纳米通道

由于波导也是一种“纳米通道”，使用光既可以捕获也能运送物体。

Because the waveguide is also a " nanochannel " it can both trap and transport objects using light .

并利用NMM-1检测纳米通道的形状、宽度和深度，计算在同一芯片上的不同位置纳米通道深度及宽度的一致性。

Using NMM-1 , the shape of the nano channels are tested . The uniformity of the different nano channels ' depth and width in the same chip is calculated .

模板法合成纳米通道在微流控系统中的应用

Fabrication of Nanostructure by Template Method in Microfluidic Systems

但当条形纳米通道的宽度增大时，选择性则会逐渐减弱。

However , the selectivity will be weakened when the distance of the two pieces of graphite becomes larger .

我们知道，改变纳米通道的半径或者纳米通道和水之间的相互作用，将会引起纳米通道内的汽液相变和开关状态的转换。

We know it will cause a vapor-liquid transition or switch between open and closed when change the radius of the nanotube or the channel-water interaction is triggered .

以聚碳酸酯膜为基底，采用化学沉积法，获得了沉积均匀的金纳米通道。

Main work in the present thesis are shown as follows : 1 Au was deposited within the pores of the polycarbonate template membrane using an electroless deposition method .

理解水在不同结构的纳米通道中的输运行为是至关重要的，近年来纳米通道的这一特性成为众多领域研究的热点。

It is important to understand the transport behaviors of water in the nanotube with different structures , which became to be the research focus for many fields near recent years .

说明这种温度敏感型纳米通道膜有望用于实际的药物控制释放体系，在生命活动模拟、纳米仿生等方面有着潜在的应用价值。

Therefore , this kind of controllable thermoresponsive membrane can be applied in practical controlled drug release , and may have a unique potential application in the field of life process simulation and so on . 2 .

由于碳纳米管本身的结构简单，而且很多相应的输运行为又与生物系统中的孔道有一些类似，所以了解并控制水在碳纳米管内的输运对于纳米通道和生物活性的研究是至关重要的。

The carbon nanotube could be treated as the alternative of biological channel as some of its transport properties are similar as biological channel . So it is very important to understand and control the transport of water in carbon nanotubes for study the nano-channel and biological activity .

添加纳米颗粒强化微小通道内对流换热

Enhancing convective heat transfer in mini tubes with nanoparticles