Cilia are tiny hair-like structures that cover the surfaces of biological cells. One of their functions is to generate flow. Artificial cilia are mechanical actuators that are designed to mimic the motion of natural cilia in order to create fluid transport in microchannels. These fluid propulsion systems have potential for application in lab-on-a-chip devices that are used, e.g., for point-of-care diagnosis. The artificial cilia can be actuated through various means such as light, magnetic fields and electric fields. One of the main challenges in the design of artificial cilia is to find the cilia geometry and spacing, microchannel geometry, external actuation field, and frequency of operation, for which the fluid transported and the pressu...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
Cilia are tiny hair-like structures that cover the surfaces of biological cells. One of their functi...
Cilia are tiny hair-like structures that cover the surfaces of biological cells. One of their functi...
Cilia are tiny hair-like structures that cover the surfaces of biological cells. One of their functi...
Cilia are tiny hair-like structures that cover the surfaces of biological cells. One of their functi...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
Cilia are tiny hair-like structures that cover the surfaces of biological cells. One of their functi...
Cilia are tiny hair-like structures that cover the surfaces of biological cells. One of their functi...
Cilia are tiny hair-like structures that cover the surfaces of biological cells. One of their functi...
Cilia are tiny hair-like structures that cover the surfaces of biological cells. One of their functi...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...
In this paper we quantitatively analyse the performance of magnetically-driven artificial cilia for ...