A Route to Ultra-Fast Amplitude-Only Spatial Light Modulation using Phase-Change Materials

A phase-change material based, thin-film, amplitude-only spatial light modulator is presented. The modulator operates in reflection and modulates the amplitude of light incident on its surface with no effect on optical phase when the phase-change material is switched between its amorphous and crystalline states. This is achieved using a thin-film device with an embedded, switchable, GeTe phase-change layer. Test modulation patterns are written to the device using laser scans, and the amplitude and phase response measured, using optical spectroscopy and off-axis digital holography. Experimental results reveal reflected intensity to be modulated by up to 38%, with an averaged phase difference of less than & AP;& pi;/50. Since phase-change materials such as GeTe can be switched on sub-microsecond timescales, this approach maps out a route for ultra-fast amplitude spatial light modulators with widespread applications in fields such as wavefront shaping, communications, sensing, and imaging.

Automated summary

A phase-change material based, thin-film, amplitude-only spatial light modulator is introduced, which modulates the amplitude of incident light without affecting its optical phase. This is achieved by using a thin-film device with a switchable GeTe phase-change layer. Experimental results show that the reflected intensity can be modulated up to 38% with a small average phase difference. The ability of phase-change materials to switch on a sub-microsecond timescales suggests the potential of this modulator in various applications, such as wavefront shaping, communications, sensing, and imaging.