Creep of beta-tin single crystals at subkelvin temperatures

Нацик, В. Д.; Soldatov, V. P.; Ivanchenko, L. G.; Kirichenko, G. I.

doi:10.1063/1.1645187

Cited by 10 publications

(7 citation statements)

References 9 publications

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“…Additional information for the high degree of graphitization of the CNTs comes from Raman measurements (see Supporting Information). Comparing the present results with previous ones where tin nanowires (whiskers) were produced without the protecting CNTs 10,12 shows that the nanowires here are less straight and do not grow with a low-index crystal direction exactly along the nanowire axis. This difference can be understood since for noncovered nanowires the surface energy and facet formation play (during growth) a crucial role and will force the wire to have low energy facets along its long sides.…”

supporting

confidence: 75%

“…The data show a clear diamagnetic behavior below the bulk superconducting transition temperature for tin T c ) 3.72 K (indicated by the arrow). 10,12 The magnetization drops rapidly below the bulk T c , but a small tail in the magnetization remains at temperatures as high as 4.0 K. As shown below, the small increase of the T c onset is due to the thinnest nanowires in which the confinement and surface-to-volume ratio becomes large enough to influence the vibrational and electronic properties. The same has been reported in the literature 13 for tin nanowires of 20 nm diameter.…”

mentioning

confidence: 91%

“…Without this paramagnetic background, the powder would still be diamagnetic at higher fields. This means that the onset of the superconducting critical field is higher than 0.4 T, which is more than 1 order of magnitude higher than the bulk thermodynamical critical field H c Bulk ) 0.021 T at 2 K. 12 Measurements above T c show that the apparent paramagnetic background is in fact the sum of a temperature-dependent paramagnetic signal, probably due to a few magnetic impurities, superimposed to a temperature-independent diamagnetic contribution. A simple removal of the background is shown in Figure 4b (black circles) where we see that the onset of critical field is of the order of 0.6 T. This increase in the critical field is a direct result of the reduced diameter of the nanowires.…”

mentioning

confidence: 92%

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Carbon Nanotubes Encapsulating Superconducting Single-Crystalline Tin Nanowires

Jankovič¹,

Gournis²,

Trikalitis³

et al. 2006

Nano Lett.

107

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Superconducting low dimensional systems are the natural choice for fast and sensitive infrared detection, because of their quantum nature and the low-noise, cryogenic operation environment. On the other hand, monochromatic and coherent electron beams, emitted from superconductors and carbon-based nanostructured materials, respectively, are significant for the development of electron optical systems such as electron microscopes and electron-beam nanofabrication systems. Here we describe for the first time a simple method which yields carbon nanotubes encapsulating single crystalline superconducting tin nanowires by employing the catalytic chemical vapor deposition method over solid tin dioxide. The superconducting tin nanowires, with diameters 15-35 nm, are covered with well-graphitized carbon walls and show, due to their reduced diameters, a critical magnetic field (Hc) more than 30 times higher than the value of bulk metallic tin.

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supporting

confidence: 75%

mentioning

confidence: 91%

mentioning

confidence: 92%

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Carbon Nanotubes Encapsulating Superconducting Single-Crystalline Tin Nanowires

Jankovič¹,

Gournis²,

Trikalitis³

et al. 2006

Nano Lett.

107

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“…11 Another possible origin for the unchanged superconducting transition temperature is that this is an effect of increased surface area, which may enhance surface electron-phonon scattering effect and compensate the size effect of reducing the superconducting transition temperature. 32 This increase in the critical field is a direct result of the reduced size of nanorods. 3͑a͒.…”

Section: Resultsmentioning

confidence: 99%

Large critical magnetic field and tunneling anomaly behavior of superconducting carbon-coated Sn nanorods and nanoparticles

Wang

Geng

Han

et al. 2010

Journal of Applied Physics

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Ac susceptibility studies of a superconducting gallium nanocomposite: Crossover in the upper critical field line and activation barriers Evidence that the upper critical field of Nb3Sn is independent of whether it is cubic or tetragonal Appl. Phys. Lett. 99, 122507 (2011); 10.1063/1.3643055Quasiperiodic superconducting V/Zr multilayers: critical magnetic fields and crossover Low Temp.The arc-discharge process is usually used to synthesize some kinds of metal nanocrystals or nanoparticles all with high melting temperature. Here, the carbon-coated Sn ͑with a low melting temperature͒ nanostructured materials with different shapes, such as carbon-coated Sn nanorods with diameter of about 100 and 50 nm and, correspondingly, the length of 500 and 200 nm, and the carbon-coated Sn nanoparticles, are prepared by a modified arc-discharge process. The carbon shells are found to surround these Sn nanostructures. The carbon shell becomes thick with decreasing the size of the Sn nanostructures. The magnetic and electrical transports are affected by the shape of nanocrystals. The critical magnetic field of the carbon-coated Sn nanorods with diameter of 50 nm and length of 200 nm is almost 25 times higher than that of bulk Sn. The superconductivity of the carbon-coated Sn nanoparticles with particle size of 40 nm is destroyed. The zero bias tunneling anomalies was observed in the carbon-coated Sn nanoparticles.

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“…It is also possible that the carriers of plastic deformation may overcome a potential barrier by quantum tunnelling or that there is a combination of thermally activated and quantum mechanical mechanisms for creep. Quantum motion of dislocations and quantum plasticity effects have been repeatedly discussed in studies of the mechanical properties of metallic crystals at temperatures on the order of and below 1 K. [22][23][24] …”

Section: Low-temperature Creep At T < T Bmentioning

confidence: 99%

Creep in solid 4He at temperatures below 1 K

Zhuchkov

Lisunov

Maı̆danov

et al. 2015

Low Temperature Physics

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Creep in solid 4 He at temperatures of $100-1000 mK is studied experimentally by detecting the flow of helium through a frozen porous membrane under a constant external force. Creep curves are measured for different temperatures and mechanical stresses. This method has made it possible to detect low creep rates in helium down to the lowest temperatures in these experiments. It is found that throughout this temperature range, creep is thermally activated and the activation energy decreases with falling temperature and increasing mechanical stress. An analysis shows that for temperatures above %500 mK, Nabarro-Herring diffusive creep takes place in solid helium with mass transfer by self diffusion of atoms and a counterflow of vacancies. The experimental data have been used to obtain the self-diffusion coefficient as a function of temperature for different stresses. At temperatures below %500 mK creep takes place at a very low flow rate ($10 À13 cm/s) and a very low activation energy ($0.5-0.7 K), while the creep mechanism remains unclear. V C 2015 AIP Publishing LLC. [http://dx.

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Creep of beta-tin single crystals at subkelvin temperatures

Cited by 10 publications

References 9 publications

Carbon Nanotubes Encapsulating Superconducting Single-Crystalline Tin Nanowires

Carbon Nanotubes Encapsulating Superconducting Single-Crystalline Tin Nanowires

Large critical magnetic field and tunneling anomaly behavior of superconducting carbon-coated Sn nanorods and nanoparticles

Creep in solid 4He at temperatures below 1 K

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