ConspectusPorous organic polymers (POPs)
are organic networks distinguished
by their highly cross-linked structures and their intrinsic porosity.
The growing emphasis on POPs is driven by their exceptional hydrothermal
stability and diverse application prospects. However, traditional
metal-catalyzed high-temperature reactions using rigid building units
yield POPs in insoluble powder form, posing challenges for processing
into different shapes for device integration and optoelectronic applications.
The successful fabrication of a soluble porous organic polymer relies
on the employment of specific design strategies and reaction conditions
to restrict the molecular weight and extensive cross-linking. In recent
decades, researchers have been actively exploring various design strategies,
such as limiting molecular weight through hyperbranching and employing
controlled polymer growth strategies, to produce solution processable
amorphous porous organic polymers. However, targeted synthesis for
specific applications remains underdeveloped, justifying the need
for an in-depth deliberation of currently available strategies and
possible future avenues. In this context, this Account highlights
the advancements in the field of solution processable amorphous cross-linked
porous organic polymers (SCPOPs), describing diverse design strategies
and function-led applications. In order to address the challenges
associated with the solution processing of amorphous cross-linked
POPs, our research group has focused on fine-tuning the noncovalent
interactions among the molecular building blocks, the key to achieving
both porosity and solubility in the resultant porous polymer. Following
this principle, we introduce long alkyl chains as flexible groups
in the monomer and comonomer units that offer a high degree of rotational
freedom and a substantial twist angle. This approach facilitates alleviation
of the pronounced π–π stacking interaction and
extensive cross-linking, thereby enhancing the solubility of the porous
polymer. As a result, the facile interaction between the analytes
and inefficiently packed polymer chains with aromatic building units
in SCPOPs opens the scope for fluorescence-based nitroaromatic sensing
in solution. Further, a stable dispersion of fluorescent porous polymer
nanoparticles could be an attractive platform for analyte detection
in water with enhanced sensitivity. The porous nature of the fluorescent
SCPOPs enables the encapsulation of diverse dye molecules, and controlling
the energy transfer efficiency from polymer to dyes results in fluorescence
tuning, leading to the emission of white light in solution, nanoparticles,
gel, and a thin transparent film. Furthermore, we demonstrate that
incorporating alternate donor–acceptor units into the cross-linked
polymer leads to the optimum band positions for light-driven redox
reactions, such as photooxidation of benzylamine and hydrogen evolution.
We investigated a biphasic catalysis route employing solution-processable
POPs to enhance the efficiency while facilitating the recovery and
reusability of the photocatalysts. As detailed in this review, the
comprehensive inspection of the design strategies and potential applications
of SCPOPs paves the way to delve into designing new processable functional
porous materials, catering to the need for current sustainable development
goals.