| 1. |
Nwaji N., Juyong G.♦, My‐Chi N.♦, Huu‐Quang N.♦, Hyojin K.♦, Youngeun C.♦, Youngmi K.♦, Hongxia C.♦, Jaebeom L.♦, Emerging potentials of Fe-based nanomaterials for chiral sensing and imaging,
Medicinal Research Review, ISSN: 1098-1128, DOI: 10.1002/med.22003, pp.Journal of Medicinal Research-22003, 2024 Abstract:
Fe-based nanostructures have possessed promising properties that make it suitable for chiral sensing and imaging applications owing to their ultra-small size, non-toxicity, biocompatibility, excellent photostability, tunable fluorescence, and water solubility. This review summarizes the recent research progress in the field of Fe-based nanostructures and places special emphases on their applications in chiral sensing and imaging. The synthetic strategies to prepare the targeted Fe-based structures were also introduced. The chiral sensing and imaging applications of the nanostructures are discussed in details. Affiliations:
| Nwaji N. | - | IPPT PAN | | Juyong G. | - | other affiliation | | My‐Chi N. | - | other affiliation | | Huu‐Quang N. | - | other affiliation | | Hyojin K. | - | other affiliation | | Youngeun C. | - | other affiliation | | Youngmi K. | - | other affiliation | | Hongxia C. | - | other affiliation | | Jaebeom L. | - | Lexington High School (US) |
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| 2. |
Mahendra G.♦, Huu-Quang N.♦, Sohyun K.♦, Birhanu Bayissa G.♦, Lemma Teshome T.♦, Nwaji N., My-Chi Thi N.♦, Juyong G.♦, Jaebeom L.♦, Rugged forest morphology of magnetoplasmonic nanorods that collect maximum light for photoelectrochemical water splitting,
Nano Micro Small Journal, ISSN: 1613-6829, DOI: 10.1002/smll.202302980, Vol.19, pp.Small-2302980, 2024Abstract:
A feasible nanoscale framework of heterogeneous plasmonic materials and
proper surface engineering can enhance photoelectrochemical (PEC)
water-splitting performance owing to increased light absorbance, efficient
bulk carrier transport, and interfacial charge transfer. This article introduces a
new magnetoplasmonic (MagPlas) Ni-doped Au@FexOy nanorods (NRs)
based material as a novel photoanode for PEC water-splitting. A two stage
procedure produces core–shell Ni/Au@FexOy MagPlas NRs. The first-step is
a one-pot solvothermal synthesis of Au@FexOy. The hollow FexOy nanotubes
(NTs) are a hybrid of Fe2O3 and Fe3O4, and the second-step is a sequential
hydrothermal treatment for Ni doping. Then, a transverse magnetic
field-induced assembly is adopted to decorate Ni/Au@FexOy on FTO glass to
be an artificially roughened morphologic surface called a rugged forest,
allowing more light absorption and active electrochemical sites. Then, to
characterize its optical and surface properties, COMSOL Multiphysics
simulations are carried out. The core–shell Ni/Au@FexOy MagPlas NRs
increase photoanode interface charge transfer to 2.73 mAcm−2 at 1.23 V RHE.
This improvement is made possible by the rugged morphology of the NRs,
which provide more active sites and oxygen vacancies as the hole transfer
medium. The recent finding may provide light on plasmonic photocatalytic
hybrids and surface morphology for effective PEC photoanodes. Affiliations:
| Mahendra G. | - | other affiliation | | Huu-Quang N. | - | other affiliation | | Sohyun K. | - | other affiliation | | Birhanu Bayissa G. | - | other affiliation | | Lemma Teshome T. | - | other affiliation | | Nwaji N. | - | IPPT PAN | | My-Chi Thi N. | - | other affiliation | | Juyong G. | - | other affiliation | | Jaebeom L. | - | Lexington High School (US) |
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