Circularly
polarized light (CPL) is an inherently chiral entity
and is considered one of the possible deterministic signals that led
to the evolution of homochirality. While accumulating examples indicate
that chirality beyond the molecular level can be induced by CPL, not
much is yet known about circumstances where the spin angular momentum
of light competes with existing molecular chiral information during
the chirality induction and amplification processes. Here we present
a light-triggered supramolecular polymerization system where chiral
information can both be transmitted and nonlinearly amplified in a
“sergeants-and-soldiers” manner. While matching handedness
with CPL resulted in further amplification, we determined that opposite
handedness could override molecular information at the supramolecular
level when the enantiomeric excess was low. The presence of a critical
chiral bias suggests a bifurcation point in the homochirality evolution
under random external chiral perturbation. Our results also highlight
opportunities for the orthogonal control of supramolecular chirality
decoupled from molecular chirality preexisting in the system.
Introduction of asymmetry into a supramolecular system via external chiral stimuli can contribute to the understanding of the intriguing homochirality found in nature. Circularly polarized light (CPL) is regarded as a chiral physical force with right-or left-handedness. It can induce and modulate supramolecular chirality due to preferential interaction with one enantiomer. Herein, this review focuses on the photon-to-matter chirality transfer mechanisms at the supramolecular level. Thus, asymmetric photochemical reactions are reviewed, and the creation of a chiral bias upon CPL irradiation is discussed. Furthermore, the possible mechanisms for the amplification and propagation of the bias into the supramolecular level are outlined based on the nature of the photochromic building block. Representative examples, including azobenzene derivatives, polydiacetylene, bicyclic ketone, polyfluorenes, C n -symmetric molecules, and inorganic nanomaterials, are presented.
For highly-integrated microfluidic systems, an actuation system is necessary to control the flow; however, the bulk of actuation devices including pumps or valves has impeded the broad application of integrated microfluidic systems. Here, we suggest a microfluidic process control method based on built-in microfluidic circuits. The circuit is composed of a fluidic timer circuit and a pneumatic logic circuit. The fluidic timer circuit is a serial connection of modularized timer units, which sequentially pass high pressure to the pneumatic logic circuit. The pneumatic logic circuit is a NOR gate array designed to control the liquid-controlling process. By using the timer circuit as a built-in signal generator, multi-step processes could be done totally inside the microchip without any external controller. The timer circuit uses only two valves per unit, and the number of process steps can be extended without limitation by adding timer units. As a demonstration, an automation chip has been designed for a six-step droplet treatment, which entails 1) loading, 2) separation, 3) reagent injection, 4) incubation, 5) clearing and 6) unloading. Each process was successfully performed for a pre-defined step-time without any external control device.
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