In the first part of this blog series The thermic diode, a new potentially revolutionary simple electronic element, Part 1 I've described the thermic diode and the related new disciplines of phononics and coherent caloritronics.
These fields of research are showing fast growing interest not only of the researchers in the field of electronics: The best positioned players ready to take on this opportunity are the semiconductor makers that have the right infrastructure for a high volume production. Once the technology is consolidated, the first companies that have taken this challenge will dictate the prizes and will address the new trends of this technology that holds promises of never before experienced thermal efficiencies.
Indeed, one of the principal strengths of the thermic diode consists in the fact that the heat is transferred through the movement of the electrons, not through an increasing of the amplitude of the oscillations of the molecules of the conducting material, as usual. This means that at very low temperatures, near to the absolute zero thermic, there should be electron transmission and not heat dissipation, and moreover the material utilized to build may be selected to operate at low temperatures as superconductors. This opens the way to the massive utilization of superconductors in the field of electronics to create smartphones, computers, tablets and wearable's having and incredible energetic efficiency and thus a huge autonomy in terms of medium time elapsed between two consecutive recharges of the device. (See Figure 1)
The heat dissipation, hence, could be dramatically reduced; however, the production of heat is not always an undesirable effect of the flow of the electrical current inside a circuit: indeed the huge thermal efficiency attainable with this solution may be coupled with the thermal harvesting of energy that is a strategy to harvest, store and finally utilize the electric energy to feed electronic circuits (see Figure 2).
A solution to harvest thermic energy to feed an electronic circuit (source: MIT)
By utilizing some organic thermoelectric generators that are devices whose basic principle of working is based on the thermoelectricity technology it is possible to create the electronic energy to recharge an electronic device. The simultaneous utilization of both of the solutions may be a winning strategy to create a self-sustainable electronics setup that would require a very low external amount of energy to work correctly.
The "thermoelectonics" is hence a huge potential technology; do you think it will be a largely adopted solution for new generation electronic devices?