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    ref material size size err size unit size type size_comment BET b nanozyme b 10n b unit specific act sa 10n sa unit comment
    7346 17 MoO3–x NUs 142.8 13.3 nm TEM
    7357 35 Cu5.4O USNPs 3.5-4.0 nm TEM The average hydrodynamic diameter of Cu5.4O USNPs was approximately 4.5 nm.
    7375 66 Fe3O4 NPs ~11 nm TEM a granular shape with a mean size of ˜11 nm
    7379 73 VOxNDs 3.16 0.3 nm TEM the thicknesses
    7378 73 VOxNDs 3.36 0.23 nm TEM lateral size
    7398 95 Co3O4 210 nm TEM The transmission electron microscopy (TEM) images of the as-prepared Co3O4 MNE are shown in Figure 1A, which has a flower-like shape with an average size of ≈210 nm.
    7402 101 CeO2 NPs <10 nm TEM The particle is negatively charged with an average diameter less than 10 nm
    7407 109 IrOx ~24.05 nm TEM The as-prepared nanoparticles show a spherica morphology with diameter of ~24.05±0.29 nm (Figure 1b)
    7410 112 Cerium Oxide Nanoparticles
    7439 149 NiO 10-20 nm TEM
    7440 150 Co3O4@β-CD NPs 10 nm TEM The morphology of Co3O4@β-CD NPs showed well dispersed nanoparticles in the size of 10 nm.
    7457 165 VONP-LPs 25 1.5 nm TEM the particle size distribution of V2O5 NPs in the range of 15–40 nm with average lateral size of 25 � 1.5 nm.
    7464 173 MoO3 NPs 2-4 nm TEM The TEM image in Fig. 1A shows that the MoO3 NPs are well dispersed with an average diameter of 2.0e4.0 nm. The lattice spacing of 0.21 nm in the HRTEM image
    7471 182 T-BiO2–x NSs 150 nm DLS The mean hydrodynamic size of T-BiO2–x NSs is around 150 nm
    7486 200 GeO2 showed besom-like morphology with uniform size (width of ≈100 nm and length of ≈1 µm). the “head of besom” was composed of long strip with width of ≈10 nm (Figure 1c,d).
    7487 201 CuS NPs 7 nm TEM the carboxylic acid-stabilized CuS NPs were synthesized with an average size of approximately 7 nm. 138.62
    7493 209 BSA-RuO2NPs 7 nm TEM As can be seen in Figure 1C, size distribution analysis of 100 random BSA-RuO2NPs by Gaussian fitting, the particle size has been calculated to be ∼7 nm. 710 U/g
    7496 212 MoOx QDs 3.42 nm TEM As depicted in TEM images, the obtained MoOx QDs are highly uniform and monodisperse nanocrystals with the average size about 3.42 nm.
    7520 264 CeO2 microspheres 5.2 μm
    7525 267 CeNZs 12 nm TEM The DSPE-PEG2000 modified CeNZs were well-dispersed in water with a hydrodynamic size of ∼12nm
    7529 271 Co3O4 nanoflowers 360 20 nm TEM
    7538 291 RuTeNRs 14 2 nm TEM
    7537 291 RuTeNRs 130 13 nm TEM As shown in the SEM and TEM images (Fig. 2a and 2b), the calcined sample shows inherited nanorod shape from its precursor, but a slight shrink in size (within 200-400 nm in width and 1.0-2.0 μm in length) is observed due to the decomposition of organic ligand. 44.4
    7550 304 Mn3O4 nanoparticles 50-250 nm SEM The observation indicates that most of nanoparticlesexhibit regular octahedral shape, with the size range of 50–250 nm
    7559 317 2D MnO2 nanoflakes 300*5 nm TEM The lateral dimension and thickness of 2D MnO2 nanoflakes were calculated to be 300 nm and 5 nm, respec
    7570 329 Mn3O4-PEG@C&A 40 nm TEM
    7589 349 ISNzymes 50 20 nm thickness μmol/min U/mg
    7590 349 IONzymes 235 13 nm
    7591 349 ISNzymes 250 40 nm width
    7588 349 ISNzymes 430 80 nm Length μmol/min U/mg
    7611 375 ZnO 10.1 1.8 μm SEM The average size of the bowtie was 10.1 ± 1.8 μm (length) and 2.6 ± 0.9 μm (width, defined as the distance of the two outmost branches at the edge) (Fig. 1ai and aii).
    7616 382 MnO2 NPs
    7652 420 ZnCo2O4
    7662 431 nanoceria 516.3 27.9 nm DLS The average hydrodynamic diameter of NC is 516.3 ± 27.9 nm in ultrapure water and 612.3 ± 19.7 nm in planarian water, with a PDI of 0.49 ± 0.05 and of 0.47 ± 0.05, respectively.
    7669 438 CS-IONzyme 250 nm TEM Three kinds of chitosan (low (50–190 KDa), medium (190–310 KDa), and high (310–375 KDa) molecular weight) functionalized IONzyme (named CS-IONzyme) were spheres of ≈250 nm in diameter, which were a bit bigger than IONzyme
    7673 445 iron(III) oxyhydroxide TEM During fungus-mineral cultivation, transmission electron microscopy (TEM) revealed that the mineral grains (from the initial hematite particles) experienced an 8-fold size reduction, giving rise to a high-density distribution (3,000–6,000 per μm−2; Figure 1A) of ∼3-nm-sized nanoparticles in the aggregates within 48 h. 0.12 0
    7686 449 CNP 34.5 2.3 nm DLS the particle size of CNP and CNP2 averaging 3–5 nm from TEM images (Fig. 1a)
    7687 449 CNPs 49.8 3.8 nm DLS
    7694 460 CeO2–x 10 nm TEM Figure 1a-1 shows the morphology of CeO2–x nanorods synthesized with 5 mol/L NaOH with a diameter of ∼10 nm and a length of 90–180 nm,
    7696 462 CuO NPs 6.8 nm TEM The TEM image shown in Figure 1 A revealed that the CuO NPs consist of spherical particles with a uniform morphology. The size distributions of CuO NPs calculated from the TEM image have been fitted by a Gaussian distribution, and the result revealed CuO NPs with an average diameter of approximately 6.8 nm (Figure 1 B).
    7702 469 V2O5 nanobelts 300 nm TEM As shown in Figure 1A,B, the high-magnification SEM image confirmed the fabrication of smooth and straight nanobelts with widths of 200–400 nm. The TEM image in Figure 1C image shows nanobelts with a mean size of ca. 300 nm in width.
    7704 471 Co2V2O7 particles 250 nm TEM As shown in Figure 1a,b, the prepared Co2V2O7 particles mostly possessed a cubic granular shape with an identical aspect ratios of nearly 1.5:1, with widths of about 250 nm.
    7706 475 Fe3O4-NPs 200 6.9 nm DLS As shown in Figure 1C, the average hydrodynamic diameters of Fe3O4-NPs were 200 ± 6.79 nm, which was in good agreement with the TEM result.
    7711 485 CeO2 NCs 214.85 6.4 nm Others The log-normal function to length histogram reveals mean lengths (x) of 197 ± 13.4 and 214.85 ± 6.4 nm from the TEM and FE-SEM images, respectively.
    7712 485 CeO2 NCs 197 13.4 nm TEM The log-normal function to length histogram reveals mean lengths (x) of 197 ± 13.4 and 214.85 ± 6.4 nm from the TEM and FE-SEM images, respectively.
    7714 486 Mn3O4 NPs 8.9 1.4 nm TEM The synthesized Mn3O4 NPs showed a uniform spherical shape under TEM (Fig. 1), and the average particle size was 8.9 ± 1.4 nm.
    7713 486 Mn3O4 NPs 226.4 6.3 nm DLS The DLS results show that the hydrodynamic particle diameter of Mn3O4 NPs was 226.4 ± 6.3 nm.
    7742 510 Mn3O4 nanoparticles (NPs) c 50-250 nm TEM The morphologies of the as-prepared four shapes of Mn3O4 NPs were observed by TEM. As shown in Fig. S1, the Mn3O4 NPs display octahedral, polyhedral, flower and spinel like shapes. The results show that most of the nanoparticles exhibit regular octahedral shape and the particle size is between 50 nm and 250 nm
    7749 519 MnO2-loaded polymer capsules 129.7 5.1 nm DLS The results presented in Fig. 2d and e show respectively the Gaussian distributions of the hydrodynamic diameter (average size: 129.7 ± 5.1 nm)
    7750 521 Fe3O4 TEM
    7751 521 Fe3O4 XRD The XRD patterns comprising of seven diffraction peaks centered at 2θ angles of 30.6°, 35.98°, 43.74°, 54.04°, 57.54°, 63.22°, and 74.89°
    7757 527 iron oxide nanoparticles (Fe3O4 NPs) 20 nm TEM Both of them showed diameters of about 20 nm in the transmission electron microscopy (TEM)
    7758 528 CuO nanorods (NRs) 15 nm TEM From a high magnification TEM image in Fig. 1. B it is clearly observed that all nanorods have smooth surfaces with average the diameter of 15 nm.
    7768 538 iron alkoxide 2.5 μm TEM the uniform three-dimensional flower-like iron alkoxide with a dimeter of about 2.5 μm was formed by assembly of nanosheets with a thickness about 50 nm 93.13
    7779 548 CeO2 7.8 0.2 nm TEM
    7782 552 MnO2 nanoparticles 64-174 nm DLS the size of MnO2 nanozymes are not estimable from the SEM image, hence the DLS analysis was performed (Fig. S2C). The results indicated that the as-prepared nanozymes had a size distribution over the range of 64–174 nm, with an average size of 109 ± 28 nm.
    7783 553 CoMoO4 nanobelts 50 μm SEM It can be seen in Fig. 1b that CoMoO4 BLs displayed belt-like structures with about 50 μm in length and 2 μm in width, which were prepared using (NH4)6Mo7O4·4H2O as “molybdenum” source.
    7787 557 Magnetic Nanoflowers 23 μm SEM magnetic nanoflower with an average diameter of 23 μm was chosen for characterization and application experiments
    7795 567 Co3O4 NCs 50 TEM, SEM As shown in Fig. 2a and b, the products are uniform nanocube with size of about 50 nm and the surface of the nanocube is smooth
    7796 568 Cu2O nanocubes 100 TEM, SEM SEM image in Fig. 3a and TEM image in Fig. 3b clearly show that the Cu2O has a uniform cube structure, and the size is ca. 100 nm
    7807 579 MnO2 μm TEM, SEM Figure 2 shows that all of the MnO2 samples were assembled to form the same morphology, nanorods. α-MnO2 nanorods were 15–95 nm in diameter and 0.27–1.3 μm in length. β-MnO2 nanorods were 40–130 nm in diameter and 0.64–2.78 μm in length. γ-MnO 2 nanorods were 18–105 nm in diameter and 0.2–0.7 μm in length. 33.700000000000003
    7808 580 WO3−x QDs
    7811 583 FA-PMo4V8 100 nm TEM TEM image (Fig. S1d) demonstrated that the assembled FA-PMo4V8 nanoparticle was colloidal spheres with diameter of 100 nm.
    7816 590 GdW10O36 nanoclusters TEM GdW10O36 NCs had a monodispersed spherical morphology and an ultra-small diameter of about 1~3 nm that exhibited high hydrophilicity and dispersity at a pH of 7.4 (Figure 1B).
    7819 593 CeO2 TEM The resulting CeO2 nanozymes obtained by a simple solvothermal protocol are in highly morphological uniformity and dispersity (Fig. 1a and S1a) with an average size of 31.1 ±3.9 nm (Fig. 1c). The STEM image (Fig. 1b) shows a flower-like morphology assembled by tiny nanoparticles with an average size of 6.1 ± 1.6 nm.
    7824 598 CeO2 NPs
    7828 602 Fe3O4 nanoparticles
    7836 611 CeVO4 TEM The micrographs indicate the formation of monodisperse, polycrystalline nanorods of different sizes (CR1≈50 nm, CR2≈100 nm and CR3≈150 nm)
    7841 618 MoO3−x NDs The typical transmission electron microscopy (TEM) image of the as-obtained supernatant (Figure 1A) showed well-dispersed nanodots with an average diameter of 3.07 ± 0.35 nm (Figure 1B) as calculated from counting 80 particles of the TEM images. The high-resolution TEM (HRTEM) characterization showed the lattice spacings of about 0.231 nm in the crystal structure of the nanodots, which was consistent well with the (224) diffraction planes of MoO3 (JCPDS No. 21-0569). As indicated in the Figure 1C, the atomic force microscope (AFM) image with the height analysis (inset of Figure 1C) confirmed the good mono-dispersibility of the nanodots. The average height was 1.43 ± 0.08 nm,
    7847 625 Ceria NPs 3–4 nm TEM The average diameter of ceria NPs is 3−4 nm (Figure 2A,B) that is measured from the transmission electron microscopy (TEM) image. Meanwhile, the result of dynamic laser scattering (DLS) measurement revealed ceria NPs possessed an average size of ∼4 nm (Figure 2C)
    7858 638 Fe3O4 32 nm TEM
    7861 643 CuO 6.64 nm TEM Average
    7865 647 MoSe2 4.5 nm TEm Average
    7869 653 MnO2 188 nm DLS Average
    7872 656 CeO2 3~4 nm XRD The synthesized CeO2 were uniform in size and the estimated average diameter was between 3 and 4 nm. The small and uniform particle size provides a larger specific surface area and more active sites, leading to superior enhanced performance in electrochemical detection.
    7873 657 iron oxides
    7884 667 nanoceria 3 nm TEM Both TEM images and DLS (images in SI) indicated that the proposed synthetic approach yielded nanoparticles with an average size of 3 nm.
    7891 674 Fe3O4 MNPs 17.7 nm SEM From the SEM images, the average diameter of the synthesized Fe3O4 MNPs was estimated to be ~17.7 nm (Fig. S2b).
    7897 680 Mn3O4 10-100 nm TEM The TEM image of the T. denitrificans-CdS@Mn3O4 system also revealed that the particles were distributed on the bacterial cells and that the diameter of those particles ranged from 10 to 100 nm (Figure 2d), similar to that of T. denitrificans-CdS
    7900 686 nano-MnO2
    7902 688 RuO2 28 nm TEM The nanoparticles aggregate randomly to form almost spherical shape with an average diameter of 28 nm, which is as per the TEM analysis. 64.5
    7912 700 Fe3O4 MCs 350 nm TEM As the reaction time extending to 16 h, solid Fe3O4 PCs transformed into hollow porous (HP) NPs via Ostwald ripening, in which the gradual outward migration and recrystallization occurred, leading to enlarged size (350 nm) of NPs as show in TEM images
    7941 732 Mn0.98Co0.02O2 12 nm SEM An average crystallite size below 12 nm and surface area of 86.14 m2 g−1 were obtained for the nanozyme Mn0.98Co0.02O2. 86.14
    7943 734 ZrO2 NPs The individual ZrO2 NP has a size range from 20 nm to 40 nm, and slight aggregation of the particles can be observed from the TEM images. Fig. 1B shows the dynamic light scattering spectra of the ZrO2 NPs, the hydrodynamic diameters of ZrO2 NPs were in the range from 90 nm to 200 nm, which confirms the slight aggregation.
    7961 749 OV-Mn3O4 NFs 100−130 nm SEM distinct nanoflower by SEM and TEM
    7971 761 MnNS nm TEM MnNS demonstrated an obvious sheet-like morphology with an average lateral size of 150 nm and a thickness of 4.5 nm, which implied a typical 2D structure and enabled MnNS to possess a large surface area and maximum surface active sites, facilitating the high enzyme-like activity.
    7978 772 Fe3O4 294.7 nm TEM
    7980 774 diamagnetic powder 50-100 nm SEM the synthesized nanoparticles with diameters ranging between ca 50 and 100 nm (Fig. 1) formed stable micrometer-sized aggregates [18] Fig. 1. SEM of microwave synthesized magnetite nanoparticles; a section from the original SEM image is presented. The bar corresponds to 1 µm.
    7983 777 CeO2 SEM Hollow CeO2 microspheres were shown to range in size from 1 to 3 µm, with the outer shell composed of smaller CeO2 particles of 20 nm average size (Figure 1). 28.0
    7984 778 ceria@Ce6 124.48 nm DLS The Fig. 2I showed that the average size of CeO2, CeO2@APTES and CeO2@Ce6 was respectively 92.04 nm, 100.37 nm and 124.48 nm.
    7986 778 CeO2@APTES 100.37 nm DLS The Fig. 2I showed that the average size of CeO2, CeO2@APTES and CeO2@Ce6 was respectively 92.04 nm, 100.37 nm and 124.48 nm.
    7985 778 CeO2 92.04 nm DLS The Fig. 2I showed that the average size of CeO2, CeO2@APTES and CeO2@Ce6 was respectively 92.04 nm, 100.37 nm and 124.48 nm.
    7987 779 PMNSs 9 nm DLS acquiring water-dispersible and stable PMNSs (with a hydrodynamic diameter of ≈9 nm) for further biomedical applications
    7998 787 ZnCo-ZIF 230 nm SEM As shown in Fig. S1,† the synthesized ZnCo-ZIF nanocrystals were monodispersed with an average diameter of about 230 nm.
    8015 809 Sm-CeO2 10 nm TEM They were cubes or polyhedral with an average diameter around 10 nm.
    8018 813 TA@VOx NSs 130 nm DLS TA@VOx NSs exhibited a uniform size distribution, with average length and width of about 120 and 60 nm, respectively. The average hydrodynamic diameter of TA@VOx NSs was found to be approximately 130 nm by using dynamic light scattering (DLS) measurements (Figure 1 b), in good agreement with the TEM test results.
    8022 819 CoFe2O4 16 nm TEM Moreover, the TEM image presented in Figure 2D shows that the CoFe2O4 nanozyme exhibited a cubic shape with an average diameter of 16 nm (Figure S4).
    8023 820 Fe3O4 10 nm TEM average hydrodynamic diameter of about 104 and 115 nm for SG-GMNPs and SS-GMNPs, respectively.
    8026 826 FeWOX NSs 15.7 2.4 nm TEM Transmission electron microscopy (TEM) imaging revealed that the obtained FeWOX NSs showed the nanosheet-structure and average size at 15.7 ± 2.4 nm (Figure 1B and Figure S1, Supporting Information). The thickness of the as-obtained nanosheets was determined by atomic force microscopy (AFM) image to be ≈0.34 nm (Figure 1D,E).
    8036 838 C-Mn3O4 NPs 6.12 2.24 nm TEM Transmission electron micrograph (TEM) shows the C-Mn3O4 NPs to be well-dispersed uniform spheres with an average diameter of ≈6.12 ± 2.24 nm.
    8041 844 nanoceria 10 nm TEM TEM image showed the spherical shape of the nanoceria with a size of ~10 nm.
    8050 856 CNP 4 1 nm HR-TEM The CNP were synthesized in the size range of 3-5 nm, as analyzed from the HR-TEM image.
    8057 862 NiMoO4 2.5 0.5 μm SEM The scanning electron microscopy (SEM) images of microflowers CoMoO4 and NiMoO4 are shown in Figures 1A and S1A, respectively. The as-prepared CoMoO4 exhibits uniform flower-like structures with a size of 4–5 μm, whereas NiMoO4 shows a relatively smooth surface with a small size of 2–3 μm. 368.8
    8056 862 CoMoO4 4.5 0.5 μm SEM The scanning electron microscopy (SEM) images of microflowers CoMoO4 and NiMoO4 are shown in Figures 1A and S1A, respectively. The as-prepared CoMoO4 exhibits uniform flower-like structures with a size of 4–5 μm, whereas NiMoO4 shows a relatively smooth surface with a small size of 2–3 μm. 103.6
    8062 867 Fe3O4 8.3 nm TEM
    8063 868 RuO2 2 nm TEM the mean diameter of the RuO2NPs was ∼2 nm, and the hydrodynamic size of RuO2NPs was about 5.4 nm
    8065 870 Co-Al-Ce mixed metal oxide (MMO) 0.31 nm TEM
    8074 879 MnO2-Silk Commercial micro-sized MnO2 (≥99.99% trace metals basis) particles from Sigma-Aldrich
    8089 897 ConFe3−nO4 (n=1–2)
    8090 898 ZnO2/CA-βCD nm SEM Fig. 4 SEM images (Mag. 10kx) and particle size distribution histograms of a ZnO2 and b ZnO2/CA-β-CD
    8094 902 Vanadium oxide quantum dots (VOxQDs) 3.39 nm TEM The average diameter of the VOxQDs was 3.39 ± 0.57nm by statistics of the 100 particles (Fig.1E).
    8099 907 CeNPs 1.7 0.5 nm TEM
    8113 921 g-C3N4/CeO2 200 nm TEM It is clearly noted that CeO2 nanomaterials could display uniformly defined monodisperse hollow nanospheres with a size of about 200 nm in diameter (Fig. 1A), as confirmed by the TEM image displayed in the amplified view (Fig. 1B).
    8115 923 Au–CeO2 125 nm TEM the uniformly dispersed Au–CeO2 JNPs of about 125 nm were obtained (Fig. 1F). The DLS results indicated that the diameter of the Au–CeO2 JNPs is about 171 nm,
    8136 1069 MnO2 nanosheets
    8139 1073 p-Fe3O4 MPs 48.3380
    8142 1076 MnO2-Dox@HFn 10-12 nm TEM
    8153 1086 FeVO4 100 nm SEM width
    8154 1086 FeVO4 120 nm SEM length
    8156 1090 CeO2 2、10 nm TEM TEM images (Figure S1) reveal the presence of well-defined nearly monodisperse nanoparticles with average sizes of 2 and 10 nm, respectively.
    8165 1104 CuMn2O4 30-80 nm SEM
    8166 1105 CuCo2O4 nanorods 0.9-1.5 μm TEM length
    8167 1105 CuCo2O4 nanorods 200-400 nm TEM width
    8170 1108 nanorods 5 nm TEM All around 5 nm as determined from high-resolution transmission electron microscopy (HRTEM) and dynamic light scattering (DLS) (Figure 1a–e). 163 ± 1
    8171 1108 nanoflowers 5 nm TEM All around 5 nm as determined from high-resolution transmission electron microscopy (HRTEM) and dynamic light scattering (DLS) (Figure 1a–e). 143 ± 2
    8172 1108 CeO2 5 nm TEM All around 5 nm as determined from high-resolution transmission electron microscopy (HRTEM) and dynamic light scattering (DLS) (Figure 1a–e).
    8173 1108 nanoparticles 5 nm TEM All around 5 nm as determined from high-resolution transmission electron microscopy (HRTEM) and dynamic light scattering (DLS) (Figure 1a–e). 208 ± 2
    8177 1112 CeO2 SEM As presented in Fig. 1a, the as-prepared CeO2 shows rod-like and porous characteristics with a diameter of ~7 nm and a length of 40~70 nm. 82.5
    8198 1145 C-IONPs 250 nm TEM On the other hand, DLS analysis also revealed uniform hydrodynamic size distribution of the nanoparticles. The hydrodynamic radius of the C-IONPs was found to be 318.4 ± 13.58 nm with a polydispersity of 41.25% ± 6.86 (Figure S4).
    8205 1158 ITO NPs 10.78 1.42 nm XRD The calculated average crystallite size of the synthesized ITO NPs was found to be 10.78 ± 1.42 nm. As can be seen from Figure 1C, the synthesized ITO NPs mainly formed aggregates greater than 50 nm in size. The results show that the hydrodynamic diameters of the present ITO NPs in PBS were less than 8% on the nanoscale, and the main hydrodynamic size of the ITO dispersion was 174.1 ± 14.02 nm.
    8213 1167 Cu2O NPs 195 45 nm TEM The particle size distribution from the TEM analysis is given in Fig. S1a. It shows that the particles exhibited a distribution with the diameter varying from 150 to 240 nm and mainly concentrated on 200 nm. Meanwhile, the NPs prepared using the precursor in a molar ratio of CuCl2 : MgCl2 = 5 : 1, Cu2O-(5 : 1-Mg) NPs, show a BET surface area of 21.32 m2 g−1 and an average pore diameter of 12.01 nm. These results clearly indicate that introduction of Mg2+ ions into the Cu-precursor has an influence on the porous structure evolution of Cu2O NPs. 22.16 The BET surface area and the average pore size of Cu2O-(sole CuCl2) are calculated to be 13.03 m2 g−1 and 7.29 nm. Meanwhile, the NPs prepared using the precursor in a molar ratio of CuCl2 : MgCl2 = 5 : 1, Cu2O-(5 : 1-Mg) NPs, show a BET surface area of 21.32 m2 g−1 and an average pore diameter of 12.01 nm. These results clearly indicate that introduction of Mg2+ ions into the Cu-precursor has an influence on the porous structure evolution of Cu2O NPs.
    8216 1170 IONPs 74 nm DLS An overestimated size (74 nm) of the suspended IONPs was obtained through DLS measurements due to the presence of hydration layers over the NP surface.
    8227 1186 ZnFe2O4 NPs 12.5 4.5 nm TEM The transmission electron microscope (TEM) image displayed that ZnFe2O4 nanoparticles (NPs) achieved good dispersion with diameters between 8 and 17 nm (Fig. 1A), which was consistent with the previous report.
    8246 1220 Bro-MnO2 220.9 nm DLS the results indicated that Bro-MnO2 was formed by the interlaced stacking of many irregular 2D networks with laminated structures, a large surface area and surface wrinkles. Analysis by dynamic light scattering (DLS) revealed that the average diameter was 220.9 nm
    8248 1223 CoFe2O4
    8249 1224 CuCo2O4 microspheres TEM Furthermore, as displayed in Fig. 2b and c, CuCo2O4 microspheres are composed of peasecod-like strips with ca. 100 nm assembled by lots of nanoparticles with ca. 10 nm (Fig. 2d and e); the rough surface with more exposed active sites31 is more conducive to adsorbing more hydrogen peroxide molecules and enhancing catalytic performance during the catalytic reaction in the subsequent experiment. The HRTEM image (the inset of Fig. 2e) reveals that the lattice spacing is 0.24 nm, consistent with the value for the (311) plane of the cubic CuCo2O4 phase.
    8251 1227 CeO2 5 nm TEM CeO2 nanoparticles were around 5 nm in size
    8254 1230 Cu2O 150 nm TEM
    8257 1237 SFO 9.3 nm TEM
    8264 1245 CeO2 80-200 nm TEM The particle size distributions and potentials of the nanovesicles are presented in Figure 2I,J, respectively. The DLS analysis indicated that the nanovesicles ranged between 80 and 200 nm in size
    8266 1249 Fe3O4 200 nm TEM Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) demonstrated that the asprepared Fe3O4 nanozymes with PEG modification have a rough surface with a diameter size of 200 nm (Figure S1).
    8271 1257 Fe3O4 NPs 23 3.7 nm TEM The Fe3O4 nanoparticles were synthesis by the co-precipitation method, and they were around 23 ± 3.7 nm in size as measured by TEM (Figure S2).
    8274 1260 MTex-500 First, we synthesized a composite (designated as TA-GO-FeOOH) consisting of β-FeOOH spheroidal nanorods (average length = 100 ± 10 nm and width = 20 ± 2 nm) in an envelope of graphene oxide (GO) and poly-tannic acid (poly-TA) (ca. 2 nm) via a TA-assisted in-situ crystallization strategy 158.347
    8275 1260 MTex-700 56.464
    8272 1260 β-FeOOH spheroidal nanorods 100 10 nm TEM length(First, we synthesized a composite (designated as TA-GO-FeOOH) consisting of β-FeOOH spheroidal nanorods (average length = 100 ± 10 nm and width = 20 ± 2 nm) in an envelope of graphene oxide (GO) and poly-tannic acid (poly-TA) (ca. 2 nm) via a TA-assisted in-situ crystallization strategy)
    8273 1260 β-FeOOH spheroidal nanorods 20 2 nm TEM Width
    8279 1264 Mn3O4 700-800 nm SEM Figure 1A and B showed the average diameter of the urchin-like Mn3O4 particles which was about 700-800 nm. 198.76
    8301 1295 RSPCO 240 nm TEM Average length
    8319 1310 MnO2 nanosheets 6 nm AFM thickness of approximate
    8320 1311 Metal oxide into the glass composition 250 μm Others diameter lower than 250 μm
    8327 1316 Fe3 O4 NPs 20-30 nm SEM When scanning electron microscopy (SEM) analysis was performed to observe the shape and size of synthesized magnetite nanoparticles, they were found to be spherical and in between 20 and 30 nm in diameter
    8329 1319 MnSiO3 nm TEM TEM image shows an irregular shape of MnSiO3 NPs was obtained and the MnSiO3 colloid was reddish brown (Fig. 2a), which indicated well-dispersed MnSiO3 NPs.
    8335 1327 LaFeO3 4.4 0.3 μm SEM
    8356 1349 Fe3O4 NPs 9 1 nm TEM The pristine Fe3O4 NPs exhibit a spherical shape with a uniform diameter in the range of 8–10 nm.
    8357 1350 MoOx QDs 1.98 nm TEM MoOx QDs with a diameter of 1.98 nm was synthesized by using commercial MoS2 powder as the precursor via a one-pot method according to our previous work (Figure 2A)
    8364 1358 Fe2.5Ti0.5O4 20-30 nm TEM 117.2
    8365 1359 Iron oxide core 6.9 ± 1.7 nm TEM an average diameter of the iron oxide core
    8366 1359 MIONzyme colloid 33.3 3.9 nm DLS hydrodynamic diameter μmol/min U/mg
    8381 1370 CeO2 3-5 nm TEM 73.9
    8387 1374 IONPs 12 nm TEM IONPs with diameters of ~12 nm were prepared by a coprecipitation method and were innovatively investigated as the sole catalyst for hydrogel nanoparticle preparation instead of the natural enzyme HRP.
    8395 1379 ZnO 50 nm SEM The average size of individual nanoparticles is approximately 50 nm, however there is a large agglomeration of nanoparticles; size of aggregates around 1000 nm.
    8399 1388 nano-PrO1.8 100-550 nm DLS The results show that the particle size of the material is approximately normal distribution, the particle size of the material is between 100 and 550 nm, and the range of particle size distribution at 292.7 nm is the largest.
    8402 1390 PbWO4 30-40 nm SEM The average diameter of one-dimensional lamellar nanostructures was in the range of 30 to 40 nm. 86.225
    8404 1392 MnxCo1-xO 1.5-2 μm SEM 31.4
    8405 1394 CNP 5 nm TEM The dry nanoparticle size from HRTEM was measured as ∼5 nm
    8419 1409 CeO2 44625 nm TEM Average size
    8423 1413 MNPs <50 nm TEM uniform size
    8434 1429 MnO2 150 nm TEM The H-MnO2 NPs are clearly shown to have the expected hollow feature with a diameter of 150 nm
    8443 1440 Fe3O4 mesocrystals 350 nm TEM The average 30.5
    8445 1441 rod-shaped CeO2 10 nm TEM Diameter 46 μmol/min U/mg
    8446 1441 rod-shaped CeO2 200 nm TEM Length 95 μmol/min U/mg
    8447 1441 CeO2 cubes 20-50 nm TEM lateral length 29 μmol/min U/mg
    8444 1441 CeO2 octahedron 15-20 nm TEM Fig. 1a shows the CeO2 octahedron with a narrow size distribution between 15 and 20 nm
    8449 1446 d-MnO2 272.6 20 nm DLS the hydrodynamic radius of MnO2 was approximately 272.6 20 nm at pH 3.73
    8454 1455 IrOx TEM The as-prepared nanoparticles show a spherical morphology with diameter of ~24.05±0.29 nm (Figure 1b). They were composed by the accumulation of many small granules (2.28±0.4 nm) formed at the initial heating period (Figure S2).
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