Dielectric microrods can be trapped horizontally in pairs of holographically controlled optical traps. External forces acting on these microrods are registered via the rotational and translational displacement of the microrod relative to the traps. In the following paper we demonstrate accurate, real-time tracking of this displacement in two dimensions. The precision of the method is estimated and the translational and rotational stiffness coefficients of the trapped microrod are evaluated by analysing the thermal motion and the Stokes drag. The variation of these stiffness coefficients relative to the displacement of the traps from the ends of the microrods is measured, and optimal trapping conditions are located
Holographically trapped nanotools can be used in a novel form of force microscopy. By measuring the ...
The use of optical traps to measure or apply forces on the molecular level requires a precise knowle...
We show how holographic optical trapping can be used for the multipoint measurement of fluid flow in...
We present a holographic optical tweezers system capable of position clamping multiple particles. Mo...
Holographic optical tweezers is a widely used technique to manipulate the individual positions of op...
SINCE their invention, optical tweezers have found a host of applications, primarily as micro- manip...
We analyse the thermal motion of a holographically trapped non-spherical force probe, capable of int...
Holographic optical trapping (HOT) is a technique for non-invasive dynamic anipulation of multiple m...
We combined a single-beam gradient optical trap with a high-resolution photodiode position detector ...
Force measurement in an interactive 3D micromanipulation system can allow the user to make delicate ...
Holographic optical traps use the forces exerted by computer-generated holograms to trap, move and o...
Optical tweezers can trap micron-sized objects such as cells, bacteria, and microspheres, and has be...
Interest in microfluidics is rapidly expanding and the use of microchips as miniature chemical react...
The use of optical traps to measure or apply forces on the molecular level requires a precise knowle...
The potential of digital holography for complex manipulation of micron-sized particles with optical ...
Holographically trapped nanotools can be used in a novel form of force microscopy. By measuring the ...
The use of optical traps to measure or apply forces on the molecular level requires a precise knowle...
We show how holographic optical trapping can be used for the multipoint measurement of fluid flow in...
We present a holographic optical tweezers system capable of position clamping multiple particles. Mo...
Holographic optical tweezers is a widely used technique to manipulate the individual positions of op...
SINCE their invention, optical tweezers have found a host of applications, primarily as micro- manip...
We analyse the thermal motion of a holographically trapped non-spherical force probe, capable of int...
Holographic optical trapping (HOT) is a technique for non-invasive dynamic anipulation of multiple m...
We combined a single-beam gradient optical trap with a high-resolution photodiode position detector ...
Force measurement in an interactive 3D micromanipulation system can allow the user to make delicate ...
Holographic optical traps use the forces exerted by computer-generated holograms to trap, move and o...
Optical tweezers can trap micron-sized objects such as cells, bacteria, and microspheres, and has be...
Interest in microfluidics is rapidly expanding and the use of microchips as miniature chemical react...
The use of optical traps to measure or apply forces on the molecular level requires a precise knowle...
The potential of digital holography for complex manipulation of micron-sized particles with optical ...
Holographically trapped nanotools can be used in a novel form of force microscopy. By measuring the ...
The use of optical traps to measure or apply forces on the molecular level requires a precise knowle...
We show how holographic optical trapping can be used for the multipoint measurement of fluid flow in...