Figure 6
Schematic representation of the vacant functional nanocavity of the two-dimensionally ordered linear-chain carbon nano-matrix available for nano-clusters assembling
Contexts in source publication
Context 1
... ordered linear-chain carbon nano-matrix represent a multi-cavity nanostructure, containing vacant functional nanocavities, available for assembling by atom clusters of various chemical elements. Schematic representation of the vacant functional nanocavity of the nano-matrix available for nano-clusters assembling is presented in Fig. 6. By cluster-assembling of the spatial structure of two-dimensionally ordered linear-chain carbon nano-matrix with various molecules, specific catalytic agents and chemical elements, the properties of the nano-matrix can be both modified or the new properties can be added. Cluster-assembly of the nano-matrix can occur both without ...
Context 2
... by the piezoelectric layers can be used for programming the required geometric configurations and sizes of the nanostructure of the grown metamaterials. Simultaneous application of the direct and inverse piezoelectric effect opens possibility for interactive ion-assisted pulse-plasma growth the carbon-based nanostructured metamaterials (see Fig. ...
Context 3
... research demonstrates how vibrations, frequency and energy flux can change and program the nanostructure of the growing carbine-enriched nanostructured metamaterials. Two-dimensionally ordered linear chain carbon nano-matrix could serve as an efficient basis for designing and the growth of the new Figure 16: Application of the direct and inverse piezoelectric effect for nano-structural monitoring system during the ion-assisted pulse-plasma deposition carbyne-enriched nanostructured metamaterials with unique properties. Structural self-organization and pattern formation are the universal and key phenomena observed during growth and heteroatom-doping of the carbyne-enriched nano-matrix at the ion-assisted pulse-plasma deposition. ...
Similar publications
![Fig. 1. Architecture for a coordinated SASO system; adapted from [5].](profile/Pia-Schweizer/publication/386362531/figure/fig1/AS:11431281326894505@1743061853201/Architecture-for-a-coordinated-SASO-system-adapted-from-5_Q320.jpg)
Citations
... With taking into account that the 2D-LCC-based nano-matrix are acoustically sensitive nanomaterial, we propose use the predictive fine tuning the nanoarchitecture, vibrational characteristics and heteroatom-doping by using the surface acoustic wave (SAW)-based toolkit, [13]. In particular, we propose to use the technology of the carbyne-enriched nanomaterial growing onto acoustically excited piezoelectric-based substrates. ...
We propose to uncover new opportunities for predictive nano-sized energetic materials performance enhancement through manipulating by vibrational interactions, energy exchange as well as heat transfer enhancement within the reaction zones at nanoscale. The combination of multiple carbon nanostructured materials with various hybridizations within a single substance can uncover new unique properties. Due to a recent fundamental discovery the collective atomic vibrations, called phonon waves, manifested in transition domains of multilayer nanostructures, incorporation of self-organized arrays of metastable nanostructures are capable controlling vibrational interactions and energy exchange within the reaction zones at nanoscale. For using this phenomenon, we propose predictive incorporation into the nano-sized energetic material composition of various carbon-based allotropes, used as catalytic nano-additives, combined with assembling them by the self-organized arrays of differently hybridized low-dimensional nanocarbon promoters. For predictive combining of multiple differently hybridized nanocarbons within a single substance we propose to use the energy-driven initiation of the allotropic phase transformations in nanocarbon promoters by concurrent electron and ion irradiation. For fine tuning the collective atomic vibrations, nanoarchitecture and functionality of the mentioned arrays of differently hybridized nanocarbon promoters we propose using combination of a set of techniques: concurrent electron and ion irradiation, using the surface acoustic waves combined with heteroatom doping along with application external electromagnetic fields and using the data-driven nanoscale manufacturing approach.
We present a method of synthesis of sp-carbon allotropes or carbynes. Linear chains of carbon atoms are obtained from graphite placed in a joint field of laser plasma and arc discharge. The combined action of laser and arc discharge allows to create conditions for the formation of a variety of carbon allotropes, whose structural composition is governed by the interplay of external fields. The method may be employed in the mass production of sp- and sp²- hybridized carbon for the needs of possible applications in micro and nanoelectronics, biosensing.
