The outbreak of the coronavirus disease has drawn public attention to the transmission of
infectious pathogens, and as major carriers of those pathogens, respiratory droplets play
an important role in the process of transmission. This Review describes respiratory
droplets from a physical and mechanical perspective, especially their correlation with the
transmission of infectious pathogens. It covers the important aspects of (i) the
generation and expulsion of droplets during respiratory activities, (ii) the transport and
evolution of respiratory droplets in the ambient environment, and (iii) the inhalation and
deposition of droplets in the human respiratory tract. State-of-the-art experimental,
computational, and theoretical models and results are presented, and the corresponding
knowledge gaps are identified. This Review stresses the multidisciplinary nature of its
subject and appeals for collaboration among different fields to fight the present
pandemic.
The approach to improve the output power of piezoelectric energy harvester is one of the current research hotspots. In the case where some sources have two or more discrete vibration frequencies, this paper proposed three types of magnetically coupled multi-frequency hybrid energy harvesters (MHEHs) to capture vibration energy composed of two discrete frequencies. Electromechanical coupling models were established to analyze the magnetic forces, and to evaluate the power generation characteristics, which were verified by the experimental test. The optimal structure was selected through the comparison. With 2 m/s2 excitation acceleration, the optimal peak output power was 2.96 mW at 23.6 Hz and 4.76 mW at 32.8 Hz, respectively. The superiority of hybrid energy harvesting mechanism was demonstrated. The influences of initial center-to-center distances between two magnets and length of cantilever beam on output power were also studied. At last, the frequency sweep test was conducted. Both theoretical and experimental analyses indicated that the proposed MHEH produced more electric power over a larger operating bandwidth.
Soft robotics revolutionized human-robot interactions, yet there exist persistent challenges for developing high-performance soft actuators that are powerful, rapid, controllable, safe, and portable. Here, we introduce a class of self-contained soft electrofluidic actuators (SEFAs), which can directly convert electrical energy into the mechanical energy of the actuators through electrically responsive fluids that drive the outside elastomer deformation. The use of special dielectric liquid enhances fluid flow capabilities, improving the actuation performance of the SEFAs. SEFAs are easily manufactured by using widely available materials and common fabrication techniques, and display excellent comprehensive performances in portability, controllability, rapid response, versatility, safety, and actuation. An artificial muscle stretching a joint and a soft bionic ray swimming in a tank demonstrate their effective performance. Hence, SEFAs offer a platform for developing soft actuators with potential applications in wearable assistant devices and soft robots.
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