Microspheres are quivered while they are shocked. And that makes it possible to create a new type of nanorobots.

The new nanorobots are swimming like micro-organisms such as amoebas. 

That thing is done by using oscillating crystals or other structures. Those nano-size systems are allowing to creating the movement of the sphere of the nanomachine. In some versions in the sphere is put the ball, where is the DNA springs. 

There are miniature magnets at the end of that structure. And there are the small iron bites at the core of the sphere. When the system is stressing those bites with electromagnetic radiation, that thing pulls the nano spring outward. But there are many other ways to make that thing. Which purpose is to change the form of the sphere of the machine. 

The quivering microspheres are one of the most interesting versions of the swimming, non-organic nanorobots. One version of the quivering can make by using the nano-crystals that are oscillating. When the sound waves are impacting those crystals. If we are thinking about the possibility to adjust the direction, where the nanomachine must swim. 

The easiest way to make that thing is to use let's say four types of crystals. If those crystals are in four sides of the nanomachine. And they are oscillating by different sound frequencies, that thing allows aiming those nanomachines to the selected way of four possibilities. 

This means that the aiming the direction of the nanomachines can adjust by stressing those crystals by using four possible sound frequencies. Of course, there is the possibility to use the four wavelength radio transmit. And if we want to make those nanomachines swim in six directions. There are needed six types of crystals that are reacting with the six different radio or acoustic frequencies. 

The question is how many directions the oscillating particles can get. In the other versions, the oscillating objects are inside the sphere, but the way how they work is always similar. If the oscillators are outside the sphere they can form the bubble ahead or around them. And move the nanomachine in the wanted direction. 

The nanomachine can have an RFID chip, which makes the system able to follow its location. And then the nanomachine can aim to move to the right location in the operational area, which can be the polluted water or the human body. 

The nanospheres can have a carbon core, which makes them able to clean water. Or they can carry antibiotics or cytostatics to the tumor area. And those systems can also mark the non-wanted tissue by using antigens. That is making the immune system destroy those non-wanted cells. 

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