Litcius/Paper detail

Mechanically Reconfigurable Organic Photonic Integrated Circuits Made from Two Electronically Different Flexible Microcrystals

Jada Ravi, Mari Annadhasan, Avulu Vinod Kumar, Rajadurai Chandrasekar

2021Advanced Functional Materials104 citationsDOI

Abstract

Abstract Fabrication of microscale organic photonic integrated circuits (μ‐OPIC) from two electronically different flexible crystals via a mechanophotonics approach is demonstrated here. The experiments focus on the mechanical micromanipulation of orange‐emitting ( E )‐1‐(4‐(dimethylamino)‐phenyl)iminomethyl‐2‐hydroxyl‐naphthalene (DPIN) and green‐emitting ( E )‐1‐(4‐bromo)iminomethyl‐2‐hydroxyl‐naphthalene (BPIN) crystals with atomic force cantilever tip. The flexibility of these crystals originate from molecular H‐bonding, CH∙∙∙π, and π···π stacking interactions. These mechanically compliant crystals form exceedingly bent and photonically relevant reconfigurable geometries during micromanipulation, including three μ‐OPICs. Remarkably, these μ‐OPICs operate through passive‐, active‐waveguiding and energy transfer mechanisms. Depending upon the crystal's electronic nature (either BPIN or DPIN) receiving the optical signal input, the circuit executes mechanism‐selective and direction‐specific optical outputs. The presented proof‐of‐principle concepts can be used to fabricate complex photonic circuits with diverse, flexible crystals performing multiple optical functions.

Topics & Concepts

Materials scienceMicroscale chemistryStackingElectronic circuitCantileverBent molecular geometryNanotechnologyFabricationOptoelectronicsPhotonic crystalPhotonic integrated circuitPhotonicsElectrical engineeringChemistryComposite materialMathematicsMathematics educationOrganic chemistryMedicinePathologyAlternative medicineEngineeringMechanical and Optical ResonatorsForce Microscopy Techniques and ApplicationsPhotonic and Optical Devices