The levitation position of diamagnetic materials has previously been controlled by changing the applied magnetic field, but so far no one has successfully controlled maglev motion in the second way, by changing the material's diamagnetic properties with an external stimulus such as temperature, light, or sound In order to magnetically levitate, an object's total magnetic force must not only be repulsive, but the repulsion must also be stronger than the force of gravity. Although all materials have some diamagnetism, it is usually too weak to allow them to magnetically levitate. As the researchers explain, magnetic levitation occurs due to an object's diamagnetism, which repels magnetic fields. One of the strongest diamagnetic materials is graphite. Magnetic levitation only occurs when a material's diamagnetic properties are stronger than its ferromagnetic and paramagnetic properties (which attract magnetic fields). The height at which a diamagnetic material levitates can be controlled by two factors: the applied magnetic field and the material's own diamagnetic properties.
Here, the researchers did just that by using a laser to reversibly control the temperature of a graphite disk levitating over a block of permanent magnets. They demonstrated that, as the graphite's temperature increases, its levitation height decreases, and vice versa. The researchers explain that the change in temperature causes a change in the graphite's magnetic susceptibility, or the degree to which its magnetization reacts to an applied magnetic field. On an atomic level, the laser increases the number of thermally excited electrons in the graphite due to the photothermal effect. The more of these electrons, the weaker the graphite's diamagnetic properties and the lower its levitation height.
Rotation also occurs when the set-up is exposed to sunlight. Applications could include a low-cost, environmentally friendly power generation system and a new type of light-driven transportation system. By converting solar energy into rotational energy, the disk can reach a rotational speed of more than 200 rpm, which could make it useful for applications such as optically driven turbines. " Whereas the laser was aimed right in the center of the graphite disk when controlling its height, aiming it at the edge of the disk changes the temperature distribution, and thus magnetic susceptibility distribution, in such a way that the repulsion force becomes unbalanced and the graphite moves in the same direction as the light beam. "In this case, it is predicted that friction disrupts the rotation of the maglev turbine. "As for the actuator, the maglev graphite can convey anything that has almost the same weight as the levitating graphite disk. The distorted temperature distribution causes the levitating graphite disk to rotate, with the direction and rotational speed depending on the irradiation site. The researchers predict that the ability to control maglev-based motion with a laser could lead to the development of maglev-based actuators and photothermal solar energy conversion systems. To rotate the levitating graphite disk, the researchers replaced the rectangular prism-shaped magnets beneath the disk with a stack of cylindrical-shaped magnets, and again aimed the laser at the disk's edge. So, if the scale expansion of the photo-actuator system is achieved, it is not a dream that a human on the maglev graphite can drive himself. Therefore, we would like to develop a light energy conversion system with a high energy conversion efficiency with reference to the so-called MEMS (Microelectromechanical Systems) technique. In addition to controlling the height of maglev graphite, the researchers found that they could also make the graphite move in any direction and rotate it by changing the site of irradiation. "At this moment, we are planning to develop a maglev turbine blade suitable for this system," Abe said.