A novel all-fiber-based LiFePO₄/Li₄Ti₅O₁₂ battery with self-standing nanofiber membrane electrodes

Li-li Chen,
Hua Yang,
Mao-xiang Jing,
Chong Han,
Fei Chen,
Xin-yu Hu,
Wei-yong Yuan,
Shan-shan Yao and
Xiang-qian Shen

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Published 13 Nov 2019

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1. Figure 1: Fabrication process of all-fiber-based gel-state batteries.
  
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2. Figure 2: Digital photos of LiFePO₄ nanofiber films. (a, b) The precursor fiber membrane; (c) the pre-treated...
  
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3. Figure 3: SEM pictures of LiFePO₄ and Li₄Ti₅O₁₂ nanofiber membranes. (a, b) LiFePO₄; (c, d) Li₄Ti₅O₁₂.
  
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4. Figure 4: TEM pictures and EDS spectra of LiFePO₄ and Li₄Ti₅O₁₂ fibers. (a)TEM of a LiFePO₄ fiber; (b) TEM of...
  
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5. Figure 5: XRD patterns of LiFePO₄ and Li₄Ti₅O₁₂ fiber membranes.
  
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6. Figure 6: Raman spectra of LiFePO₄ and Li₄Ti₅O₁₂ fiber membranes.
  
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7. Figure 7: CV curves of LiFePO₄ and Li₄Ti₅O₁₂ fiber membrane electrodes.
  
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8. Figure 8: Charge–discharge curves of LiFePO₄ and Li₄Ti₅O₁₂ fiber membrane electrodes.
  
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9. Figure 9: EIS curves of LiFePO₄ and Li₄Ti₅O₁₂ fiber membrane electrodes.
  
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10. Figure 10: Rate performance of LiFePO₄ and Li₄Ti₅O₁₂ fiber membrane electrodes.
  
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11. Figure 11: Cycle performance of LiFePO₄ and Li₄Ti₅O₁₂ fiber membrane electrodes.
  
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12. Figure 12: Charge–discharge curves of the LiFePO₄//Li₄Ti₅O₁₂ all-fiber battery at 1C.
  
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13. Figure 13: Rate performance of the LiFePO₄//Li₄Ti₅O₁₂ all-fiber battery.
  
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14. Figure 14: Cycle performance of the LiFePO₄//Li₄Ti₅O₁₂ all-fiber battery at 1C.
  
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15. Figure 15: Sketch of 3D network structure for fast electron and ion transport.
  
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Beilstein J. Nanotechnol. 2019, 10, 2229–2237, doi:10.3762/bjnano.10.215

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Targeted therapeutic effect against the breast cancer cell line MCF-7 with a CuFe₂O₄/silica/cisplatin nanocomposite formulation

B. Rabindran Jermy,
Vijaya Ravinayagam,
Widyan A. Alamoudi,
Dana Almohazey,
Hatim Dafalla,
Lina Hussain Allehaibi,
Abdulhadi Baykal,
Muhammet S. Toprak and
Thirunavukkarasu Somanathan

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Published 12 Nov 2019

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1. Scheme 1: Schematic representation of CuFe₂O₄/HYPS/cisplatin nanoformulation.
  
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2. Figure 1: Powder XRD patterns of CuFe₂O₄/HYPS with different Cu concentrations (x = 0.08, 0.10, 0.12, 0.15 an...
  
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3. Figure 2: BET adsorption–desorption isotherm and pore size distribution of (a) HYPS and (b) 30 wt% CuFe₂O₄/HY...
  
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4. Figure 3: FTIR spectra of HYPS and 30 wt % CuFe₂O₄/HYPS.
  
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5. Figure 4: Transmission electron microscopy of (a, b) 30 wt % CuFe₂O₄/HYPS at different scale magnifications a...
  
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6. Figure 5: Vibrating sample magnetometer spectrum of 30 wt % CuFe₂O₄/HYPS.
  
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7. Figure 6: DR-UV–visible spectra of (a) CuFe₂O₄/HYPS and (b) cisplatin/CuFe₂O₄/HYPS.
  
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8. Figure 7: Percentage cumulative cisplatin release in tumor pH 5 conditions for 72 h in (a) CuFe₂O₄/HYPS, (b) ...
  
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9. Figure 8: Percentage cell viability using MTT assay on the MCF-7 cell line. The cells were treated with the f...
  
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10. Figure 9: EC₅₀ values for each condition. Data sets from Figure 8 were used to extrapolate the line equation of each ...
  
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Beilstein J. Nanotechnol. 2019, 10, 2217–2228, doi:10.3762/bjnano.10.214

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Ultrathin Ni₁₋_xCo_xS₂ nanoflakes as high energy density electrode materials for asymmetric supercapacitors

Xiaoxiang Wang,
Teng Wang,
Rusen Zhou,
Lijuan Fan,
Shengli Zhang,
Feng Yu,
Tuquabo Tesfamichael,
Liwei Su and
Hongxia Wang

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Published 11 Nov 2019

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1. Figure 1: (a) X-ray diffraction patterns of Ni₁₋_xCo_xS₂; (b) FESEM images and (c) enlarged FESEM images of Ni₁₋...
  
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2. Figure 2: (a) EDS pattern of Ni₁₋_xCo_xS₂ and high-resolution XPS spectra of (b) Ni 2p, (c) Co 2p, and (d) S 2p...
  
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3. Figure 3: (a) CV curves at sweep rates from 2 to 100 mV·s⁻¹ (vs Hg/HgO); (b) GCD curves at different current ...
  
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4. Figure 4: a) Configuration of the ASC; (b) CV curves of the ASC at different potential windows with a scan ra...
  
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Beilstein J. Nanotechnol. 2019, 10, 2207–2216, doi:10.3762/bjnano.10.213

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Mannosylated brush copolymers based on poly(ethylene glycol) and poly(ε-caprolactone) as multivalent lectin-binding nanomaterials

Stefania Ordanini,
Wanda Celentano,
Anna Bernardi and
Francesco Cellesi

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Published 07 Nov 2019

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1. Figure 1: Synthetic approach (upper panel), final structure and nomenclature (lower panels) of the mannose-fu...
  
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2. Scheme 1: Synthetic pathway to obtain linear and four-arm mannosylated copolymers.
  
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3. Figure 2: A) Kinetic profiles obtained for the synthesis of (A4-)PEG₉-PCL₁ and (A4-)PEG₈-PCL₂ copolymers. Rea...
  
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4. Figure 3: Comparison of the ¹H NMR spectrum of one selected polymer (A4-PEG₈-PCL₂, MeOD) before (upper panel)...
  
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5. Figure 4: TEM images of A4-PEG₈-PCL₂ 10 mg/mL in water; size distribution is dominated by small nanoparticles...
  
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6. Figure 5: DLS size distribution (vol %) of the glycopolymers PEG₉-PCL₁-Man₁ (A), PEG₈-PCL₂-Man₂ (B), A4-PEG₉-...
  
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7. Figure 6: A) Schematic representation of Con A clustering by multivalent ligands. B) Con A suspensions after ...
  
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8. Figure 7: Turbidimetric assay results. A) Optical density (OD) data were recorded at 420 nm every 12 s for 10...
  
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Beilstein J. Nanotechnol. 2019, 10, 2192–2206, doi:10.3762/bjnano.10.212

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Nonlinear absorption and scattering of a single plasmonic nanostructure characterized by x-scan technique

Tushar C. Jagadale,
Dhanya S. Murali and
Shi-Wei Chu

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Published 06 Nov 2019

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1. Figure 1: (a) Schematic principle of the x-scan method, the excitation focus is scanned in x-direction. The b...
  
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2. Figure 2: (a) Backward path and (b) forward path images of spherical gold nanostructures in the linear excita...
  
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3. Figure 3: (a) Backward path and (b) forward path images of the same ten spherical gold nanostructures shown i...
  
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4. Figure 4: (a) Backward path and (b) forward path images of the same ten spherical gold nanostructures as in Figure 3 ...
  
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5. Figure 5: (a) Excitation intensity dependent attenuation (blue dots), absorption (green dots) and backscatter...
  
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6. Figure 6: (a) Schematic of the experimental setup of the laser scanning system based on an inverted microscop...
  
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Beilstein J. Nanotechnol. 2019, 10, 2182–2191, doi:10.3762/bjnano.10.211

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Use of data processing for rapid detection of the prostate-specific antigen biomarker using immunomagnetic sandwich-type sensors

Camila A. Proença,
Tayane A. Freitas,
Thaísa A. Baldo,
Elsa M. Materón,
Flávio M. Shimizu,
Gabriella R. Ferreira,
Frederico L. F. Soares,
Ronaldo C. Faria and
Osvaldo N. Oliveira Jr.

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Published 06 Nov 2019

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1. Figure 1: (A) Amperometric responses for a blank solution and PSA solutions at concentrations of: (a) 12.5, (...
  
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2. Figure 2: Peak current as a function of the PSA concentration fitted with a Langmuir–Freundlich equation (das...
  
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3. Figure 3: ELISA and INμ-SPCE results for PSA in control cell lysates (PNT-2) and prostate cancer cells (LNCap...
  
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4. Figure 4: Parallel coordinates plot for PSA concentrations from 12.5 to 1111 fg·mL⁻¹ after the feature-select...
  
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5. Figure 5: IDMAP plot obtained from the data in Figure 1A for buffers containing different PSA concentrations and from Figure 3...
  
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6. Figure 6: Schematic illustration of the fabrication of sandwich-type electrochemical immunosensors (INμ-SPCEs...
  
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7. Figure 7: Electrode modification with 10 μg·mL⁻¹ monoclonal antibody (Ab₁) using 5 μL of 2 mg·mL⁻¹ PDDA and 5...
  
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8. Figure 8: Preparation of the bioconjugate complex of Ab₂ and HRP (Ab₂-MNP-HRP).
  
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9. Figure 9: Illustration of the PSA capturing step.
  
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Beilstein J. Nanotechnol. 2019, 10, 2171–2181, doi:10.3762/bjnano.10.210

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Liquid crystal tunable claddings for polymer integrated optical waveguides

José M. Otón,
Manuel Caño-García,
Fernando Gordo,
Eva Otón,
Morten A. Geday and
Xabier Quintana

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Published 05 Nov 2019

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1. Figure 1: COMSOL simulations of light propagation in a directional coupler and two MMIs, all having rectangul...
  
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2. Figure 2: Power output in the input waveguide as a function of the effective refractive index of the LC cladd...
  
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3. Figure 3: A directional coupler prototype showing power distribution between the output guides.
  
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4. Figure 4: Power density distribution in the first three periods (3L_π) of a 1 × 1 symmetric MMI and a 2 × 2 as...
  
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5. Figure 5: The characteristic length of an MMI is nearly constant until the cladding index reaches values clos...
  
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6. Figure 6: A number of SU8 PWG MMIs of different lengths prepared at the lab. The substrate is SiO₂ on an Si w...
  
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7. Figure 7: An MMI with inorganic Si₃N₄ core and high-birefringence LC cladding does not show variations in cha...
  
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8. Figure 8: Two waveguides at short distance interacting through evanescent fields. The interaction is tuned by...
  
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Beilstein J. Nanotechnol. 2019, 10, 2163–2170, doi:10.3762/bjnano.10.209

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BergaCare SmartLipids: commercial lipophilic active concentrates for improved performance of dermal products

Florence Olechowski,
Rainer H. Müller and
Sung Min Pyo

Review
Published 04 Nov 2019

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1. Figure 1: Simple representation of the structure of SmartLipids. The mixture of structurally very different s...
  
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2. Figure 2: Maximum loading reported for SLNs, NLCs and SmartLipids for the dermal active agents retinol [11-13] (left...
  
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3. Figure 3: X-ray diffraction patterns of SLNs (pink curve) and SmartLipids mixture (red curve) determined dire...
  
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4. Figure 4: Fast degradation of lipophilic active agents (R) in fluid carriers (blue), such as oil/water emulsi...
  
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5. Figure 5: Storage study with retinol loaded SmartLipids particles over six months. Remaining retinol content ...
  
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6. Figure 6: Left: Nile red-labeled lipid nanoparticle suspension (right arm) and nanoemulsion (left arm) applie...
  
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7. Figure 7: Determination of the relative film thickness by measuring the dielectric constant D on skin. Probe ...
  
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8. Figure 8: Penetration of curcumin into pig ear skin, vertical pig ear slices, fluorescence microscopy images ...
  
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9. Figure 9: Models of cosmetic active agents or drugs (green) incorporated into lipid nanoparticles, from left ...
  
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10. Figure 10: Examples of release profiles from lipid nanoparticles: very fast release of cyclosporine within min...
  
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11. Figure 11: In vitro release of the sunscreen oxybenzone from a nanoemulsion (grey) and from a SLN suspension (...
  
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Beilstein J. Nanotechnol. 2019, 10, 2152–2162, doi:10.3762/bjnano.10.208

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Nitrogen-vacancy centers in diamond for nanoscale magnetic resonance imaging applications

Alberto Boretti,
Lorenzo Rosa,
Jonathan Blackledge and
Stefania Castelletto

Review
Published 04 Nov 2019

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1. Figure 1: Diamond NV center mediated optomagnetic imaging of brain sample neural activity [72]. Image reproduced ...
  
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2. Figure 2: Experimental set-up and characterization of NV centers and the gradient microcoil of [43]. Image reprod...
  
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3. Figure 3: Single-cell magnetic imaging quantum diamond microscope [53]. Image reprinted with permission from [53], co...
  
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4. Figure 4: NV-NMR detection system schematic of [73]. Image reprinted with permission from [73], copyright 2013, AAAS....
  
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5. Figure 5: Experimental setup and magnetometry with repetitive readout [78]. Image reprinted with permission from [78]...
  
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6. Figure 6: NV-ensemble sensor for coherently averaged synchronized readout (CASR) NMR. Image reprinted with pe...
  
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Beilstein J. Nanotechnol. 2019, 10, 2128–2151, doi:10.3762/bjnano.10.207

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Improved adsorption and degradation performance by S-doping of (001)-TiO₂

Xiao-Yu Sun,
Xian Zhang,
Xiao Sun,
Ni-Xian Qian,
Min Wang and
Yong-Qing Ma

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Published 01 Nov 2019

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1. Figure 1: Experimental (×) and calculated (—) X-ray powder diffraction patterns of 1-S0 (a) and 2-S2 (b). Pea...
  
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2. Figure 2: TEM images (a–c) and HRTEM images (d–f) for 1-S0, 2-S0, and 2-S2.
  
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3. Figure 3: The FTIR spectra of 1-S0, 1-S2 and 1-S5 (a); 2-S0, 2-S2 and 2-S5 (b).
  
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4. Figure 4: Core-level XP spectra of Ti 2p (a and d), O 1s (b and e) and S 2p (c and f) for 2-S1 and 2-S3. The ...
  
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5. Figure 5: Valence-band XPS of 2-S0, 2-S0.5, 2-S1, 2-S3 and 2-S5.
  
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6. Figure 6: The UV–vis DRS of 2-S0, 2-S0.5, 2-S1, 2-S3 and 2-S5. The inset is the magnified plot of the UV–vis ...
  
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7. Figure 7: The temporal evolution of the UV–Vis spectra during the photodegradation of aqueous MB over the sam...
  
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8. Figure 8: Nitrogen adsorption–desorption isotherms of samples 2-S0, 2-S and 2-S5. The inset shows the pore si...
  
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9. Figure 9: The PL spectra of 2-S0, 2-S0.5, 2-S2, 2-S3 and 2-S5 using an excitation wavelength of λ_ex = 300 nm.
  
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10. Figure 10: ESR spectra of radical adducts trapped by DMPO in 2-S0 (a, e), 2-S2 (b, f), 2-S3 (c, g), and 2-S2 (...
  
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Beilstein J. Nanotechnol. 2019, 10, 2116–2127, doi:10.3762/bjnano.10.206

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