Abstract
Over the past two decades, both fundamental and applied research in conducting polymers have grown rapidly. Conducting polymers (CPs) are unique due to their ease of synthesis, environmental stability, and simple doping/dedoping chemistry. Electrically conductive silicone polymers are the current state-of-the-art for, e.g., optoelectronic materials. The combination of inorganic elements and organic polymers leads to a highly electrically conductive composite with improved thermal stability. Silicone-based materials have a set of extremely interesting properties, i.e., very low surface energy, excellent gas and moisture permeability, good heat stability, low-temperature flexibility, and biocompatibility. The most effective parameters constructing the physical properties of CPs are conjugation length, degree of crystallinity, and intra- and inter-chain interactions. Conducting polymers, owing to their ease of synthesis, remarkable environmental stability, and high conductivity in the doped form, have remained thoroughly studied due to their varied applications in fields like biological activity, drug release systems, rechargeable batteries, and sensors. For this reason, this review provides an overview of organosilicon polymers that have been reported over the past two decades.
Highlights
Silicon, as the second most common element in the earth’s crust, forms bonds mainly with oxygen, hydrogen, and carbon
The parameters of individual polymers are varied, which proves that the selection of appropriate side chains is of great importance when designing high-performance Organic solar cells (OSC)
Among all materials belonging to aggregationinduced emission (AIE), silole-based compounds are readily used in organic light-emitting diode (OLED) due to their high thermal stability, good electronic mobility, and affinity, and they exhibit high solid-state fluorescence quantum efficiency—some compounds achieve efficiency up to 100% [76,77]
Summary
As the second most common element in the earth’s crust, forms bonds mainly with oxygen (siloxanes), hydrogen (silanes), and carbon (silanes and siloles). Due to their physicochemical properties, silicone structures have found wide application in materials science [1], optoelectronic technology [2], medicine [3], and environmental protection [4]. The torsional potential of Si–O bonds is significantly lower than that of C–C bonds Due to these properties, siloxanes are flexible chains and have high thermal stability [10]. The work focuses on polymers that have been used mainly in organic light-emitting diode (OLED), organic photovoltaic (OPV), and sensors
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