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Journal articles on the topic 'Nanojunction'

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Author: Grafiati
Published: 10 March 2023

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1

Xu, Xiao Yong, Zhong He Wen, Xian Zhong Wang, and Yun Xiang. "Preparation and Characterization on Self-Catalytic of SnO2 Nanowire Junctions." Advanced Materials Research 148-149 (October 2010): 916–19. http://dx.doi.org/10.4028/www.scientific.net/amr.148-149.916.

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Multiple branched SnO2 nanowire junctions have been synthesized by thermal evaporation of SnO powder. Their nanostructures were studied by transmission electron microscopy and field emission scanning electron microcopy. It was observed that Sn nanoparticles generated from decomposition of the SnO powder acted as self-catalysts to control the SnO2 nanojunction growth. Orthorhombic SnO2 was found as a dominate phase in nanojunction growth instead of rutile structure; The branches and stems of nanojunctions were found to be an epitaxial growth by electron diffraction analysis and high-resolution electron microscopy observation. The growth directions of the branched SnO2 nanojunctions went along the orthorhombic [110] and [1—,10]. A self-catalytic vapor–liquid–solid growth mechanism is proposed to describe the growth process of the branched SnO2 nanowire junctions. Introduction
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2

Hiraoka, Ryoichi, Chun-Liang Lin, Kotaro Nakamura, Ryo Nagao, Maki Kawai, Ryuichi Arafune, and Noriaki Takagi. "Transport characteristics of a silicene nanoribbon on Ag(110)." Beilstein Journal of Nanotechnology 8 (August 16, 2017): 1699–704. http://dx.doi.org/10.3762/bjnano.8.170.

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We present the transport characteristics of individual silicene nanoribbons (SiNRs) grown on Ag(110). By lifting up a single SiNR with a low-temperature scanning tunneling microscope tip, a nanojunction consisting of tip, SiNR and Ag is fabricated. In the differential conductance spectra of the nanojunctions fabricated by this methodology, a peak appears at the Fermi level which is not observed in the spectra measured either for the SiNRs before being lifted up or the clean Ag substrate. We discuss the origin of the peak as it relates to the SiNR.
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3

Bourahla, Boualem, and Ouahiba Nafa. "Magnons Heat Transfer and Magnons Scattering in Magnetic Sandwich Lattices: Application to Fe/Gd(5)/Fe System." SPIN 06, no. 03 (September 2016): 1650007. http://dx.doi.org/10.1142/s2010324716500077.

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A model calculation is presented for the coherent magnon transmission and thermal transport at ferromagnetic nanojunction boundaries. The system consists of a Gd ultrathin film sandwiched between two Fe semi-infinite ferromagnetically ordered crystals. The dynamic of the system is analyzed using the equations of motion for the spin precession amplitudes on the lattice sites, valid for the range of temperatures of interest. The coherent transmission and reflection cross sections at the nanojunction boundary are calculated using the matching method. These calculations are presented for arbitrary directions on the boundary, for all accessible frequencies in the propagating bands, at variable temperatures and for a given thicknesses of the ultrathin nanojunction, with no externally applied magnetic field. The model is applied in particular to the Fe/Gd(5)/Fe system with a ferromagnetic Gd nanojunction. Our model yields the total integrated coherent thermal conductivity due to coherent magnons transmission via the sandwiched five Gd spin layers of the nanojunction. It elucidates, in particular, the dependence of the coherent magnons transmission and thermal transport in relation to the spatially inhomogeneous magnetic order of the atomic planes of the nanojunction for a given thickness.
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4

Su, Yiping, Zhicheng Zhao, Shun Li, Fei Liu, and Zuotai Zhang. "Rational design of a novel quaternary ZnO@ZnS/Ag@Ag2S nanojunction system for enhanced photocatalytic H2 production." Inorganic Chemistry Frontiers 5, no. 12 (2018): 3074–81. http://dx.doi.org/10.1039/c8qi00828k.

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5

Ngoc, Trinh Minh, Nguyen Van Duy, Chu Manh Hung, Nguyen Duc Hoa, Nguyen Ngoc Trung, Hugo Nguyen, and Nguyen Van Hieu. "Ultralow power consumption gas sensor based on a self-heated nanojunction of SnO2 nanowires." RSC Advances 8, no. 63 (2018): 36323–30. http://dx.doi.org/10.1039/c8ra06061d.

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6

Liu, Fuli, Lizhu Song, Shuxin Ouyang, and Hua Xu. "Cu-Based mixed metal oxides for an efficient photothermal catalysis of the water-gas shift reaction." Catalysis Science & Technology 9, no. 9 (2019): 2125–31. http://dx.doi.org/10.1039/c9cy00359b.

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7

Chowdhury, R., S. Adhikari, and P. Rees. "Graphene based single molecule nanojunction." Physica B: Condensed Matter 407, no. 5 (March 2012): 855–58. http://dx.doi.org/10.1016/j.physb.2011.12.101.

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8

He, Huixin, Jisheng Zhu, Nongjian J. Tao, Larry A. Nagahara, Islamshah Amlani, and Raymond Tsui. "A Conducting Polymer Nanojunction Switch." Journal of the American Chemical Society 123, no. 31 (August 2001): 7730–31. http://dx.doi.org/10.1021/ja016264i.

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9

Ziv, Amir, Avra Tzaguy, Ori Hazut, Shira Yochelis, Roie Yerushalmi, and Yossi Paltiel. "Self-formed nanogap junctions for electronic detection and characterization of molecules and quantum dots." RSC Advances 7, no. 42 (2017): 25861–66. http://dx.doi.org/10.1039/c7ra04600f.

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10

Guo, Shien, Hongyan Ning, Mingxia Li, Rong Hao, Yuting Luan, and Baojiang Jiang. "The fabrication and the characterization of a TiO2/titanate nanohybrid for efficient hydrogen evolution." RSC Advances 5, no. 17 (2015): 13011–15. http://dx.doi.org/10.1039/c4ra14544e.

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11

Wang, Jing, Weiqing Xu, Xiangyuan Liu, Fou Bai, Xianghua Zhou, and Shuping Xu. "An organic–metal–inorganic three-component nanojunction array: design, construction and its reversible diode-like resistive electrical switching behavior." Journal of Materials Chemistry C 4, no. 3 (2016): 504–12. http://dx.doi.org/10.1039/c5tc03340c.

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12

Yang, X. F., H. L. Wang, Y. S. Chen, Y. W. Kuang, X. K. Hong, Y. S. Liu, J. F. Feng, and X. F. Wang. "Giant spin thermoelectric effects in all-carbon nanojunctions." Physical Chemistry Chemical Physics 17, no. 35 (2015): 22815–22. http://dx.doi.org/10.1039/c5cp02779a.

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13

Patriarchea, Chrysanthi, Ioannis Vamvasakis, Eirini D. Koutsouroubi, and Gerasimos S. Armatas. "Enhancing interfacial charge transfer in mesoporous MoS2/CdS nanojunction architectures for highly efficient visible-light photocatalytic water splitting." Inorganic Chemistry Frontiers 9, no. 4 (2022): 625–36. http://dx.doi.org/10.1039/d1qi01278a.

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Mesoporous MoS2-modified CdS nanojunction networks possessing advantageous electronic connectivity and charge transfer behavior at the interfaces deliver highly efficient visible-light photocatalytic H2 production activity from water splitting.
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14

Ondarcuhu, Thierry, and Christian Joachim. "Combing a nanofibre in a nanojunction." Nanotechnology 10, no. 1 (January 1, 1999): 39–44. http://dx.doi.org/10.1088/0957-4484/10/1/009.

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15

El-Khoury, Patrick Z., Grant E. Johnson, Irina V. Novikova, Yu Gong, Alan G. Joly, James E. Evans, Mikhail Zamkov, Julia Laskin, and Wayne P. Hess. "Enhanced Raman scattering from aromatic dithiols electrosprayed into plasmonic nanojunctions." Faraday Discussions 184 (2015): 339–57. http://dx.doi.org/10.1039/c5fd00036j.

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We describe surface enhanced Raman spectroscopy (SERS) experiments in which molecular coverage is systematically varied from 3.8 × 105 to 3.8 × 102 to 0.38 molecules per μm2 using electrospray deposition of ethanolic 4,4′-dimercaptostilbene (DMS) solutions. The plasmonic SERS substrate used herein consists of a well-characterized 2-dimensional (2D) array of silver nanospheres (see El-Khoury et al., J. Chem. Phys., 2014, 141, 214308), previously shown to feature uniform topography and plasmonic response, as well as intense SERS activity. When compared to their ensemble averaged analogues, the spatially and temporally averaged spectra of a single molecule exhibit several unique features including: (i) distinct relative intensities of the observable Raman-active vibrational states, (ii) more pronounced SERS backgrounds, and (iii) broader Raman lines indicative of faster vibrational dephasing. The first observation may be understood on the basis of an intuitive physical picture in which the removal of averaging over multiple molecules exposes the tensorial nature of Raman scattering. When an oriented single molecule gives rise to the recorded SERS spectra, the relative orientation of the molecule with respect to vector components of the local electric field determines the relative intensities of the observable vibrational states. Using a single molecule SERS framework, described herein, we derive a unique molecular orientation in which a single DMS molecule is isolated at a nanojunction formed between two silver nanospheres in the 2D array. The DMS molecule is found lying nearly flat with respect to the metal. The derived orientation of a single molecule at a plasmonic nanojunction is consistent with observations (ii) and (iii). In particular, a careful inspection of the temporal spectral variations along the recorded single molecule SERS time sequences reveals that the time-averaged SERS backgrounds arise from individual molecular events, marked by broadened SERS signatures. We assign the broadened spectra along the SERS time sequence – which sum up to a SERS background in the averaged spectra – to instances in which the π-framework of the DMS molecule is parallel to the metal at a classical plasmonic nanojunction. This also accounts for Raman line broadening as a result of fast vibrational dephasing, and driven by molecular reorientation at a plasmonic nanojunction. Furthermore, we report on the molecular orientation dependence of single molecule SERS enhancement factors. We find that in the case of a single DMS molecule isolated at a plasmonic nanojunction, molecular orientation may affect the derived single molecule SERS enhancement factor by up to 5 orders of magnitude. Taking both chemical effects as well as molecular orientation into account, we were able to estimate a single molecule enhancement factor of ∼1010 in our measurements.
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16

Wangperawong, Artit, and Stacey F. Bent. "Three-dimensional nanojunction device models for photovoltaics." Applied Physics Letters 98, no. 23 (June 6, 2011): 233106. http://dx.doi.org/10.1063/1.3595411.

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17

Li, Haidong, Lin Wang, and Yisong Zheng. "Suppressed conductance in a metallic graphene nanojunction." Journal of Applied Physics 105, no. 1 (January 2009): 013703. http://dx.doi.org/10.1063/1.3054449.

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18

Chen, Wei, Hong Liang Zhang, Han Huang, Lan Chen, and Andrew Thye Shen Wee. "Self-assembled organic donor/acceptor nanojunction arrays." Applied Physics Letters 92, no. 19 (May 12, 2008): 193301. http://dx.doi.org/10.1063/1.2920199.

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19

R. Mondal, B. Bhattacharya, and U. Sarkar. "Electrical Property of Zigzag Graphene-Molecular Nanojunction." Advanced Science Letters 22, no. 1 (January 1, 2016): 246–49. http://dx.doi.org/10.1166/asl.2016.6811.

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20

Mubeen, Syed, Bongyoung Yoo, and Nosang V. Myung. "Fabrication of nanoelectrodes and nanojunction hydrogen sensor." Applied Physics Letters 93, no. 13 (September 29, 2008): 133111. http://dx.doi.org/10.1063/1.2993337.

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21

Hettler, M. H., H. Schoeller, and W. Wenzel. "Non-linear transport through a molecular nanojunction." Europhysics Letters (EPL) 57, no. 4 (February 2002): 571–77. http://dx.doi.org/10.1209/epl/i2002-00500-3.

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22

Lin, Chenxiang, Mingyi Xie, Julian J. L. Chen, Yan Liu, and Hao Yan. "Rolling-Circle Amplification of a DNA Nanojunction." Angewandte Chemie 118, no. 45 (November 20, 2006): 7699–701. http://dx.doi.org/10.1002/ange.200602113.

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23

Lin, Chenxiang, Mingyi Xie, Julian J. L. Chen, Yan Liu, and Hao Yan. "Rolling-Circle Amplification of a DNA Nanojunction." Angewandte Chemie International Edition 45, no. 45 (November 20, 2006): 7537–39. http://dx.doi.org/10.1002/anie.200602113.

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24

Lü, Xiaoling, Yisong Zheng, Huanwen Xin, and Liwei Jiang. "Spin polarized electron transport through a graphene nanojunction." Applied Physics Letters 96, no. 13 (March 29, 2010): 132108. http://dx.doi.org/10.1063/1.3380662.

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25

Hou, J. G., Bing Wang, Jinlong Yang, X. R. Wang, H. Q. Wang, Qingshi Zhu, and Xudong Xiao. "Nonclassical Behavior in the Capacitance of a Nanojunction." Physical Review Letters 86, no. 23 (June 4, 2001): 5321–24. http://dx.doi.org/10.1103/physrevlett.86.5321.

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26

Li, Haidong, Ruixue Li, Qiongyan Yu, Xiubao Kang, and Jun Ding. "Line defect induced conductance suppression in graphene nanojunction." Solid State Communications 233 (May 2016): 18–23. http://dx.doi.org/10.1016/j.ssc.2016.02.009.

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27

Markel, Vadim A. "Coherently tunable third-order nonlinearity in a nanojunction." Journal of Physics B: Atomic, Molecular and Optical Physics 38, no. 21 (October 11, 2005): L347—L355. http://dx.doi.org/10.1088/0953-4075/38/21/l01.

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28

Khan, R., H. W. Ra, J. T. Kim, W. S. Jang, D. Sharma, and Y. H. Im. "Nanojunction effects in multiple ZnO nanowire gas sensor." Sensors and Actuators B: Chemical 150, no. 1 (September 2010): 389–93. http://dx.doi.org/10.1016/j.snb.2010.06.052.

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29

Goker, A. "Entropy Current through a Strongly Correlated Plexcitonic Nanojunction." Journal of Physical Chemistry C 122, no. 8 (February 21, 2018): 4607–14. http://dx.doi.org/10.1021/acs.jpcc.8b00057.

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30

Forzani, Erica S., Haiqian Zhang, Larry A. Nagahara, Ishamshah Amlani, Raymond Tsui, and Nongjian Tao. "A Conducting Polymer Nanojunction Sensor for Glucose Detection." Nano Letters 4, no. 12 (December 2004): 2519. http://dx.doi.org/10.1021/nl048314y.

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31

Forzani, Erica S., Haiqian Zhang, Larry A. Nagahara, Ishamshah Amlani, Raymond Tsui, and Nongjian Tao. "A Conducting Polymer Nanojunction Sensor for Glucose Detection." Nano Letters 4, no. 9 (September 2004): 1785–88. http://dx.doi.org/10.1021/nl049080l.

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32

Liu, M., and W. Wang. "Application of nanojunction-based RRAM to reconfigurable IC." Micro & Nano Letters 3, no. 3 (2008): 101. http://dx.doi.org/10.1049/mnl:20080029.

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33

Xing, Wendong, Jun Hu, Sheng-Chin Kung, Keith C. Donavan, Wenbo Yan, Ruqian Wu, and Reginald M. Penner. "A Chemically-Responsive Nanojunction within a Silver Nanowire." Nano Letters 12, no. 3 (March 6, 2012): 1729–35. http://dx.doi.org/10.1021/nl300427w.

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34

Park, Jae, Jeewhan Oh, and Sung Kim. "Controllable pH Manipulations in Micro/Nanofluidic Device Using Nanoscale Electrokinetics." Micromachines 11, no. 4 (April 10, 2020): 400. http://dx.doi.org/10.3390/mi11040400.

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Recently introduced nanoscale electrokinetic phenomenon called ion concentration polarization (ICP) has been suffered from serious pH changes to the sample fluid. A number of studies have focused on the origin of pH changes and strategies for regulating it. Instead of avoiding pH changes, in this work, we tried to demonstrate new ways to utilize this inevitable pH change. First, one can obtain a well-defined pH gradient in proton-received microchannel by applying a fixed electric current through a proton exchange membrane. Furthermore, one can tune the pH gradient on demand by adjusting the proton mass transportation (i.e., adjusting electric current). Secondly, we demonstrated that the occurrence of ICP can be examined by sensing a surrounding pH of electrolyte solution. When pH > threshold pH, patterned pH-responsive hydrogel inside a straight microchannel acted as a nanojunction to block the microchannel, while it did as a microjunction when pH < threshold pH. In case of forming a nanojunction, electrical current significantly dropped compared to the case of a microjunction. The strategies that presented in this work would be a basis for useful engineering applications such as a localized pH stimulation to biomolecules using tunable pH gradient generation and portable pH sensor with pH-sensitive hydrogel.
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35

Chakraborty, Suvendu, and Santanu K. Maiti. "Controlled thermoelectric performance in a nanojunction: A theoretical approach." Journal of Applied Physics 127, no. 2 (January 14, 2020): 024302. http://dx.doi.org/10.1063/1.5109854.

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36

Nowak, Roland, and Ryszard Jabłoński. "Dopant-Based Charge Sensing Utilizing P-I-N Nanojunction." Metrology and Measurement Systems 24, no. 2 (June 27, 2017): 391–99. http://dx.doi.org/10.1515/mms-2017-0029.

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AbstractWe studied lateral silicon p-i-n junctions, doped with phosphorus and boron, regarding charge sensing feasibility. In order to examine the detection capabilities and underlying mechanism, we used in a complementary way two measurement techniques. First, we employed a semiconductor parameter analyzer to measure I−V characteristics at a low temperature, for reverse and forward bias conditions. In both regimes, we systematically detected Random Telegraph Signal. Secondly, using a Low Temperature Kelvin Probe Force Microscope, we measured surface electronic potentials. Both p-i-n junction interfaces, p-i and i-n, were observed as regions of a dynamic behaviour, with characteristic time-dependent electronic potential fluctuations. Those fluctuations are due to single charge capture/emission events. We found analytically that the obtained data could be explained by a model of two-dimensional p-n junction and phosphorus-boron interaction at the edge of depletion region. The results of complementary measurements and analysis presented in this research, supported also by the previous reports, provide fundamental insight into the charge sensing mechanism utilizing emergence of individual dopants.
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37

Aguilar, Alvaro Díaz, Erica S. Forzani, Xiulan Li, Nongjian Tao, Larry A. Nagahara, Islamshah Amlani, and Raymond Tsui. "Chemical sensors using peptide-functionalized conducting polymer nanojunction arrays." Applied Physics Letters 87, no. 19 (November 7, 2005): 193108. http://dx.doi.org/10.1063/1.2128038.

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38

Hackens, B., L. Gence, C. Gustin, X. Wallart, S. Bollaert, A. Cappy, and V. Bayot. "Sign reversal and tunable rectification in a ballistic nanojunction." Applied Physics Letters 85, no. 19 (2004): 4508. http://dx.doi.org/10.1063/1.1814803.

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39

Kwon, Sangku, Hyungtak Seo, Hyunsoo Lee, Ki-Joon Jeon, and Jeong Young Park. "Reversible bistability of conductance on graphene/CuOx/Cu nanojunction." Applied Physics Letters 100, no. 12 (March 19, 2012): 123101. http://dx.doi.org/10.1063/1.3694754.

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40

Zhou, Shenghan, Xiangdong Guo, Ke Chen, Matthew Thomas Cole, Xiaowei Wang, Zhenjun Li, Jiayu Dai, Chi Li, and Qing Dai. "Optical‐Field‐Driven Electron Tunneling in Metal–Insulator–Metal Nanojunction." Advanced Science 8, no. 24 (October 27, 2021): 2101572. http://dx.doi.org/10.1002/advs.202101572.

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41

Goker, A. "Time dependent thermal transport through a strongly correlated plexcitonic nanojunction." Physica B: Condensed Matter 625 (January 2022): 413452. http://dx.doi.org/10.1016/j.physb.2021.413452.

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42

Zhukov, M. V., S. Yu Lukashenko, I. D. Sapozhnikov, and A. O. Golubok. "Creation and study of liquid nanojunction using SPM-base technology." Journal of Physics: Conference Series 1695 (December 2020): 012167. http://dx.doi.org/10.1088/1742-6596/1695/1/012167.

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43

Xu, Hua, Shuxin Ouyang, Lequan Liu, Defa Wang, Tetsuya Kako, and Jinhua Ye. "Porous-structured Cu2O/TiO2 nanojunction material toward efficient CO2 photoreduction." Nanotechnology 25, no. 16 (March 26, 2014): 165402. http://dx.doi.org/10.1088/0957-4484/25/16/165402.

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44

Wang, Yan, Zhi-Chao Li, Wei-Jiang Gong, Xiao-Yan Sui, and Xiao-Hui Chen. "Thermoelectric and thermospin switch realized by a three-terminal nanojunction." Journal of Applied Physics 113, no. 18 (May 14, 2013): 184308. http://dx.doi.org/10.1063/1.4804325.

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45

Butti, P., I. Shorubalko, U. Sennhauser, and K. Ensslin. "Finite element simulations of graphene based three-terminal nanojunction rectifiers." Journal of Applied Physics 114, no. 3 (July 21, 2013): 033710. http://dx.doi.org/10.1063/1.4815956.

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46

Taylor, Richard W., Roger J. Coulston, Frank Biedermann, Sumeet Mahajan, Jeremy J. Baumberg, and Oren A. Scherman. "In Situ SERS Monitoring of Photochemistry within a Nanojunction Reactor." Nano Letters 13, no. 12 (November 13, 2013): 5985–90. http://dx.doi.org/10.1021/nl403164c.

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47

Pohl, Vincent, Lukas Eugen Marsoner Steinkasserer, and Jean Christophe Tremblay. "Imaging Time-Dependent Electronic Currents through a Graphene-Based Nanojunction." Journal of Physical Chemistry Letters 10, no. 18 (August 26, 2019): 5387–94. http://dx.doi.org/10.1021/acs.jpclett.9b01732.

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48

Shen, Shaohua, Coleman X. Kronawitter, Jiangang Jiang, Penghui Guo, Liejin Guo, and Samuel S. Mao. "A ZnO/ZnO:Cr isostructural nanojunction electrode for photoelectrochemical water splitting." Nano Energy 2, no. 5 (September 2013): 958–65. http://dx.doi.org/10.1016/j.nanoen.2013.03.017.

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49

Gu, Zhenao, Xiaoqiang An, Ruiping Liu, Lunqiao Xiong, Junwang Tang, Chengzhi Hu, Huijuan Liu, and Jiuhui Qu. "Interface-modulated nanojunction and microfluidic platform for photoelectrocatalytic chemicals upgrading." Applied Catalysis B: Environmental 282 (March 2021): 119541. http://dx.doi.org/10.1016/j.apcatb.2020.119541.

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50

Ai, Yong, Van Quynh Nguyen, Jalal Ghilane, Pierre-Camille Lacaze, and Jean-Christophe Lacroix. "Plasmon-Induced Conductance Switching of an Electroactive Conjugated Polymer Nanojunction." ACS Applied Materials & Interfaces 9, no. 33 (August 9, 2017): 27817–24. http://dx.doi.org/10.1021/acsami.7b04695.

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