Regulating the conductivity of conducting polymers has
spurred increasing studies, aiming at meeting different demands in
various fields, including chemosensors, photovoltaic cells, and so
on. Herein, linear pillar[5]arene-containing conjugated polymers were
designed and synthesized via metathesis cyclopolymerization of pillar[5]arene-functionalized
1,6-heptadiyne. Upon addition of an ionic guest, such polymers could
form inclusion complexes, of which the glass transition temperature
decreased dramatically. With the aid of ionic guest and host–guest
complexations between the pendant pillararenes and guest, these supramolecular
materials exhibited tunable conductivity from 10–12 to 10–3 S·cm–1 at 30 °C.
In addition, compared with the polymers without pendant pillar[5]arenes,
such polymers showed better compatibility with the ionic guest, which
could prevent the leakage of the latter one and was good for the conductivity
of the material.
Linear polymers containing pillar[5]arenes as the pendant groups were designed and synthesized via ring-opening metathesis polymerization. Such polymers could form supramolecular brush polymers and exhibited tunable fluorescence property based on...
Constructing polymeric materials with stretchable and self-healing properties arise increasing interest in the field of tissue engineering, wearable electronics and soft actuators. Herein, a new type of supramolecular cross-linker was constructed through host-guest interaction between pillar[5]arene functionalized acrylate and pyridinium functionalized acrylate, which could form supramolecular polymeric material via photo-polymerization of n-butyl acrylate (BA). Such material exhibited excellent tensile properties, with maximum tensile strength of 3.4 MPa and strain of 3000%, respectively. Moreover, this material can effectively dissipate energy with the energy absorption efficiency of 93%, which could be applied in the field of energy absorbing materials. In addition, the material showed self-healing property after cut and responded to competitive guest.
In this work, a bidirectional grating coupler for perfectly vertical coupling is proposed. The coupling efficiency is enhanced using a silicon nitride (Si3N4) layer above a uniform grating. In the presence of Si3N4 layer, the back-reflected optical power into the fiber is diminished and coupling into the waveguide is increased. Genetic algorithm (GA) is used to optimize the grating and Si3N4 layer simultaneously. The optimal design obtained from GA shows that the average in-plane coupling efficiency is enhanced from about 57.5% (−2.5 dB) to 68.5% (−1.65 dB), meanwhile the average back-reflection in the C band is reduced from 17.6% (−7.5 dB) to 7.4% (−11.3 dB). With the help of a backside metal mirror, the average coupling efficiency and peak coupling efficiency are further increased to 87% (−0.6 dB) and 89.4% (−0.49 dB). The minimum feature size of the designed device is 266 nm, which makes our design easy to fabricate through 193 nm deep-UV lithography and lowers the fabrication cost. In addition, the coupler proposed here shows a wide-band character with a 1-dB bandwidth of 64 nm and 3-dB bandwidth of 96 nm. Such a grating coupler design can provide an efficient and cost-effective solution for vertical fiber-to-chip optical coupling of a Wavelength Division Multiplexing (WDM) application.
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