The 3D nano-skyscrapers can be used to make the new type of microchips. And even small-size quantum computers that can operate at room temperature can be possible by using biocomputers.

Image 1) "Researchers from the University of Cambridge used 3D printing. To create grids of high-rise ‘nano-housing’ where sun-loving bacteria can grow quickly".

"The researchers were then able to extract the bacteria’s waste electrons, leftover from photosynthesis, which could be used to power small electronics. Credit: Gabriella Bocchetti" (ScitechDaily/3D-Printed “Nano-Skyscrapers” Help Bacteria Convert Sunlight Into Electricity)

The 3D nano-skyscrapers can be used to make the new type of microchips. And even small-size quantum computers that can operate at room temperature can be possible by using biocomputers. Those systems can revolutionize nanotechnology. 

The nano-skyscrapers can offer the space where the bacteria that transform light to electricity can live. That kind of bacteria that transforms sunlight into electricity can deliver energy to the nano-size microprocessors. The nano-size microchips can use synthetic DNA as the springs that are operating as miniature switches.  

The fact is that the nanoscale springs that can transmit electricity can also make it possible to make the nano-scale quantum processors that can operate at room temperature. In that case, the data is traveling through the nanostructure in wires. And each of the wires is the one certain state or layer of the qubit. 

The fast DNA replication makes it possible to fix errors in the quantum system. The nano-size springs make it possible that the system can use binary as well as quantum mode. So, at first data and data-handling instructions are transmitted to the system by using the binary mode. Then the system can start to use quantum states. 

When we are thinking about this type of quantum computer there is the possibility that they use only the lines of the qubit. If the operations of this type of quantum computer are limited in the number of wires. That thing is still more effective than binary computers. 

But bio processors can also benefit bioluminescence light. For making the states for the qubit. The tubes where bacteria are growing can quip with the fast-operating dimmers. Those dimmers can control the light level that transmits data to the photovoltaic cells. The system can operate similarly with cameras. 

The extremely fast-operating dimmers adjust the light level. And the shutter cuts the data line. There is the possibility to put the CCD (Photovoltaic chip) on the nanotube or nano-skyscraper structure. And there is a color filter that can adjust the light, open and close in each of the tubes. Each wavelength that the CCD detects can be a certain state of the qubit. 

Image 2) "Test tubes holding water samples glow green inside an illuminator, indicating contamination. Credit: Northwestern University"(ScitechDaily/New DNA Computer Assesses Water Quality: Genetic Networks Mimic Electronic Circuits). 

The same technology is introduced in image 2. Can use for making electricity for the miniature quantum computer. In that case, every tube would equip with a closer and dimmer that makes it possible to adjust the light that travels to photovoltaic cells. 

Even if that kind of quantum computer is not possible those systems can deliver energy to nano-scale microprocessors that require extremely low voltage. 

Maybe those processors are not so powerful as the central computers are. But they can give more abilities for things like nanorobots. The computer that can use bioelectricity is interesting because it can operate without outcoming electricity. 

The only thing that this kind of system requires is nutrients that are delivering food to those bacteria. So the system can use an artificial stomach where are the same bacteria as humans. And the system can eat the same food as humans, and transfer it to electricity. But if the bacteria is a so-called vegetable. The normal vegetable fertilizer is enough. For making the power for the nano-tech processor. 

If there is some kind of damage in that kind of system the fast DNA replication allows to clone more of those electric bacteria. DNA auto replication allows also make the spare parts for the system. And that thing can be the next-generation tool for robotics. The lightweight and powerful microchips are required in independently operating small-size robots. 

https://scitechdaily.com/3d-printed-nano-skyscrapers-help-bacteria-convert-sunlight-into-electricity/

https://scitechdaily.com/dna-replication-speed-limit-could-be-a-breakthrough-for-stem-cell-therapy/

https://scitechdaily.com/new-dna-computer-assesses-water-quality-genetic-networks-mimic-electronic-circuits/

Image 1) https://scitechdaily.com/3d-printed-nano-skyscrapers-help-bacteria-convert-sunlight-into-electricity/

Image 2) https://scitechdaily.com/new-dna-computer-assesses-water-quality-genetic-networks-mimic-electronic-circuits/