Journal articles: 'Individual nanostructures'

1

Wong, Tak-Sing, Adam Po-Hao Huang, and Chih-Ming Ho. "Wetting Behaviors of Individual Nanostructures." Langmuir 25, no. 12 (June 16, 2009): 6599–603. http://dx.doi.org/10.1021/la900874f.

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2

Wood, Jonathan. "Microscope probes carriers in individual nanostructures." Materials Today 9, no. 1-2 (January 2006): 13. http://dx.doi.org/10.1016/s1369-7021(05)71328-6.

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Samuelson, Lars, Niclas Carlsson, Pedro Castrillo, Anders Gustafsson, Dan Hessman, Joakim Lindahl, Lars Montelius, Anders Petersson, Mats-Erik Pistol, and Werner Seifert. "Nano-Optical Studies of Individual Nanostructures." Japanese Journal of Applied Physics 34, Part 1, No. 8B (August 30, 1995): 4392–97. http://dx.doi.org/10.1143/jjap.34.4392.

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Ratto, Fulvio, Andrea Locatelli, Stefano Fontana, Sharmin Kharrazi, Shriwas Ashtaputre, Sulabha K Kulkarni, Stefan Heun, and Federico Rosei. "Chemical Mapping of Individual Semiconductor Nanostructures." Small 2, no. 3 (March 2006): 401–5. http://dx.doi.org/10.1002/smll.200500345.

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Gallart, Mathieu, Spyros Varoutsis, Jonas Bylander, Emmanuel Moreau, Isabelle Robert-Philip, Izo Abram, and Jean Michel Gérard. "Single photon emission from individual semiconductor nanostructures." Physica E: Low-dimensional Systems and Nanostructures 17 (April 2003): 568–71. http://dx.doi.org/10.1016/s1386-9477(02)00873-1.

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Hu, Hailong, Huigao Duan, Joel K. W. Yang, and Ze Xiang Shen. "Plasmon-Modulated Photoluminescence of Individual Gold Nanostructures." ACS Nano 6, no. 11 (October 31, 2012): 10147–55. http://dx.doi.org/10.1021/nn3039066.

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Havener, Robin W., Adam W. Tsen, Hee Cheul Choi, and Jiwoong Park. "Laser-based imaging of individual carbon nanostructures." NPG Asia Materials 3, no. 10 (October 2011): 91–99. http://dx.doi.org/10.1038/asiamat.2011.145.

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Roddaro, Stefano, Daniele Ercolani, Mian Akif Safeen, Francesco Rossella, Vincenzo Piazza, Francesco Giazotto, Lucia Sorba, and Fabio Beltram. "Large thermal biasing of individual gated nanostructures." Nano Research 7, no. 4 (April 2014): 579–87. http://dx.doi.org/10.1007/s12274-014-0426-y.

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9

Nicolosi, Valeria. "Processing and characterisation of two-dimensional nanostructures." Acta Crystallographica Section A Foundations and Advances 70, a1 (August 5, 2014): C510. http://dx.doi.org/10.1107/s2053273314094893.

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Low-dimensional nanostructured materials such as organic and inorganic nanotubes, nanowires and platelets are potentially useful in a number of areas of nanoscience and nanotechnology due to their remarkable mechanical, electrical and thermal properties. However difficulties associated with their lack of processability have seriously hampered both. In the last few years dispersion and exfoliation methods have been developed and demonstrated to apply universally to 1D and 2D nanostructures of very diverse nature, offering a practical means of processing the nanostructures for a wide range of innovative technologies. Among the first materials to have benefitted most from these advances are carbon nanotubes [6] and more recently graphene. Recently this work has been extended to boron nitride and a wide range of two-dimensional transition metal chalcogenides. These are potentially important because they occur in >40 different types with a wide range of electronic properties, varying from metallic to semiconducting. To make real applications truly feasible, however, it is crucial to fully characterize the nanostructures on the atomic scale and correlate this information with their physical and chemical properties. Advances in aberration-corrected optics in electron microscopy have revolutionised the way to characterise nano-materials, opening new frontiers for materials science. With the recent advances in nanostructure processability, electron microscopes are now revealing the structure of the individual components of nanomaterials, atom by atom. Here we will present an overview of very different low-dimensional materials issues, showing what aberration-corrected electron microscopy can do to answer materials scientists' questions. Particular emphasis will be given to the investigation of hexagonal boron nitride (hBN), molybdenum disulfide (MoS2), and tungsten disulfide (WS2) and the study of their structure, defects, stacking sequence, vacancies and low-atomic number individual adatoms. The analyses of the h-BN data showed that majority of nanosheets retain bulk stacking. However several of the images displayed stacking different from the bulk. Similar, to 2D h-BN, images of MoS2 and WS2 have shown the stacking previously unobserved in the bulk. This novel stacking consists of Mo/W stacked on the top each other in the consecutive layers.

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Dreser, Christoph, Dominik A. Gollmer, Godofredo Bautista, Xiaorun Zang, Dieter P. Kern, Martti Kauranen, and Monika Fleischer. "Plasmonic mode conversion in individual tilted 3D nanostructures." Nanoscale 11, no. 12 (2019): 5429–40. http://dx.doi.org/10.1039/c8nr10254f.

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11

Zhao, Peng, Yu Zhang, Shuai Tang, Runze Zhan, Juncong She, Jun Chen, and Shaozhi Deng. "A Universal Method to Weld Individual One-Dimensional Nanostructures with a Tungsten Needle Based on Synergy of the Electron Beam and Electrical Current." Nanomaterials 10, no. 3 (March 5, 2020): 469. http://dx.doi.org/10.3390/nano10030469.

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One-dimensional (1D) nanostructures are extensively used in the design of novel electronic devices, sensors, and energy devices. One of the major challenges faced by the electronics industry is the problem of contact between the 1D nanostructure and electrode, which can limit or even jeopardize device operations. Herein, a universal method that can realize good Ohmic and mechanical contact between an individual 1D nanostructure and a tungsten needle at sub-micron or micron scale is investigated and presented in a scanning electron microscope (SEM) chamber with the synergy of an electron beam and electrical current flowing through the welded joint. The linear I‒V curves of five types of individual 1D nanostructures, characterized by in-situ electrical measurements, demonstrate that most of them demonstrate good Ohmic contact with the tungsten needle, and the results of in-situ tensile measurements demonstrate that the welded joints possess excellent mechanical performance. By simulation analysis using the finite element method, it is proved that the local heating effect, which is mainly produced by the electrical current flowing through the welded joints during the welding process, is the key factor in achieving good Ohmic contact.

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12

Poempool, Thanavorn, Zon, Suwit Kiravittaya, Suwat Sopitpan, Supachok Thainoi, Songphol Kanjanachuchai, Somchai Ratanathamaphan, and Somsak Panyakeow. "GaSb and InSb Quantum Nanostructures: Morphologies and Optical Properties." MRS Advances 1, no. 23 (December 10, 2015): 1677–82. http://dx.doi.org/10.1557/adv.2015.6.

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ABSTRACTGaSb/GaAs and InSb/GaAs material systems can create type-II quantum nanostructures which provide interesting electronic and optical properties such as having long carrier life time, low carriers-recombination rate, and emitting/absorbing low photon energy. These characteristics of type-II nanostructures can be applied for infrared or gas detection devices, for memory devices and even for novel intermediate band solar cells. In contrast, lattice mismatches of GaSb/GaAs and InSb/GaAs material system are 7.8% and 14.6%, respectively, which need some specific molecular beam epitaxial (MBE) growth conditions for quantum nanostructure formation via Stranski–Krastanov growth mode.In this paper, the growth of self-assembled GaSb and InSb quantum nanostructures on (001) GaAs substrate by using MBE was reported. The surface morphology of these two quantum nanostructures and their optical properties were characterized by atomic force microscopy and photoluminescence (PL). The experimental results were compared between these two quantum nanostructures. Due to the lattice mismatch in each material system and the difference in sticking coefficient of Ga- and In-atoms during epitaxial growth, we obtain GaSb/GaAs quantum dots (QDs) with a density ∼1010 dots/cm2 and InSb/GaAs QDs with a density of ∼108 dots/cm2. The facet analysis of individual quantum nanostructure in each material system reveals that GaSb/GaAs QD has a dome-like shape with nearly isotropic property while InSb QDs form a rectangular-like shape with elongation along [110]-direction showing a strong anisotropic property.Low temperature PL spectra from capped GaSb and InSb quantum nanostructures show the energy peaks at 1.08-1.11 and 1.16-1.17 eV, respectively. The variations of PL peaks as a function of both temperature and excitation power are investigated. PL peak shows clear blue shift when excitation power is increased. This work manifests a possibility to use both GaSb and InSb quantum nanostructures for nanoelectronic and nanophotonic applications.

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13

Bubenchikov, Michael, Alexey Bubenchikov, and Alexander Malozemov. "Studying permeability of nanostructures obtained from polyethylene threads." Thermal Science 23, Suppl. 2 (2019): 463–69. http://dx.doi.org/10.2298/tsci19s2463b.

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The paper studies process of interaction of a moving molecule with structure atoms. The mathematical description is based on application of Hamiltonian systems model and numerical methods for solving the basic problem of molecular dynamics. The interaction between individual atoms and the simplest molecules is cared out using the classical Lennard-Jones potential. Polyethylene nanostructures are considered as filtering elements for selective separation of natural gas mixtures, in particular, their light components: hydrogen and helium. The influence of geometric dimensions and geometric features of a nanostructure on selectivity of gas mixtures separation is studied.

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Ma, Churong, Jiahao Yan, Yuming Wei, Pu Liu, and Guowei Yang. "Enhanced second harmonic generation in individual barium titanate nanoparticles driven by Mie resonances." Journal of Materials Chemistry C 5, no. 19 (2017): 4810–19. http://dx.doi.org/10.1039/c7tc00650k.

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Although previous designs of nonlinear optical (NLO) nanostructures have focused on photonic crystals and metal plasmonic nanostructures, complex structures, large ohmic loss, and Joule heating greatly hinder their practical applications.

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15

Lutz, Christopher, and Leo Gross. "30 years of moving individual atoms." Europhysics News 51, no. 2 (March 2020): 26–28. http://dx.doi.org/10.1051/epn/2020205.

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In the thirty years since atoms were first positioned individually, the atom-moving capability of scanning probe microscopes has grown to employ a wide variety of atoms and small molecules, yielding custom nanostructures that show unique electronic, magnetic and chemical properties.

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16

Domènech-Gil, Guillem, Jordi Samà, Paolo Pellegrino, Sven Barth, Isabel Gràcia, Carles Cané, and Albert Romano-Rodriguez. "Gas Nanosensors Based on Individual Indium Oxide Nanostructures." Procedia Engineering 120 (2015): 795–98. http://dx.doi.org/10.1016/j.proeng.2015.08.826.

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17

Ushioda, S. "Probing individual nanostructures with STM-induced light emission." Solid State Communications 117, no. 3 (January 2001): 159–66. http://dx.doi.org/10.1016/s0038-1098(00)00438-5.

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18

Dai, Alan, Michal Vadai, Katherine Sytwu, and Jennifer Dionne. "Liquid-Phase Electron Spectroscopy of Individual Plasmonic Nanostructures." Microscopy and Microanalysis 26, S2 (July 30, 2020): 204–5. http://dx.doi.org/10.1017/s1431927620013781.

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19

Mocuta, C., B. Krause, R. Mundboth, T. H. Metzger, J. Stangl, G. Bauer, I. Vartanyants, C. Deneke, and O. G. Schmidt. "X-ray microdiffraction on individual self-assembled nanostructures." Acta Crystallographica Section A Foundations of Crystallography 63, a1 (August 22, 2007): s89. http://dx.doi.org/10.1107/s0108767307098054.

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20

Zhu, Yanwu, Yousheng Zhang, Fook-Chiong Cheong, Chorng-Haur Sow, and Chwee-Teck Lim. "Annealing effects on the elastic modulus of tungsten oxide nanowires." Journal of Materials Research 23, no. 8 (August 2008): 2149–56. http://dx.doi.org/10.1557/jmr.2008.0277.

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Three-point bend test coupled with transmission electron microscopy (TEM) analysis was carried out on individual tungsten oxide nanowires (NWs) before and after annealing. Three-point bend test monitors the change in the Young’s modulus of the NW after annealing, while TEM provides nanostructural detail changes on the same NW. In this way, insight into the correlation between the mechanical properties of a NW and its nanostructure details can be obtained. Annealing increased the diameter of the NWs by forming a uniform amorphous/polycrystalline outer coating. The coating results in a decrease in Young’s moduli for thicker NWs. On the other hand, annealing led to increased Young’s moduli of thinner NWs, which is attributed to the improved crystallinity in these NWs after annealing. This study points to a more refined strategy for more in-depth understanding of the relationship between the nanostructures and elastic mechanical properties of NWs.

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21

Demontis, Valeria, Mirko Rocci, Maurizio Donarelli, Rishi Maiti, Valentina Zannier, Fabio Beltram, Lucia Sorba, Stefano Roddaro, Francesco Rossella, and Camilla Baratto. "Conductometric Sensing with Individual InAs Nanowires." Sensors 19, no. 13 (July 7, 2019): 2994. http://dx.doi.org/10.3390/s19132994.

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In this work, we isolate individual wurtzite InAs nanowires and fabricate electrical contacts at both ends, exploiting the single nanostructures as building blocks to realize two different architectures of conductometric sensors: (a) the nanowire is drop-casted onto—supported by—a SiO2/Si substrate, and (b) the nanowire is suspended at approximately 250 nm from the substrate. We test the source-drain current upon changes in the concentration of humidity, ethanol, and NO2, using synthetic air as a gas carrier, moving a step forward towards mimicking operational environmental conditions. The supported architecture shows higher response in the mid humidity range (50% relative humidity), with shorter response and recovery times and lower detection limit with respect to the suspended nanowire. These experimental pieces of evidence indicate a minor role of the InAs/SiO2 contact area; hence, there is no need for suspended nanostructures to improve the sensing performance. Moreover, the sensing capability of single InAs nanowires for detection of NO2 and ethanol in the ambient atmosphere is reported and discussed.

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22

Yang, Zhong-Jian, Yan-Hui Deng, Ying Yu, and Jun He. "Magnetic toroidal dipole response in individual all-dielectric nanodisk clusters." Nanoscale 12, no. 19 (2020): 10639–46. http://dx.doi.org/10.1039/d0nr01440k.

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23

Vacha, Martin, Masaaki Saeki, Makoto Furuki, Lyong Sun Pu, Ken-ichi Hashizume, and Toshiro Tani. "Optical properties of individual nanostructures of molecular J-aggregates." Journal of Luminescence 98, no. 1-4 (July 2002): 35–40. http://dx.doi.org/10.1016/s0022-2313(02)00248-x.

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Vacha, Martin, Makoto Furuki, Lyong Sun Pu, Ken-ichi Hashizume, and Toshiro Tani. "Individual J-Aggregate Nanostructures as Self-Assembled Organic Microcavities." Journal of Physical Chemistry B 105, no. 49 (December 2001): 12226–29. http://dx.doi.org/10.1021/jp011360r.

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25

Gao, Bo, Koshala Sarveswaran, Gary H. Bernstein, and Marya Lieberman. "Guided Deposition of Individual DNA Nanostructures on Silicon Substrates." Langmuir 26, no. 15 (August 3, 2010): 12680–83. http://dx.doi.org/10.1021/la101343k.

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26

Li, Jian, Pablo Jiménez-Calvo, Erwan Paineau, and Mohamed Nawfal Ghazzal. "Metal Chalcogenides Based Heterojunctions and Novel Nanostructures for Photocatalytic Hydrogen Evolution." Catalysts 10, no. 1 (January 7, 2020): 89. http://dx.doi.org/10.3390/catal10010089.

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The photo-conversion efficiency is a key issue in the development of new photocatalysts for solar light driven water splitting applications. In recent years, different engineering strategies have been proposed to improve the photogeneration and the lifetime of charge carriers in nanostructured photocatalysts. In particular, the rational design of heterojunctions composites to obtain peculiar physico-chemical properties has achieved more efficient charge carriers formation and separation in comparison to their individual component materials. In this review, the recent progress of sulfide-based heterojunctions and novel nanostructures such as core-shell structure, periodical structure, and hollow cylinders is summarized. Some new perspectives of opportunities and challenges in fabricating high-performance photocatalysts are also discussed.

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27

Halas, Naomi. "Playing with Plasmons: Tuning the Optical Resonant Properties of Metallic Nanoshells." MRS Bulletin 30, no. 5 (May 2005): 362–67. http://dx.doi.org/10.1557/mrs2005.99.

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AbstractNanoshells, concentric nanoparticles consisting of a dielectric core and a metallic shell, are simple spherical nanostructures with unique, geometrically tunable optical resonances. As with all metallic nanostructures, their optical properties are controlled by the collective electronic resonance, or plasmon resonance, of the constituent metal, typically silver or gold. In striking contrast to the resonant properties of solid metallic nanostructures, which exhibit only a weak tunability with size or aspect ratio, the optical resonance of a nanoshell is extraordinarily sensitive to the inner and outer dimensions of the metallic shell layer. The underlying reason for this lies beyond classical electromagnetic theory, where plasmon-resonant nanoparticles follow a mesoscale analogue of molecular orbital theory, hybridizing in precisely the same manner as the individual atomic wave functions in simple molecules. This plasmon hybridization picture provides an essential “design rule” for metallic nanostructures that can allow us to effectively predict their optical resonant properties. Such a systematic control of the far-field optical resonances of metallic nanostructures is accomplished simultaneously with control of the field at the surface of the nanostructure. The nanoshell geometry is ideal for tuning and optimizing the near-field response as a stand-alone surface-enhanced Raman spectroscopy (SERS) nanosensor substrate and as a surface-plasmon-resonant nanosensor.Tuning the plasmon resonance of nanoshells into the near-infrared region of the spectrum has enabled a variety of biomedical applications that exploit the strong optical contrast available with nanoshells in a spectral region where blood and tissue are optimally transparent.

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García, Javier, Alejandro M. Manterola, Miguel Méndez, Jose Angel Fernández-Roldán, Víctor Vega, Silvia González, and Víctor M. Prida. "Magnetization Reversal Process and Magnetostatic Interactions in Fe56Co44/SiO2/Fe3O4 Core/Shell Ferromagnetic Nanowires with Non-Magnetic Interlayer." Nanomaterials 11, no. 9 (September 2, 2021): 2282. http://dx.doi.org/10.3390/nano11092282.

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Nowadays, numerous works regarding nanowires or nanotubes are being published, studying different combinations of materials or geometries with single or multiple layers. However, works, where both nanotube and nanowires are forming complex structures, are scarcer due to the underlying difficulties that their fabrication and characterization entail. Among the specific applications for these nanostructures that can be used in sensing or high-density magnetic data storage devices, there are the fields of photonics or spintronics. To achieve further improvements in these research fields, a complete understanding of the magnetic properties exhibited by these nanostructures is needed, including their magnetization reversal processes and control of the magnetic domain walls. In order to gain a deeper insight into this topic, complex systems are being fabricated by altering their dimensions or composition. In this work, a successful process flow for the additive fabrication of core/shell nanowires arrays is developed. The core/shell nanostructures fabricated here consist of a magnetic nanowire nucleus (Fe56Co44), grown by electrodeposition and coated by a non-magnetic SiO2 layer coaxially surrounded by a magnetic Fe3O4 nanotubular coating both fabricated by means of the Atomic Layer Deposition (ALD) technique. Moreover, the magnetization reversal processes of these coaxial nanostructures and the magnetostatic interactions between the two magnetic components are investigated by means of standard magnetometry and First Order Reversal Curve methodology. From this study, a two-step magnetization reversal of the core/shell bimagnetic nanostructure is inferred, which is also corroborated by the hysteresis loops of individual core/shell nanostructures measured by Kerr effect-based magnetometer.

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29

Yang, Yuanqing, Vladimir A. Zenin, and Sergey I. Bozhevolnyi. "Anapole-Assisted Strong Field Enhancement in Individual All-Dielectric Nanostructures." ACS Photonics 5, no. 5 (March 7, 2018): 1960–66. http://dx.doi.org/10.1021/acsphotonics.7b01440.

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30

Lobov, I. A., N. A. Davletkildeev, and D. V. Sokolov. "Work function tuning of the individual polyaniline/carbon nanotube nanostructures." IOP Conference Series: Materials Science and Engineering 443 (November 14, 2018): 012021. http://dx.doi.org/10.1088/1757-899x/443/1/012021.

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31

Oh, Young Mu, Kyung Moon Lee, Kyung Ho Park, Yongsun Kim, Y. H. Ahn, Ji-Yong Park, and Soonil Lee. "Correlating Luminescence from Individual ZnO Nanostructures with Electronic Transport Characteristics." Nano Letters 7, no. 12 (December 2007): 3681–85. http://dx.doi.org/10.1021/nl071959o.

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32

Zhang, Z. H., Xuefeng Wang, J. B. Xu, S. Muller, C. Ronning, and Quan Li. "Evidence of intrinsic ferromagnetism in individual dilute magnetic semiconducting nanostructures." Nature Nanotechnology 4, no. 8 (July 13, 2009): 523–27. http://dx.doi.org/10.1038/nnano.2009.181.

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33

Bai, X. D., Zhi Xu, K. H. Liu, and E. G. Wang. "In situ TEM probing properties of individual one-dimensional nanostructures." International Journal of Nanotechnology 4, no. 1/2 (2007): 119. http://dx.doi.org/10.1504/ijnt.2007.012319.

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34

Zheng, Jianlin, Matthew C. Wingert, Jaeyun Moon, and Renkun Chen. "Simultaneous specific heat and thermal conductivity measurement of individual nanostructures." Semiconductor Science and Technology 31, no. 8 (July 21, 2016): 084005. http://dx.doi.org/10.1088/0268-1242/31/8/084005.

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35

Ito, K., S. Ohyama, Y. Uehara, and S. Ushioda. "STM light emission spectra of individual nanostructures of porous Si." Surface Science 363, no. 1-3 (August 1996): 423–27. http://dx.doi.org/10.1016/0039-6028(96)00171-9.

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Ushioda, S. "Novel Optical Spectroscopy of Individual Nanostructures: STM Light Emission Spectroscopy." Chemical Educator 1, no. 4 (September 1996): 1–14. http://dx.doi.org/10.1007/s00897960047a.

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37

Lee, Ka Yin, Elliot Beutler, David Masiello, and Maureen Joel Lagos. "Substrate Effects on the Phonon Response of Individual Dielectric Nanostructures." Microscopy and Microanalysis 27, S1 (July 30, 2021): 312–14. http://dx.doi.org/10.1017/s1431927621001690.

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Li, Xiaodong, Ioannis Chasiotis, and Takayuki Kitamura. "In Situ Scanning Probe Microscopy Nanomechanical Testing." MRS Bulletin 35, no. 5 (May 2010): 361–67. http://dx.doi.org/10.1557/mrs2010.568.

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AbstractScanning probe microscopy (SPM) has undergone rapid advancements since its invention almost three decades ago. Applications have been extended from topographical imaging to the measurement of magnetic fields, frictional forces, electric potentials, capacitance, current flow, piezoelectric response and temperature (to name a few) of inorganic and organic materials, as well as biological entities. Here, we limit our focus to mechanical characterization by taking advantage of the unique imaging and force/displacement sensing capabilities of SPM. This article presents state-of-the-art in situ SPM nanomechanical testing methods spanning (1) probing the mechanical properties of individual one-dimensional nanostructures; (2) mapping local, nanoscale strain fields, fracture, and wear damage of nanostructured heterogeneous materials; and (3) measuring the interfacial strength of nanostructures. The article highlights several novel SPM nanomechanical testing methods, which are expected to lead to further advancements in nanoscale mechanical testing and instrumentation toward the exploration and fundamental understanding of mechanical property size effects in nanomaterials.

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Iijima, Sumio. "Closed graphene nanostructures." Proceedings, annual meeting, Electron Microscopy Society of America 53 (August 13, 1995): 194–95. http://dx.doi.org/10.1017/s0424820100137343.

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Graphene is named a single sheet of graphite, or a 2-D carbon hexagons network. The graphene structure has been observed in partially graphitized carbon which is familiar to electron microscopists and its HRTEM image properties were analyzed previously in detail. C60 molecules, which has brought a great excitements in interdisciplinary fields of science and technology, is basically the same graphene structure with a curvature. The individual C60 molecule can be imaged without difficulty by HRTEM. Many of fundamental problems with the molecule however are not solved by the HRTEM technique. On the other hand, carbon nanotubes, a family of the fullerene and discovered serendipitously by the present author5, are an ideal subject for the HRTEM investigation and in fact their structural details can only be analyzed by this technique. The present talk reviews the carbon nanotubes and related structures with an emphasis of usefulness of the HRTEM.Search for the multi-shell graphite particles leads to unexpected discovery of carbon nanotubes which grow on a cathode in a carbon-arc chamber for the C60 production.

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40

Sojo Gordillo, Jose Manuel, Gerard Gadea Diez, Mercè Pacios Pujadó, Marc Salleras, Denise Estrada-Wiese, Marc Dolcet, Luis Fonseca, Alex Morata, and Albert Tarancón. "Thermal conductivity of individual Si and SiGe epitaxially integrated NWs by scanning thermal microscopy." Nanoscale 13, no. 15 (2021): 7252–65. http://dx.doi.org/10.1039/d1nr00344e.

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Thermal conductivity measurement of integrated high aspect ratio nanostructures has been demonstrated using spatially-resolved scanning thermal microscopy. Thermal conductivities of integrated individual Si and SiGe nanowires were measured.

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41

Bienville, T., J. F. Robillard, L. Belliard, I. Roch-Jeune, A. Devos, and B. Perrin. "Individual and collective vibrational modes of nanostructures studied by picosecond ultrasonics." Ultrasonics 44 (December 2006): e1289-e1294. http://dx.doi.org/10.1016/j.ultras.2006.05.179.

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42

Günster, J., M. Baxendale, S. Otani, and R. Souda. "Growth of individual carbon composite nanostructures on the faceted TiC() surface." Surface Science 494, no. 1 (November 2001): L781—L786. http://dx.doi.org/10.1016/s0039-6028(01)01508-4.

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43

Anderson, I., J. Scott, K. Klein, A. Melechko, and M. Simpson. "Screening of Individual Nanostructures with STEM-EELS and EFTEM Spectral Imaging." Microscopy and Microanalysis 12, S02 (July 31, 2006): 1170–71. http://dx.doi.org/10.1017/s1431927606067894.

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44

Fan, Zheng, Xinyong Tao, Xudong Fan, Xiaodong Li, and Lixin Dong. "Sliding Probe Methods for In Situ Nanorobotic Characterization of Individual Nanostructures." IEEE Transactions on Robotics 31, no. 1 (February 2015): 12–18. http://dx.doi.org/10.1109/tro.2014.2367331.

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Ma, Houyi, Yongli Jiao, Bingsheng Yin, Shuyun Wang, Shiyong Zhao, Shaoxin Huang, Wei Pan, Shenhao Chen, and Fanjun Meng. "Spontaneous Organization of Individual Silver Nanoparticles into One-Dimensionally Ordered Nanostructures." ChemPhysChem 5, no. 5 (May 17, 2004): 713–16. http://dx.doi.org/10.1002/cphc.200301007.

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46

Brewster, Megan M., Xiang Zhou, Ming-Yen Lu, and Silvija Gradečak. "The interplay of structural and optical properties in individual ZnO nanostructures." Nanoscale 4, no. 5 (2012): 1455. http://dx.doi.org/10.1039/c2nr11706a.

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Tsuruoka, T. "Optical characterization of individual semiconductor nanostructures using a scanning tunneling microscope." Journal of Electron Microscopy 53, no. 2 (April 1, 2004): 169–75. http://dx.doi.org/10.1093/jmicro/53.2.169.

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Rufner, Jorgen F., Cecile S. Bonifacio, Troy B. Holland, Amiya K. Mukherjee, Ricardo H. R. Castro, and Klaus van Benthem. "Local Current-Activated Growth of Individual Nanostructures with High Aspect Ratios." Materials Research Letters 2, no. 1 (October 28, 2013): 10–15. http://dx.doi.org/10.1080/21663831.2013.855272.

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Ruan, Gang, Greg Vieira, Thomas Henighan, Aaron Chen, Dhananjay Thakur, R. Sooryakumar, and Jessica O. Winter. "Simultaneous Magnetic Manipulation and Fluorescent Tracking of Multiple Individual Hybrid Nanostructures." Nano Letters 10, no. 6 (June 9, 2010): 2220–24. http://dx.doi.org/10.1021/nl1011855.

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Rudolph, Tobias, and Felix H. Schacher. "Selective crosslinking or addressing of individual domains within block copolymer nanostructures." European Polymer Journal 80 (July 2016): 317–31. http://dx.doi.org/10.1016/j.eurpolymj.2016.03.018.

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Journal articles on the topic 'Individual nanostructures'

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