Simultaneously shaping the intensity and phase of light for optical nanomanipulation

Holographic optical tweezers can be applied to manipulate microscopic particles in arbitrary optical patterns, which classical optical tweezers cannot do. This ability relies on accurate computer-generated holography (CGH), yet most CGH techniques can only shape the intensity profiles while the phase distributions are random. Here, we introduce a new method for fast generation of holograms that allows for simultaneously shaping both the intensity and phase distributions of light. The method uses a discrete inverse Fourier transform formula to directly calculate a hologram in one step, in which a random phase factor is introduced into the formula to enable simultaneous control of intensity and phase. Various optical patterns can be created, as demonstrated by the experimentally measured intensity and phase profiles projected from the holograms. The simultaneous shaping of intensity and phase of light provides new opportunities for optical trapping and manipulation, such as optical transportation of metal nanoparticles in ring traps with linear and nonlinear phase distributions.