pei-Sen Gao ◽

...

Keyword(s):

Transition Metal ◽

Research Area ◽

Metal Catalysts ◽

Organic Reactions ◽

Electrochemical Cells ◽

Organic Electrochemistry ◽

Transition Metal Catalyzed ◽

Metal Catalyzed

Abstract: Transition metal-catalyzed organic electrochemistry is a rapidly growing research area owing in part of the ability of metal catalysts to alter the selectivity of a given transformation. This conversion...

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Synthesis, Study, and Application of Pd(II) Hydrazone Complexes as the Emissive Components of Single-Layer Light-Emitting Electrochemical Cells

Inorganic Chemistry ◽

10.1021/acs.inorgchem.0c03102 ◽

2021 ◽

Author(s):

Marzieh Emami ◽

Hashem Shahroosvand ◽

Rahman Bikas ◽

Tadeusz Lis ◽

Cody Daneluik ◽

...

Keyword(s):

Single Layer ◽

Electrochemical Cells ◽

Light Emitting ◽

Hydrazone Complexes

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