Co-based (oxy)hydroxide catalysts towards the oxygen evolution reaction

Karolina Cysewska,
Marcin Łapiński,
Marcin Zając,
Jakub Karczewski,
Piotr Jasiński and
Sebastian Molin

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Published 29 Mar 2023

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1. Figure 1: Chronoamperometric graphs recorded during electrochemical deposition of the catalysts on nickel foa...
  
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2. Figure 2: SEM images and corresponding EDX maps of NiFe (a), NiFe-GO (b), CoNiFe (c), and CoNiFe-GO (d) depos...
  
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3. Figure 3: Normalized XAS spectra (a–d) and XRD patterns (e) of NiFe, CoNiFe, NiFe-GO, and CoNiFe-GO.
  
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4. Figure 4: XPS high-resolution spectra of Ni 2p (a), Fe 2p (b), Co 2p (c), and C 1s (d) levels of the catalyst...
  
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5. Figure 5: Linear scan voltammetry profiles (a) with corresponding evolutions of the OER overpotential η (10 m...
  
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6. Figure 6: Linear scan voltammetry profiles (a) with corresponding Tafel plots (b) and evolution of the OER ov...
  
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7. Figure 7: Linear scan voltammetry profiles (a) with corresponding Tafel plots (b) and evolution of the OER ov...
  
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8. Figure 8: Chronopotentiometric curves recorded in aqueous solution of 1 M KOH at 10 mA∙cm⁻²_geo (a) and SEM im...
  
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Beilstein J. Nanotechnol. 2023, 14, 420–433, doi:10.3762/bjnano.14.34

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Plasmonic nanotechnology for photothermal applications – an evaluation

A. R. Indhu,
L. Keerthana and
Gnanaprakash Dharmalingam

Review
Published 27 Mar 2023

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1. Figure 1: Schematic representation of surface plasmon resonance (SPR) excitation. (a) SPR wave or surface pla...
  
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2. Figure 2: Optical spectra (absorption – red, scattering – blue, and extinction – black) of different morpholo...
  
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3. Figure 3: Manifestation of the governing factors of SPR. Shown are the changes to the peak position while con...
  
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4. Figure 4: Dissipation ratio of electron–hole pair loss vs phonon loss of the surface plasmon excitation for d...
  
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5. Figure 5: Extinction efficiencies of gold nanospheres calculated through the quasi-static approximation vs us...
  
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6. Figure 6: Absorption spectra of Au nanospheres of different diameters showing the shift of excitation wavelen...
  
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7. Figure 7: Normalized absorption spectra of Ag-NMs with different radii of the concentric spheres irradiated u...
  
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8. Figure 8: The PT conversion mechanism. (a) Photoexcitation of plasmons. (b) Electron thermalization. (c) Elec...
  
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9. Figure 9: Radiative and non-radiative decay time scales of the conversion processes in PPT materials. For the...
  
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10. Figure 10: Hot carrier lifetimes on the Fermi surface and variation between positive and negative curvature, e...
  
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11. Figure 11: Electron–phonon coupling timescales for different diameters of metal nanoparticles: (a) Ag, (b) Au,...
  
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12. Figure 12: Comparison of the probability distribution of electrons and holes at various energy levels for coin...
  
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13. Figure 13: Relaxation process of the phonon vibration. Figure 13i (left panel) was redrawn from [82]. Figure 13ii (right panel) was ad...
  
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14. Figure 14: Thermal capacitance coefficient (β) for the ellipsoidal, rod, disk, and ring morphologies of Au nan...
  
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15. Figure 15: Absorption spectra of spherical nanoparticles of Ag, Au, and Cu with radii between 50 and 100 nm an...
  
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16. Figure 16: PT conversion and thermalization of plasmonic nanoparticles after absorption of a laser pulse. The ...
  
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17. Figure 17: SEM images of Au nanoassemblies. (a) Hexagonally filled Au polyhedra. (b) Hexagonally filled Au pol...
  
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18. Figure 18: (i) FDTD calculation of absorption spectra of Au nanorods (aspect ratio of ca. 3) for different num...
  
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19. Figure 19: TEM images with 50 nm scale bars of linked Ag nanospheres prepared with an injection rate of 5 μL/m...
  
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20. Figure 20: TEM images of CuS, metal, and bimetal plasmonic nanoparticles and the corresponding temperature ris...
  
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21. Figure 21: (i) (a, b) SEM images of a black Au membrane in a hexagonal ordered array of AAO. (c) Thermal image...
  
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22. Figure 22: (i) Simulated electric field intensities of Ag/SiO₂ at the ZX plane: (a) Core–shell (d_Ag = 40 nm, t...
  
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23. Figure 23: Integrated nanostructures for PT conversion. (i) Hollow mesoporous bimetallic (Ag/Au) nanoshells fo...
  
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24. Figure 24: PT conversion efficiencies of different transition metal nitrides (HfN, ZrN, and TiN) and the corre...
  
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25. Figure 25: Colloidal stability of nanoparticles for different particle sizes from 8 to 68 nm of organic pigmen...
  
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26. Figure 26: Illustration of the chemical interaction stability of nanoparticles. (i) Chemical interactions betw...
  
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27. Figure 27: Thermal stability of Ag and Au nanoparticles of different shapes at different temperatures. (i) (a)...
  
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28. Figure 28: Thermal stability of Au nanorods at increasing temperatures. (i) Aspect ratio and plasmonic absorba...
  
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Beilstein J. Nanotechnol. 2023, 14, 380–419, doi:10.3762/bjnano.14.33

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New trends in nanobiotechnology

Pau-Loke Show,
Kit Wayne Chew,
Wee-Jun Ong,
Sunita Varjani and
Joon Ching Juan

Editorial
Published 27 Mar 2023

Beilstein J. Nanotechnol. 2023, 14, 377–379, doi:10.3762/bjnano.14.32

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Quercetin- and caffeic acid-functionalized chitosan-capped colloidal silver nanoparticles: one-pot synthesis, characterization, and anticancer and antibacterial activities

Akif Hakan Kurt,
Elif Berna Olutas,
Fatma Avcioglu,
Hamza Karakuş,
Mehmet Ali Sungur,
Cansu Kara Oztabag and
Muhammet Yıldırım

Full Research Paper
Published 20 Mar 2023

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1. Figure 1: Chemical structures of chitosan, quercetin, and caffeic acid, respectively.
  
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2. Figure 2: UV–vis absorption spectra of (a) chitosan-only (Ch-), (b) chitosan/quercetin (Ch/Q-), and (c) chito...
  
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3. Figure 3: FTIR spectra of (a) the chitosan/quercetin (Ch/Q-)-, and (b) the chitosan/caffeic acid (Ch/CA-)-cap...
  
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4. Figure 4: TEM images of (a) the chitosan/quercetin- (Ch/Q-) and (b) the chitosan/caffeic acid (Ch/CA-)-capped...
  
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5. Figure 5: (a) UV–vis absorption spectra of the quercetin–AlCl₃ complex and quercetin only (inset figure). (b)...
  
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6. Figure 6: Concentration (dose)-dependent viability of U-118 MG and ARPE-19 cell lines for (a, b) the chitosan...
  
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Beilstein J. Nanotechnol. 2023, 14, 362–376, doi:10.3762/bjnano.14.31

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The steep road to nonviral nanomedicines: Frequent challenges and culprits in designing nanoparticles for gene therapy

Yao Yao,
Yeongun Ko,
Grant Grasman,
Jeffery E. Raymond and
Joerg Lahann

Perspective
Published 17 Mar 2023

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1. Figure 1: Prevalence of reporting imaging and (or) flow cytometry techniques, protein corona, 3D cell culture...
  
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2. Figure 2: Practical concerns regarding dose determination in nucleic acid–NP systems. Left: Examples of possi...
  
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Beilstein J. Nanotechnol. 2023, 14, 351–361, doi:10.3762/bjnano.14.30

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Polymer nanoparticles from low-energy nanoemulsions for biomedical applications

Santiago Grijalvo and
Carlos Rodriguez-Abreu

Review
Published 13 Mar 2023

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1. Figure 1: Schematics of the structural and curvature changes during (a) PIT and (b) PIC nanoemulsification.
  
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2. Figure 2: (A) TEM and (B) SEM images of ethyl cellulose nanoparticles obtained from nanoemulsions with an O/S...
  
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3. Figure 3: Luciferase activity inhibition (%) for complexes formulated with PLGA nanoparticles from nanoemulsi...
  
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4. Figure 4: (a) Partial phase diagram of the system PBS/Polysorbate 80/4% PLGA in ethyl acetate. The O/W nanoem...
  
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5. Figure 5: Representative TEM images of negatively stained nanoparticles (NPs) complexed with DNA plasmids (pV...
  
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6. Figure 6: TEM images and corresponding size distributions of (a) PEGylated polyurethane and (b) lysine-coated...
  
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Beilstein J. Nanotechnol. 2023, 14, 339–350, doi:10.3762/bjnano.14.29

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Overview of mechanism and consequences of endothelial leakiness caused by metal and polymeric nanoparticles

Magdalena Lasak and
Karol Ciepluch

Review
Published 08 Mar 2023

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1. Figure 1: The main functions of endothelial cells.
  
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2. Figure 2: Two main routes to transport NPs across the endothelium, namely the transcellular route and the par...
  
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3. Figure 3: Mechanism of NanoEL. Adherens junctions between endothelial cells are maintained by a complex set o...
  
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4. Figure 4: Au NanoEL required actin remodeling. (A) Blocking the RhoA kinase actin remodeling process with Y27...
  
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Beilstein J. Nanotechnol. 2023, 14, 329–338, doi:10.3762/bjnano.14.28

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Quasi-guided modes resulting from the band folding effect in a photonic crystal slab for enhanced interactions of matters with free-space radiations

Kaili Sun,
Yangjian Cai,
Uriel Levy and
Zhanghua Han

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Published 06 Mar 2023

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1. Figure 1: (a) Schematic of the photonic crystal slab structure of air holes in a silicon layer. (b) Top view ...
  
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2. Figure 2: Dispersion curves of the GMs (hollow circles) supported by the PCS of air holes in SOI and the QGMs...
  
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3. Figure 3: (a) Q-factors along the dispersion curves of QGMs in Figure 2. (b) Q-factor as a function of the level of p...
  
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4. Figure 4: Transmission spectra at different incident angles with the incidence in (a) the xz plane and (b) th...
  
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Beilstein J. Nanotechnol. 2023, 14, 322–328, doi:10.3762/bjnano.14.27

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Bismuth-based nanostructured photocatalysts for the remediation of antibiotics and organic dyes

Akeem Adeyemi Oladipo and
Faisal Suleiman Mustafa

Review
Published 03 Mar 2023

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1. Figure 1: Mechanism of the photocatalytic process used to treat water contaminated with organic pollutants.
  
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2. Figure 2: Most recently studied and common bismuth-based nanostructured photocatalysts.
  
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3. Figure 3: Bandgaps of some bismuth-based photocatalysts extracted from various research articles [27,35-37,83-86].
  
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4. Figure 4: Summary of the commonly used synthesis methods for bismuth-based nanostructured photocatalysts.
  
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5. Figure 5: Photocatalytic degradation pathways of antibiotics by bismuth-based photocatalyst. (Adapted from [191], ...
  
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6. Figure 6: (a) Photocatalysis mechanisms of bismuth-based nanosheets via S-scheme heterojunction and type-II h...
  
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Beilstein J. Nanotechnol. 2023, 14, 291–321, doi:10.3762/bjnano.14.26

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Biocatalytic synthesis and ordered self-assembly of silica nanoparticles via a silica-binding peptide

Mustafa Gungormus

Full Research Paper
Published 28 Feb 2023

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1. Figure 1: (a) OD profiles of particle formation (dashed line: no SiBP, empty markers: SiBP alone, solid marke...
  
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2. Figure 2: SEM images of the SiO₂ particles formed by SiBP alone at concentrations of (a) 0.04 mM, (b) 0.4 mM,...
  
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3. Figure 3: SEM images and size distributions of the particles formed with (a) NH₃ only and NH₃ with (b) 0.04 m...
  
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4. Figure 4: (a) UV–vis spectra of the reactions with NH₃ alone and NH₃ + 1 mM SiBP. SEM images of the SiO₂ part...
  
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5. Figure 5: SEM micrographs of (a, c) single-layer and (b, d) multilayer self-assembled SiO₂ particles (insets:...
  
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6. Figure 6: (a) Qualitative demonstration of the long-range homogeneity of self-assembly and angular dependence...
  
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Beilstein J. Nanotechnol. 2023, 14, 280–290, doi:10.3762/bjnano.14.25

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Evaluation of electrosynthesized reduced graphene oxide–Ni/Fe/Co-based (oxy)hydroxide catalysts towards the oxygen evolution reaction

Plasmonic nanotechnology for photothermal applications – an evaluation

New trends in nanobiotechnology

Quercetin- and caffeic acid-functionalized chitosan-capped colloidal silver nanoparticles: one-pot synthesis, characterization, and anticancer and antibacterial activities

The steep road to nonviral nanomedicines: Frequent challenges and culprits in designing nanoparticles for gene therapy

Polymer nanoparticles from low-energy nanoemulsions for biomedical applications

Overview of mechanism and consequences of endothelial leakiness caused by metal and polymeric nanoparticles

Quasi-guided modes resulting from the band folding effect in a photonic crystal slab for enhanced interactions of matters with free-space radiations

Bismuth-based nanostructured photocatalysts for the remediation of antibiotics and organic dyes

Biocatalytic synthesis and ordered self-assembly of silica nanoparticles via a silica-binding peptide

Other Beilstein-Institut Open Science Activities

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