DMD-Based Excitation of Transverse Laser Modes by Spatial Pump Beam Shaping

Florian Schepers, Tim Bexter, T. Hellwig, C. Fallnich
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Abstract

The excitation of transverse laser modes, can be achieved by a cavity-internal amplitude or phase modulation of the laser light. For this purpose typically additional cavity-internal components are applied, which can result in increased losses and a limited resonator internal power [1]. Therefore, gain shaping based methods [2], where the selective mode excitation is achieved via a cavity-external modulation of the pump beam are of great interest, as they require no modification of the laser cavity itself. However, the so far presented gain shaping methods are strongly limited with respect to the number of modes that can be excited, as they apply pump beams of a fixed spatial shape. Here, we present a spatial gain shaping method that applies a digital micromirror device (DMD) as a shaping tool for the pump beam, enabling a high degree of freedom for the gain distributions that can be generated. We demonstrate the advantage of our approach by exciting nearly 1000 different single Hermite-Gaussian (HG) modes in an end-pumped Nd:YVO4 laser, increasing the number of excitable HG modes by at least a factor of five in comparison to other excitation methods [2, 3].
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基于dmd的空间泵浦光束整形激励横向激光模式
横向激光模式的激发可以通过对激光的腔内振幅或相位调制来实现。为此,通常使用额外的腔内元件,这可能导致损耗增加和谐振器内部功率受限。因此,基于增益整形的方法[2],其中通过泵浦光束的腔外调制实现选择模式激发是非常有趣的,因为它们不需要修改激光腔本身。然而,迄今为止提出的增益整形方法在可以激发的模式数量方面受到强烈限制,因为它们应用的是固定空间形状的泵浦光束。在这里,我们提出了一种空间增益整形方法,该方法应用数字微镜器件(DMD)作为泵浦光的整形工具,使可以生成的增益分布具有高度的自由度。我们通过在端泵浦Nd:YVO4激光器中激发近1000种不同的单厄米-高斯(HG)模式来证明我们方法的优势,与其他激发方法相比,可激发的HG模式的数量至少增加了五倍[2,3]。
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