3D Printed Room Temperature Phosphorescence Materials Enabled by Edible Natural Konjac Glucomannan

Shaping room temperature phosphorescence (RTP) materials into 3D bodies is important for stereoscopic optoelectronic displays but remains challenging due to their poor processability and mechanical properties. Here, konjac glucomannan (KGM) is employed to anchor arylboronic acids with various pi conjugations via a facile B & horbar;O covalent reaction to afford printable inks, using which full-color high-fidelity 3D RTP objects with high mechanical strength can be obtained via direct ink writing-based 3D printing and freeze-drying. The doubly rigid structure supplied by the synergy of hydrogen bonding and B & horbar;O covalent bonding can protect the triplet excitons; thus, the prepared 3D RTP object shows a striking lifetime of 2.14 s. The printed counterparts are successfully used for 3D anti-counterfeiting and can be recycled and reprinted nondestructively by dissolving in water. This success expands the scope of printable 3D luminescent materials, providing an eco-friendly platform for the additive manufacturing of sophisticated 3D RTP architectures. An ingenious design strategy is developed to construct sophisticated 3D room temperature phosphorescence (RTP) architectures with high fidelity and mechanical strength via direct ink writing-based 3D printing and freeze-drying. Konjac glucomannan with decent rheological properties can anchor arylboronic acid chromophores with various pi conjugations via B & horbar;O covalent bonds in pure water to afford 3D-printable inks. image