Li Fengchang, Cao Qiang, Wang Xiaoliang, Wang Ruonan
Opt Lett. 2024 Apr 15;49(8):1892-1895. doi: 10.1364/OL.519935.
We experimentally demonstrate the highly-efficient nonlocal erasing and writing of ferroelectric domains using a femtosecond laser in lithium niobate. Based on the induction of a focused infrared femtosecond laser without any relative displacement or additional treatment, the original multiple ferroelectric domains can be either erased (erasing operation) or elongated (writing operation) simultaneously in the crystal, depending on the laser focusing depth and the laser pulse energy. In the erasing operation, the original multiple ferroelectric domains can be cleared completely by just one laser induction, while in the writing operation, the average length of the ferroelectric domains can be elongated up to 235 µm by three laser inductions. A model has been proposed in which a thermoelectric field and a space charge field are used cooperatively to successfully explain the mechanism of nonlocal erasing and writing. This method greatly improves the efficiency and flexibility of tailoring ferroelectric domain structures, paving the way to large-scale all-optical industrial production for nonlinear photonic crystals and nonvolatile ferroelectric domain wall memories.
我们通过实验证明了利用飞秒激光在铌酸锂中高效地进行铁电畴的非局部擦除和写入。基于聚焦红外飞秒激光的诱导,无需任何相对位移或额外处理,根据激光聚焦深度和激光脉冲能量,晶体中的原始多个铁电畴可以同时被擦除(擦除操作)或拉长(写入操作)。在擦除操作中,只需一次激光诱导就能完全清除原始的多个铁电畴,而在写入操作中,通过三次激光诱导,铁电畴的平均长度可拉长至235微米。我们提出了一个模型,其中热电电场和空间电荷场协同作用,成功地解释了非局部擦除和写入的机制。该方法大大提高了定制铁电畴结构的效率和灵活性,为非线性光子晶体和非易失性铁电畴壁存储器的大规模全光工业生产铺平了道路。