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Автор: Grafiati
Опубліковано: 10 грудня 2022
Оновлено: 28 січня 2023

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1

Sajjad, Muhammad, and Peter Feng. "Electron microscopic characterization of multi-layer boron nitride nanosheets." MRS Proceedings 1549 (2013): 85–90. http://dx.doi.org/10.1557/opl.2013.859.

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AbstractWe report on the direct synthesis of multi-layer boron nitride nanosheets (BNNSs) and their electron microscopic characterization. The synthesis process is carried out by irradiating hexagonal boron nitride (h-BN) target using short laser pulses. Scanning electron microscopy showed large area (≈50×50 μm2) flat layers of BNNSs transparent to the electron beam. Low magnification transmission electron microscope (TEM) is used to characterize different areas of nanosheets. TEM revealed that each individual nanosheet is composed of several layers. High resolution TEM (HRTEM) measurements confirmed the layered structure. HRTEM analysis of the edge of a nanosheet showed 10 layers from which we obtained the thickness (3.3nm) of an individual nanosheet. Selected area electron diffraction pattern indicated polycrystalline structure of nanosheets. Raman spectroscopy clearly identified E2g vibrational mode related to h-BN.
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2

Alshehri, Mansoor H. "Computational Study on the Interaction and Moving of ssDNA through Nanosheets." Crystals 11, no. 9 (August 25, 2021): 1019. http://dx.doi.org/10.3390/cryst11091019.

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The adsorption characteristics and moving through nanopores of a single-stranded deoxyribonucleic acid (ssDNA) molecule on monolayers, such ashexagonal boron nitride and graphene nanosheets, were studied using the continuous approach with the 6–12 Lennard–Jones potential function. The ssDNA molecule is assumed to be at a distance l above the sheet, and the relation between the minimum energy location and the perpendicular distance of the ssDNA molecule from the nanosheet surface is found. In addition, by assuming that there is a hole in the surface of the nanosheet as a pore, the interaction energies for the ssDNA molecule moving through the pore in the surface of the nanosheet (used to calculate the radius p of the hole) are obtained, which provides the minimum energies. Furthermore, a comparative study with graphene was performed in order to compare with hexagonal boron nitride nanosheets. Our results indicate that the binding energies of the ssDNA onto graphene and hexagonal boron nitride nanosheets are approximately 15.488 and 17.582 (kcal/mol), corresponding to perpendicular distances of l=20.271 and l=20.231 Å, respectively. In addition, we observe that the ssDNA molecule passes through graphene and hexagonal boron nitride nanopores when the gap radius p>7.5 Å. Our results provide critical insights to understand and develop the interactions and translocation of DNA molecules with and through nanosheets.
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3

Lee, Jae-Kap, Jin-Gyu Kim, K. P. S. S. Hembram, Seunggun Yu, and Sang-Gil Lee. "AB-stacked nanosheet-based hexagonal boron nitride." Acta Crystallographica Section B Structural Science, Crystal Engineering and Materials 77, no. 2 (March 17, 2021): 260–65. http://dx.doi.org/10.1107/s2052520621000317.

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Hexagonal boron nitride (h-BN) has been generally interpreted as having an AA stacking sequence. Evidence is presented in this article indicating that typical commercial h-BN platelets (∼10–500 nm in thickness) exhibit stacks of parallel nanosheets (∼10 nm in thickness) predominantly in the AB sequence. The AB-stacked nanosheet occurs as a metastable phase of h-BN resulting from the preferred texture and lateral growth of armchair (110) planes. It appears as an independent nanosheet or unit for h-BN platelets. The analysis is supported by simulation of thin AB films (2–20 layers), which explains the unique X-ray diffraction pattern of h-BN. With this analysis and the role of pressure in commercial high-pressure high-temperature sintering (driving nucleation and parallelizing the in-plane crystalline growth of the nuclei), a growth mechanism is proposed for 2D h-BN (on a substrate) as `substrate-induced 2D growth', where the substrate plays the role of pressure.
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4

Zhou, Shuaishuai, Tongle Xu, Fang Jiang, Na Song, Liyi Shi, and Peng Ding. "High thermal conductivity property of polyamide-imide/boron nitride composite films by doping boron nitride quantum dots." Journal of Materials Chemistry C 7, no. 44 (2019): 13896–903. http://dx.doi.org/10.1039/c9tc04381k.

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In this study, we report a flexible polyamide-imide (PAI)/boron nitride nanosheet (BNNS) composite film with improved thermal conductivity by doping boron nitride quantum dots (BNQDs) using an evaporation-induced self-assembly method.
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5

Alshehri, Mansoor H. "Investigation of Interaction of Noble Metals (Cu, Ag, Au, Pt and Ir) with Nanosheets." Micromachines 12, no. 8 (July 29, 2021): 906. http://dx.doi.org/10.3390/mi12080906.

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Two-dimensional nanomaterials, such as graphene and hexagonal boron nitride nanosheets, have attracted tremendous interest in the research community and as a starting point for the development of nanotechnology. Using classical applied mathematical modeling, we derive explicit analytical expressions to determine the binding energies of noble metals, including copper, silver, gold, platinum and iridium (Cu, Ag, Au, Pt and Ir) atoms, on graphene and hexagonal boron nitride nanosheets. We adopt the 6–12 Lennard–Jones potential function, together with the continuous approach, to determine the preferred minimum energy position of an offset metal atom above the surface of the graphene and hexagonal boron nitride nanosheets. The main results of this study are analytical expressions of the interaction energies, which we then utilize to report the mechanism of adsorption of the metal atoms on graphene and hexagonal boron nitride surfaces. The results show that the minimum binding energy occured when Cu, Ag, Au, Pt and Ir were set at perpendicular distances in the region from 3.302 Å to 3.683 Å above the nanosheet surface, which correspond to adsorption energies in the region ranging from 0.842 to 2.978 (kcal/mol). Our results might assist in providing information on the interaction energies between the metal atoms and the two-dimensional nanomaterials.
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6

Zeng, Xiaoliang, Lei Ye, Rong Sun, Jianbin Xu, and Ching-Ping Wong. "Observation of viscoelasticity in boron nitride nanosheet aerogel." Physical Chemistry Chemical Physics 17, no. 26 (2015): 16709–14. http://dx.doi.org/10.1039/c5cp02192h.

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7

Heidari, Hassan, Sadegh Afshari, and Esmaeil Habibi. "Sensing properties of pristine, Al-doped, and defected boron nitride nanosheet toward mercaptans: a first-principles study." RSC Advances 5, no. 114 (2015): 94201–9. http://dx.doi.org/10.1039/c5ra09923d.

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8

Liu, Fei, Yaqi Ren, and Xixi Ji. "Nanosheet-Structured Boron Carbon Nitride Spheres as Stable Electrocatalyst Support for Oxygen Reduction Reaction." International Journal of Materials Science and Engineering 5, no. 4 (2017): 123–32. http://dx.doi.org/10.17706/ijmse.2017.5.4.123-132.

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9

Wen, Xin, Yongcheng Wang, and Jingxiang Zhao. "Negatively charged boron nitride nanosheets as a potential metal-free electrocatalyst for the oxygen reduction reaction: a computational study." New Journal of Chemistry 42, no. 15 (2018): 12838–44. http://dx.doi.org/10.1039/c8nj01228h.

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10

Pan, An, Yongjun Chen, and Jianbao Li. "An effective route for the synthesis of boron nitride micro-nano structures and the growth mechanism." CrystEngComm 17, no. 5 (2015): 1098–105. http://dx.doi.org/10.1039/c4ce01756k.

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11

Morishita, Takuya, and Naoko Takahashi. "Highly thermally conductive and electrically insulating polymer nanocomposites with boron nitride nanosheet/ionic liquid complexes." RSC Advances 7, no. 58 (2017): 36450–59. http://dx.doi.org/10.1039/c7ra06691k.

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12

Tang, Shaobin, Xunhui Zhou, Tianyong Liu, Shiyong Zhang, Tongtong Yang, Yi Luo, Edward Sharman, and Jun Jiang. "Single nickel atom supported on hybridized graphene–boron nitride nanosheet as a highly active bi-functional electrocatalyst for hydrogen and oxygen evolution reactions." Journal of Materials Chemistry A 7, no. 46 (2019): 26261–65. http://dx.doi.org/10.1039/c9ta10500j.

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13

Kim, Kiho, Hyunwoo Oh, and Jooheon Kim. "Fabrication of covalently linked exfoliated boron nitride nanosheet/multi-walled carbon nanotube hybrid particles for thermal conductive composite materials." RSC Advances 8, no. 58 (2018): 33506–15. http://dx.doi.org/10.1039/c8ra05620j.

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14

Pakdel, Amir, Chunyi Zhi, Yoshio Bando, Tomonobu Nakayama, and Dmitri Golberg. "Boron Nitride Nanosheet Coatings with Controllable Water Repellency." ACS Nano 5, no. 8 (July 22, 2011): 6507–15. http://dx.doi.org/10.1021/nn201838w.

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15

Zhang, Yonghui, Chun Chan, Zhen Li, Jiale Ma, Qiangqiang Meng, Chunyi Zhi, Hongyan Sun, and Jun Fan. "Nanotoxicity of Boron Nitride Nanosheet to Bacterial Membranes." Langmuir 35, no. 18 (April 8, 2019): 6179–87. http://dx.doi.org/10.1021/acs.langmuir.9b00025.

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16

Yin, Chuan-Gen, Yu Ma, Zhong-Jie Liu, Jin-Chen Fan, Peng-Hui Shi, Qun-Jie Xu, and Yu-Lin Min. "Multifunctional boron nitride nanosheet/polymer composite nanofiber membranes." Polymer 162 (January 2019): 100–107. http://dx.doi.org/10.1016/j.polymer.2018.12.038.

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17

Hou, Xiao, Mengjie Wang, Li Fu, Yapeng Chen, Nan Jiang, Cheng-Te Lin, Zhongwei Wang, and Jinhong Yu. "Boron nitride nanosheet nanofluids for enhanced thermal conductivity." Nanoscale 10, no. 27 (2018): 13004–10. http://dx.doi.org/10.1039/c8nr00651b.

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18

Li, Xinyi, Song Chen, Qian Liu, Yonglan Luo, and Xuping Sun. "Correction: Hexagonal boron nitride nanosheet as an effective nanoquencher for the fluorescence detection of microRNA." Chemical Communications 57, no. 68 (2021): 8520. http://dx.doi.org/10.1039/d1cc90289j.

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19

Xu, Yancui, Taotao Li, Weiwei Xu, Chaowei Li, Songfeng E, Liangjie Wang, Xiaoyang Long, Yu Bai, Lai Xu, and Yagang Yao. "Scalable production of high-quality boron nitride nanosheets via a recyclable salt-templating method." Green Chemistry 21, no. 24 (2019): 6746–53. http://dx.doi.org/10.1039/c9gc03285a.

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20

Fu, Li, Guoxin Chen, Nan Jiang, Jinhong Yu, Cheng-Te Lin, and Aimin Yu. "In situ growth of metal nanoparticles on boron nitride nanosheets as highly efficient catalysts." Journal of Materials Chemistry A 4, no. 48 (2016): 19107–15. http://dx.doi.org/10.1039/c6ta06409d.

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21

Wang, Lei, Yang Wang, Chang-Wu Zhang, Jing Wen, Xuefei Weng, and Lei Shi. "A boron nitride nanosheet-supported Pt/Cu cluster as a high-efficiency catalyst for propane dehydrogenation." Catalysis Science & Technology 10, no. 5 (2020): 1248–55. http://dx.doi.org/10.1039/c9cy02313e.

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Анотація:
Here, we report a great promotion in platinum utilization efficiency and catalytic performance for the dehydrogenation of propane using a hexagonal boron nitride nanosheet-supported Pt/Cu cluster catalyst.
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22

Zhang, Baoguo, Yongzhong Wu, Lei Zhang, Qin Huo, Haixiao Hu, Fukun Ma, Mingzhi Yang, Dong Shi, Yongliang Shao, and Xiaopeng Hao. "Growth of high-quality GaN crystals on a BCN nanosheet-coated substrate by hydride vapor phase epitaxy." CrystEngComm 21, no. 8 (2019): 1302–8. http://dx.doi.org/10.1039/c8ce01921e.

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23

Li, Xinyi, Song Chen, Qian Liu, Yonglan Luo, and Xuping Sun. "Hexagonal boron nitride nanosheet as an effective nanoquencher for the fluorescence detection of microRNA." Chemical Communications 57, no. 65 (2021): 8039–42. http://dx.doi.org/10.1039/d1cc03011f.

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Hexagonal boron nitride nanosheet acts as an effective nanoquencher for fluorescence detection of biocompatible microRNA, capable of achieving a detection limit as low as 2.39 nM with rapid response and high specificity.
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24

Xue, Ye, and Xiao Hu. "Electrospun Silk-Boron Nitride Nanofibers with Tunable Structure and Properties." Polymers 12, no. 5 (May 11, 2020): 1093. http://dx.doi.org/10.3390/polym12051093.

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In this study, hexagonal boron nitride (h-BN) nanosheets and Bombyx mori silk fibroin (SF) proteins were combined and electrospun into BNSF nanofibers with different ratios. It was found that the surface morphology and crosslinking density of the nanofibers can be tuned through the mixing ratios. Fourier transform infrared spectroscopy study showed that pure SF electrospun fibers were dominated by random coils and they gradually became α-helical structures with increasing h-BN nanosheet content, which indicates that the structure of the nanofiber material is tunable. Thermal stability of electrospun BNSF nanofibers were largely improved by the good thermal stability of BN, and the strong interactions between BN and SF molecules were revealed by temperature modulated differential scanning calorimetry (TMDSC). With the addition of BN, the boundary water content also decreased, which may be due to the high hydrophobicity of BN. These results indicate that silk-based BN composite nanofibers can be potentially used in biomedical fields or green environmental research.
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25

Bosi, Matteo. "Growth and synthesis of mono and few-layers transition metal dichalcogenides by vapour techniques: a review." RSC Advances 5, no. 92 (2015): 75500–75518. http://dx.doi.org/10.1039/c5ra09356b.

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Nanosheet materials such as graphene, boron nitride and transition metal dichalcogenides have gathered attention in recent years thanks to their properties and promises for future technology, energy generation and post-CMOS device concepts.
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26

Vijayaraghavan, Venkatesh, and Liangchi Zhang. "Tensile and Interfacial Loading Characteristics of Boron Nitride-Carbon Nanosheet Reinforced Polymer Nanocomposites." Polymers 11, no. 6 (June 21, 2019): 1075. http://dx.doi.org/10.3390/polym11061075.

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The discovery of hybrid boron nitride–carbon (BN–C) nanostructures has triggered enormous research interest in the design and fabrication of new generation nanocomposites. The robust design of these nanocomposites for target applications requires their mechanical strength to be characterized with a wide range of factors. This article presents a comprehensive study, with the aid of molecular dynamics analysis, of the tensile loading mechanics of BN–C nanosheet reinforced polyethylene (PE) nanocomposites. It is observed that the geometry and lattice arrangement of the BN–C nanosheet influences the tensile loading characteristics of the nanocomposites. Furthermore, defects in the nanosheet can severely impact the tensile loading resistance, the extent of which is determined by the defect’s location. This study also found that the tensile loading resistance of nanocomposites tends to weaken at elevated temperatures. The interfacial mechanics of the BN–C nanocomposites are also investigated. This analysis revealed a strong dependency with the carbon concentration in the BN–C nanosheet.
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27

Bando, Yoshio. "Boron Nitride Nanotube/nanosheet for Energy and Environmental Applications." Video Proceedings of Advanced Materials 1, no. 1 (November 1, 2020): 2020–0837. http://dx.doi.org/10.5185/vpoam.2020.0837.

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28

Qin, Si, Dan Liu, Ying Chen, Cheng Chen, Guang Wang, Jiemin Wang, Joselito M. Razal, and Weiwei Lei. "Nanofluidic electric generators constructed from boron nitride nanosheet membranes." Nano Energy 47 (May 2018): 368–73. http://dx.doi.org/10.1016/j.nanoen.2018.03.030.

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29

Low, Ze-Xian, Jing Ji, David Blumenstock, Yong-Min Chew, Daniel Wolverson, and Davide Mattia. "Fouling resistant 2D boron nitride nanosheet – PES nanofiltration membranes." Journal of Membrane Science 563 (October 2018): 949–56. http://dx.doi.org/10.1016/j.memsci.2018.07.003.

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30

Moraes, Ana C. M., Woo Jin Hyun, Jung‐Woo T. Seo, Julia R. Downing, Jin‐Myoung Lim, and Mark C. Hersam. "Ion‐Conductive, Viscosity‐Tunable Hexagonal Boron Nitride Nanosheet Inks." Advanced Functional Materials 29, no. 39 (August 2019): 1902245. http://dx.doi.org/10.1002/adfm.201902245.

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31

Li, Wei, Huan Yang, Shuaifeng Chen, Qing Chen, Lijie Luo, Jianbao Li, Yongjun Chen, and Changjiu Li. "Temperature-Dependent Morphology Evolution of Boron Nitride and Boron Carbonitride Nanostructures." Journal of Nanomaterials 2019 (March 6, 2019): 1–11. http://dx.doi.org/10.1155/2019/3572317.

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Анотація:
Boron nitride (BN) and boron carbonitride (BCN) nanostructures with versatile morphology were synthesized at different temperatures. The morphologies such as smooth microspheres, nanoflake-decorated microspheres, solid nanowires, hollow nanotubes (bamboo-like nanotubes, quasi-cylindrical nanotubes, and cylindrical nanotubes), and nanosheet-assembled microwires have been observed. Systematic investigation showed that the reaction temperature was responsible for the versatile morphologies through influencing the guiding effect of catalyst alloy droplet and the diffusion rates of growth species. The diffusion rate differences between surface diffusion (along the surface of the droplet) and bulk diffusion (through the bulk of the droplet) at different reaction temperatures were suggested to affect the final structure of the BN and BCN nanostructures.
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32

Zheng, Xuewen, Haifeng Cong, Ting Yang, Kemeng Ji, Chengyang Wang, and Mingming Chen. "High-efficiency 2D nanosheet exfoliation by a solid suspension-improving method." Nanotechnology 33, no. 18 (February 10, 2022): 185602. http://dx.doi.org/10.1088/1361-6528/ac4b7c.

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Abstract Two-dimensional (2D) materials with mono or few layers have wide application prospects, including electronic, optoelectronic, and interface functional coatings in addition to energy conversion and storage applications. However, the exfoliation of such materials is still challenging due to their low yield, high cost, and poor ecological safety in preparation. Herein, a safe and efficient solid suspension-improving method was proposed to exfoliate hexagonal boron nitride nanosheets (hBNNSs) in a large yield. The method entails adding a permeation barrier layer in the solvothermal kettle, thus prolonging the contact time between the solvent and hexagonal boron nitride (hBN) nanosheet and improving the stripping efficiency without the need for mechanical agitation. In addition, the proposed method selectively utilizes a matching solvent that can reduce the stripping energy of the material and employs a high-temperature steam shearing process. Compared with other methods, the exfoliating yield of hBNNSs is up to 42.3% at 150 °C for 12 h, and the strategy is applicable to other 2D materials. In application, the ionic conductivity of a PEO/hBNNSs composite electrolytes reached 2.18 × 10−4 S cm−1 at 60 °C. Overall, a versatile and effective method for stripping 2D materials in addition to a new safe energy management strategy were provided.
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33

Nan, Yang, Dan Tan, Junqi Zhao, Morten Willatzen, and Zhong Lin Wang. "Shape- and size dependent piezoelectric properties of monolayer hexagonal boron nitride nanosheets." Nanoscale Advances 2, no. 1 (2020): 470–77. http://dx.doi.org/10.1039/c9na00643e.

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34

Zhang, He-xin, Byeong-Gwang Shin, Dong-Eun Lee, and Keun-Byoung Yoon. "Preparation of PP/2D-Nanosheet Composites Using MoS2/MgCl2- and BN/MgCl2-Bisupported Ziegler–Natta Catalysts." Catalysts 10, no. 6 (May 27, 2020): 596. http://dx.doi.org/10.3390/catal10060596.

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Анотація:
Polypropylene/molybdenum disulfied (PP/MoS2) and Polypropylene/hexagonal boron nitride (PP/hBN) nanocomposites with varying concentration (0–6 wt %) were fabricated via in situ polymerization using two-dimensional (2D)-nanosheet/MgCl2-supported Ti-based Ziegler–Natta catalysts, which was prepared through a novel coagglomeration method. For catalyst preparation and interfacial interaction, MoS2 and hBN were modified with octadecylamine (ODA) and octyltriethoxysilane (OTES), respectively. Compared with those of pristine PP, thermal stability of composites was 70 °C higher and also tensile strength and Young’s modulus of the composites were up to 35% and 60% higher (even at small filler contents), respectively. The alkyl-modified 2D nanofillers were characterized by strong interfacial interactions between the nanofiller and the polymer matrix. The coagglomeration method employed in this work allows easy introduction and content manipulation of various 2D-nanosheets for the preparation of 2D-nanosheet/MgCl2-supported Ti-based Ziegler–Natta catalysts.
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35

Li, Yangdi, Vincent Garnier, Philippe Steyer, Catherine Journet, and Bérangère Toury. "Millimeter-Scale Hexagonal Boron Nitride Single Crystals for Nanosheet Generation." ACS Applied Nano Materials 3, no. 2 (February 6, 2020): 1508–15. http://dx.doi.org/10.1021/acsanm.9b02315.

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36

Qu, Wenyang, Soumendu Bagchi, Xiaoming Chen, Huck Beng Chew, and Changhong Ke. "Bending and interlayer shear moduli of ultrathin boron nitride nanosheet." Journal of Physics D: Applied Physics 52, no. 46 (August 29, 2019): 465301. http://dx.doi.org/10.1088/1361-6463/ab3953.

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37

Habib, Touseef, Dinesh Sundaravadivelu Devarajan, Fardin Khabaz, Dorsa Parviz, Thomas C. Achee, Rajesh Khare, and Micah J. Green. "Cosolvents as Liquid Surfactants for Boron Nitride Nanosheet (BNNS) Dispersions." Langmuir 32, no. 44 (October 27, 2016): 11591–99. http://dx.doi.org/10.1021/acs.langmuir.6b02611.

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38

Li, Taotao, Liangjie Wang, Kai Zhang, Yancui Xu, Xiaoyang Long, Shoujian Gao, Ru Li, and Yagang Yao. "Freestanding Boron Nitride Nanosheet Films for Ultrafast Oil/Water Separation." Small 12, no. 36 (August 11, 2016): 4960–65. http://dx.doi.org/10.1002/smll.201601298.

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39

Feng, Xiao-Qin, Hong-Xia Lu, Jian-Ming Jia, and Chang-Shun Wang. "Electronic and magnetic properties of BN nanosheet superlattices: First-principles calculations." International Journal of Modern Physics B 32, no. 31 (December 20, 2018): 1850348. http://dx.doi.org/10.1142/s0217979218503484.

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Анотація:
Systematic ab initio calculations reveal that the electronic and magnetic properties are modified by superlattices of zigzag and armchair Boron nitride nanosheet (BNNS). Superlattices are constructed by partially hydrogenated B and N atoms of BNNS. The results show that only no more than half N atoms hydrogenated superlattices are antiferromagnetic. The electronic properties of zigzag BN nanosheet superlattices depend on the degree of hydrogenation of N atoms sensitively. As a result, changing the degree of hydrogenation of N atoms results in the transition from semiconductor to metal.
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40

Rouhi, S., R. Ansari, and A. Shahnazari. "Vibrational characteristics of single-layered boron nitride nanosheet/single-walled boron nitride nanotube junctions using finite element modeling." Materials Research Express 3, no. 12 (December 22, 2016): 125027. http://dx.doi.org/10.1088/2053-1591/aa50bd.

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41

Roy, Dipayan, Karamjyoti Panigrahi, Bikram K. Das, Uday K. Ghorui, Souvik Bhattacharjee, Madhupriya Samanta, Sourav Sarkar, and Kalyan K. Chattopadhyay. "Boron vacancy: a strategy to boost the oxygen reduction reaction of hexagonal boron nitride nanosheet in hBN–MoS2 heterostructure." Nanoscale Advances 3, no. 16 (2021): 4739–49. http://dx.doi.org/10.1039/d1na00304f.

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42

Qin, Hongfa, Yingjing Liang, and Jianzhang Huang. "Size and temperature effect of Young’s modulus of boron nitride nanosheet." Journal of Physics: Condensed Matter 32, no. 3 (October 22, 2019): 035302. http://dx.doi.org/10.1088/1361-648x/ab49b0.

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43

Cai, Qiran, Srikanth Mateti, Kenji Watanabe, Takashi Taniguchi, Shaoming Huang, Ying Chen, and Lu Hua Li. "Boron Nitride Nanosheet-Veiled Gold Nanoparticles for Surface-Enhanced Raman Scattering." ACS Applied Materials & Interfaces 8, no. 24 (June 14, 2016): 15630–36. http://dx.doi.org/10.1021/acsami.6b04320.

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44

Ge, Xin, Jiangyun Zhang, Guoqing Zhang, Weijie Liang, Jinsheng Lu, and Jianfang Ge. "Low Melting-Point Alloy–Boron Nitride Nanosheet Composites for Thermal Management." ACS Applied Nano Materials 3, no. 4 (April 2, 2020): 3494–502. http://dx.doi.org/10.1021/acsanm.0c00223.

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45

Guo, Yufeng, and Wanlin Guo. "Magnetism in Oxygen-Functionalized Hexagonal Boron Nitride Nanosheet on Copper Substrate." Journal of Physical Chemistry C 119, no. 1 (December 24, 2014): 873–78. http://dx.doi.org/10.1021/jp5122799.

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46

Zhang, Ya, Huitong Du, Yongjun Ma, Lei Ji, Haoran Guo, Ziqi Tian, Hongyu Chen, et al. "Hexagonal boron nitride nanosheet for effective ambient N2 fixation to NH3." Nano Research 12, no. 4 (March 7, 2019): 919–24. http://dx.doi.org/10.1007/s12274-019-2323-x.

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47

Islam, Shariful, Mohammad Tanvir Ahmed, and Farid Ahmed. "DETECTION OF GLYCINE AND SEROTONIN NEUROTRANSMITTERS BY HEXAGONAL BORON NITRIDE 2-D NANOSHEET." International Journal of Advanced Research 10, no. 06 (June 30, 2022): 368–74. http://dx.doi.org/10.21474/ijar01/14897.

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Анотація:
Neurotransmitters, called as chemical messengers, play a significant role in human body by transmitting message or signal between neurons or neurons to muscles, and their disorder badly affects the human body. In this study we have analyzed the sensing capability ofhexagonal boron nitridenanosheet (BNNS), which is of great interest because of their remarkable physical and chemical properties, to detect several neurotransmitters like glycineand serotonin. Structuraland electronic properties of the materials have been calculated using density functional theory analysis by Gaussian09 package. A significant change has been observed inhexagonal boron nitridesheet when neurotransmitters come in contact with this. This study will be helpful for the detection of the chemical messengers in human body.
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48

Li, Liping, Kun Dai, Jiyuan Li, Yaxin Shi, Zizhu Zhang, Tong Liu, Jun Xie, Ruiping Zhang, and Zhibo Liu. "A Boron-10 nitride nanosheet for combinational boron neutron capture therapy and chemotherapy of tumor." Biomaterials 268 (January 2021): 120587. http://dx.doi.org/10.1016/j.biomaterials.2020.120587.

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49

Brljak, Nermina, Atul D. Parab, Rahul Rao, Joseph M. Slocik, Rajesh R. Naik, Marc R. Knecht, and Tiffany R. Walsh. "Material composition and peptide sequence affects biomolecule affinity to and selectivity for h-boron nitride and graphene." Chemical Communications 56, no. 62 (2020): 8834–37. http://dx.doi.org/10.1039/d0cc02635b.

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Huang, Caijin, Cheng Chen, Xinxin Ye, Weiqing Ye, Jinli Hu, Chao Xu, and Xiaoqing Qiu. "Stable colloidal boron nitride nanosheet dispersion and its potential application in catalysis." Journal of Materials Chemistry A 1, no. 39 (2013): 12192. http://dx.doi.org/10.1039/c3ta12231j.

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