Carbyne and fullerene are the ultimate combination.

"Schematic representation of carbyne stabilized inside small diameter double walled carbon nanotubes. Credit: Emil Parth, Faculty of Physics, University of Vienna, Edited" (ScitechDaily, Atomic Eavesdropping: How Carbyne Talks Through Quantum Vibrations)

Carbyne and fullerene are the ultimate combination. "Scientists in Vienna have successfully created a stable form of carbyne, the world’s strongest material. Carbyne is a linear acetylenic carbon – an infinitely long carbon chain. It can be considered as a one-dimensional allotrope of carbon. Carbyne has a chemical structure with alternating single and triple bonds: (−C≡C−)n. This structure of carbon gives an impressive Young’s modulus (a measure of the tensile stiffness of a solid material) of 32.7 TPa, which is forty times that of diamond, and thirty times that of carbon nanotubes." (LabCharge, Carbyne: Officially the Strongest Material in the World) 

The carbyne chemical bond structure, the triple bond between two carbon atoms that alternates with the single bond gives this carbon chain an ultimate strength. Unlike the regular single bond carbon, fullerene the triple bond in carbon allows that part of the triple bond to open. And then those opened bonds act as quantum antennas that conduct energy out from the carbyne. If there is the possibility to make this kind of structure into the fullerene that makes this structure stronger than regular fullerene because those quantum spikes transport energy out from the structure more effectively than in simple graphene layers. 

There are no limits to the length of the carbyne chain. There is the possibility that carbyne is used in nano-canvas, which is like normal canvas, but the carbyne chain replaced normal yarn. The nano-canvas formed of the squares of the carbyne. Another way to use the carbyne is to put it into the fullerene nanotubes. The carbyne chains that are in the fullerene nanotubes can conduct energy out of the structure. This thing makes those carbon tubes sustain the energy loads. 

That opens the road to the new armor. The carbyne chain can also make it possible to create new and effective sensors. When some energy impulse hits the nanotube, that oscillates the carbyne. And the laser beam can detect that movement. There is also the possibility that the carbyne-nanotube combinations make it possible to create miniature flying devices. The system brings energy to the carbyne. That makes carbyne heat. And it can make the nanotube hover. 

The energy that travels out from the carbyne makes a fully symmetrical effect around the system. This means the carbyne-fullerene combination turns hovering. The system makes a halo around it and the system can hover in that halo or acoustic bubble. In computing networks, the system can push and pull the carbyne stick back and forth. That allows the transmission of information in a short-distance mechanical network. The carbyne stick pushes the nano-button and sends zeros and ones like Morse code to the receiver. 

The carbyne stick can also act as an antenna that transmits energy impacts to targets. The idea is that the energy impacts are aimed to carbyne straight. Or through the fullerene tubes. That makes it possible to create new quantum tools that can move and manipulate objects. 

The virtually negative material means the case that energy flows only away from the structure. This material causes the need to rethink material limits. It can make new types of solutions possible. And those solutions can open roads to the new information superhighways. 

https://www.labxchange.org/library/items/lb:LabXchange:0f37aae6:html:1

https://scitechdaily.com/atomic-eavesdropping-how-carbyne-talks-through-quantum-vibrations/