It consists of back irons, permanent magnets and a solenoid coil
There have been many reports on nanodevices and molecular machines based on DNA, proteins, and polymers [1�C5]. Moreover, molecular devices fabricated using DNA base sequences have generated significant interest because DNA can be used for molecular programming [6�C11]. DNA base sequences can be used to design two-dimensional and three-dimensional DNA nanostructures in solution. DNA structures are designed using a rigid motif including several DNA junctions and building blocks. However, DNA nanostructures are too rigid to drive dynamically. Therefore, stimuli-responsive polymer-based materials have been investigated for the fabrication of molecular devices and molecular machines [12�C16].
The properties and functions of stimuli-responsive polymeric materials can be altered by external stimuli. Recently, thermoresponsive poly(N-isopropylacrylamide) (PNIPAAm) has been investigated, especially for use in microfluidic devices [17,18]. In order to drive stimuli-responsive polymer materials, external devices for controlling the external stimuli are needed.In contrast, organic systems can generate autonomous motion without external stimuli. In order to produce autonomous molecular machines resembling living organisms, self-oscillating polymeric materials have been developed and investigated [19�C21]. The energy source in these self-oscillating polymer materials is the Belousov�CZhabotinsky (BZ) reaction. The BZ reaction is a well-known oscillating reaction that is accompanied by spontaneous redox oscillations to generate a wide variety of nonlinear phenomena [22�C27].
The overall process of the BZ reaction is the oxidation of an organic substrate by an oxidizing Anacetrapib agent in the presence of a catalyst under strongly acidic conditions. In the BZ reaction, changes in the oxidation state of ruthenium tris(2,2��-bipyridine), the metal catalyst in the BZ reaction, occur periodically. As the oxidation state of the Ru catalyst changes, the solubility of the Ru catalyst changes simultaneously. In previous studies, polymer chains covalently bonded to the Ru catalyst were synthesized to convert the chemical energy to the driving force for the polymer chain oscillations [21]. As the oxidation state of the Ru catalyst moiety changes in the BZ reaction, the solubility of the polymer chain changes concurrently.
As a result, the self-oscillating polymer chains undergo aggregation and disaggregation upon self-oscillation induced by the BZ reaction under constant temperature conditions. In previous investigations, Hara et al. developed self-oscillating polymer chains with acrylamide-2-methylpropane sulfonic acid (AMPS) [28]. The AMPS-containing polymer chains could control the self-oscillation and cause the viscosity self-oscillation under the acid-free conditions [29,30].