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Daniel Adjah Anang

Chemical Engineering

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About

Dr. Daniel Anang is a Chemical and Materials Engineer who currently works as a lecturer at the Chemical Engineering department of K.N.U.S.T. He has over 5 years of research experience in emerging new energy storage systems. Dr. Anang, over the years, has gained rich experience in material synthesis, electrode fabrication and assembling of Li and Na ion batteries, supercapacitors and fuel cells and have several publications in the area to his credit.Dr. Anang also specializes in food process/product development. He is involved in a number of new food product development researches and has several publications in the area in internationally recognized Journals.

Research Summary

(inferred from publications by AI)

The researcher has made significant contributions across diverse areas of research, including high-performance supercapacitor materials and advanced battery technologies. They have developed innovative cathode materials for both active and inert batteries, enhanced food characterization techniques, explored photocatalytic processes for energy generation, and pioneered the creation of solar cells from ground-up materials. Their efforts span multiple domains, encompassing energy storage devices and sustainable materials, thereby advancing both theoretical and practical aspects of battery technology and solar energy applications.

Research Themes

All Papers

Facilely synthesized NiMoO4/CoMoO4 nanorods as electrode material for high performance supercapacitor(2018)
Rational design of sucrose-derived graphitic carbon coated MnMoO4 for high performance asymmetric supercapacitor(2022)
Facile room temperature synthesis and application of MnMoO4·0.9H2O as supercapacitor electrode material(2018)
Honeycomb layered oxide Na3Ni2SbO6 for high performance pseudocapacitor(2017)
Sucrose-directed porous carbon interfaced α-Fe2O3-rGO for supercapacitors(2023)
Carbon quantum dots from glucose oxidation as a highly competent anode material for lithium and sodium-ion batteries(2018)
O3-type layer-structured Na0.8[Ni1/5Fe1/5Co1/5Mn1/5Ti1/5]O2 as long life and high power cathode material for sodium-ion batteries(2019)
Honeycomb-layer structured Na<sub>3</sub>Ni<sub>2</sub>BiO<sub>6</sub> as a high voltage and long life cathode material for sodium-ion batteries(2016)
Ge-doped Li4Ti5-Ge O12 (x = 0.05) as a fast-charging, long-life bi-functional anode material for lithium- and sodium-ion batteries(2020)
Cd-Doped Li<sub>4–<i>x</i></sub>Cd<sub><i>x</i></sub>Ti<sub>5</sub>O<sub>12</sub> (<i>x</i> = 0.20) as a High Rate Capable and Stable Anode Material for Lithium-Ion Batteries(2023)
NaFeSnO4: Tunnel structured anode material for rechargeable sodium-ion batteries(2020)
New O3-Type Layer-Structured Na0.80[Fe0.40Co0.40Ti0.20]O2 Cathode Material for Rechargeable Sodium-Ion Batteries(2021)
Synthesis and Characterization of Novel Calcium Oxide/Calcium Ferrite, CaO/CaFe2O4 Composite Nanocatalyst for Biodiesel Production(2023)
Nutritional, microbial and sensory attributes of bread fortified with defatted watermelon seed flour(2018)
Synthesis of magnesium oxide from waste magnesium-rich <i>Cucurbita pepo</i> (pumpkin) seeds(2023)
Single Atom and Nanocluster Photocatalysts for Hydrogen Peroxide Synthesis under Visible Light(2025)
Catalytic Wet Oxidation of Paper Mill Debarking Water(2008)

Collaboration Network

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About This Profile

This profile is generated from publicly available publication metadata and is intended for research discovery purposes. Themes, summaries, and trajectories are inferred computationally and may not capture the full scope of the lecturer's work. For authoritative information, please refer to the official KNUST profile.