Autonomous self-repair in piezoelectric molecular crystals.
Surojit BhuniaShubham ChandelSumanta Kumar KaranSomnath DeyAkash TiwariSusobhan DasNishkarsh KumarRituparno ChowdhurySaikat MondalIshita GhoshAmit MondalBhanu Bhusan KhatuaNirmalya GhoshC Malla ReddyPublished in: Science (New York, N.Y.) (2021)
Living tissue uses stress-accumulated electrical charge to close wounds. Self-repairing synthetic materials, which are typically soft and amorphous, usually require external stimuli, prolonged physical contact, and long healing times. We overcome many of these limitations in piezoelectric bipyrazole organic crystals, which recombine following mechanical fracture without any external direction, autonomously self-healing in milliseconds with crystallographic precision. Kelvin probe force microscopy, birefringence experiments, and atomic-resolution structural studies reveal that these noncentrosymmetric crystals, with a combination of hydrogen bonds and dispersive interactions, develop large stress-induced opposite electrical charges on fracture surfaces, prompting an electrostatically driven precise recombination of the pieces via diffusionless self-healing.
Keyphrases
- stress induced
- single molecule
- room temperature
- ionic liquid
- living cells
- physical activity
- mental health
- dna damage
- genome wide
- dna repair
- hip fracture
- quantum dots
- single cell
- biofilm formation
- dna methylation
- oxidative stress
- mass spectrometry
- cystic fibrosis
- label free
- liquid chromatography
- fluorescent probe
- tandem mass spectrometry