Grayscale control of local magnetic properties with direct-write laser annealing

Across the fields of magnetism, microelectronics, optics, and others, engineered local variations in physical properties can yield groundbreaking functionalities that play a crucial role in enabling future technologies. Beyond binary modifications, 1D lateral gradients in material properties (achieved by gradients in thickness, stoichiometry, temperature, or strain) give rise to a plethora of new effects in thin film magnetic systems. However, extending such gradient-induced behaviors to 2D is challenging to realize with existing methods, which are plagued by slow processing speeds, dose instabilities, or limitation to variation along one dimension. Here, we show for the first time how commonplace direct-write laser exposure techniques, initially developed for grayscale patterning of photoresist surfaces, can be repurposed to perform grayscale direct-write laser annealing. With this technique, we demonstrate the ease with which two-dimensional, continuous variations in magnetic properties can be created at the mesoscopic scale in numerous application-relevant materials, including ferromagnetic, ferrimagnetic, and synthetic antiferromagnetic thin-film systems. The speed, versatility, and new possibilities to create complex magnetic energy landscapes offered by direct-write laser annealing opens the door to the lateral modification of the magnetic, electronic, and structural properties of a variety of thin films with an abundance of applications.