In a breakthrough that promises to redefine the landscape of two-dimensional (2D) materials, researchers have unveiled a novel method to fabricate mosaic lateral heterostructures within 2D lead halide perovskites. This pioneering work resolves longstanding challenges linked to patterning these sensitive materials, offering a versatile platform for future optoelectronic and light-emitting devices.
Lateral heterostructures, in which two or more distinct materials grow adjacently sharing an interface within the same atomic plane, have been pivotal in advancing nanoscience. Their significance spans exploring exotic quantum phenomena to enhancing device efficiencies and miniaturization. However, the synthesis of such heterostructures within 2D lead halide perovskites—a class of materials known for their exceptional optoelectronic properties—has long been hindered by the inherent softness and ionic nature of their crystal lattices. Conventional lithography and etching strategies, typically used to create patterned templates for sequential material growth, tend to damage or degrade the delicate perovskite layers.
Addressing this, the new study introduces a spontaneous strain-induced etching mechanism that generates square holes systematically within a continuous 2D perovskite layer. These nanoscale voids act as natural templates for the lateral epitaxial growth of a different perovskite variant, differing in halide or metal ion composition. The result is a seamless mosaic of heterostructures, where adjacent crystalline domains are laterally integrated, preserving atomically sharp interfaces essential for high-performance electronic behavior.
Central to this development is the discovery of an intrinsic strain field within the perovskite layer, which triggers etching preferentially along the crystallographic [100] and [010] directions. This highly anisotropic process is unusual compared to conventional isotropic etching and leads to stable square-shaped cavities without the need for aggressive external patterning. The size of these square holes is tunable based on the applied etching duration and the temperature conditions, providing a controllable means to engineer the spatial layout of the heterostructure arrays.
Further advancement was achieved by integrating a rapid solvent evaporation growth technique. This method leverages the edges of the etched square holes as nucleation centers for the epitaxial growth of a chemically distinct perovskite phase. The epitaxy ensures coherence and crystallographic alignment at the heterojunction boundaries, minimizing defects and enabling efficient charge carrier transfer. This approach exemplifies a departure from traditional sequential edge growth limited in scale and design complexity.
The ramifications for optoelectronic applications are substantial. The mosaic heterostructures fabricated demonstrated multi-color photoluminescence, essential for next-generation light-emitting diodes (LEDs) and display technologies. The ability to seamlessly integrate diverse perovskite phases in a single planar architecture lays the groundwork for intricate device circuits and quantum light sources, where precise control over emission wavelengths and junction properties is critical.
This work also provides valuable insights into the fundamental structural physics of 2D perovskites. The correlation between internal strain fields and spontaneous morphological patterning expands understanding of lattice dynamics and stability in soft, ionically bonded crystals. It opens fresh avenues to manipulate perovskite microdomains by harnessing intrinsic material stresses rather than relying solely on external lithographic interventions.
Moreover, scalability is a compelling aspect of this technique. Unlike epitaxial approaches constrained by substrate size or patterning precision, spontaneous strain-directed etching coupled with controlled epitaxial growth on hole edges can be extended over large wafer areas. This holds great promise for industrial-scale synthesis of complex heterostructure arrays necessary for commercial electronics and photonics.
The interdisciplinary nature of this advance bridges materials chemistry, crystallography, and device physics. It represents a leap forward compared to previous reports focused on transition-metal dichalcogenides or covalent 2D materials, where more robust crystal lattices facilitated lithography-based patterning. By developing a gentle, internal mechanism that maintains perovskite integrity during pattern formation, the study solves a technical bottleneck hindering deeper exploration of perovskite heterointerfaces.
In conclusion, the creation of mosaic lateral heterostructures within 2D lead halide perovskites via strain-managed spontaneous etching and epitaxial growth introduces a new horizon in nanomaterial engineering. This method enables precise spatial control, versatile compositional tuning, and preserves lattice coherence essential for high-functionality optoelectronic devices. As the rapid evolution of halide perovskite technologies continues, these findings empower the design of bespoke integrated photonic structures with unprecedented complexity and performance.
This transformative approach is poised to energize research directions not only in fundamental physics but also applied quantum materials and photonics, potentially impacting energy-efficient displays, lasers, and quantum information technologies. With the ability to construct stable, tunable heterojunction mosaics on a scalable platform, the field edges closer to new classes of integrated devices that amalgamate diverse functionalities in ultrathin, flexible form factors.
Subject of Research: Mosaic lateral heterostructures in two-dimensional lead halide perovskites achieved via strain-induced spontaneous etching and epitaxial growth.
Article Title: Mosaic lateral heterostructures in two-dimensional perovskite.
Article References:
Zhang, S., Lu, Y., Zhang, L. et al. Mosaic lateral heterostructures in two-dimensional perovskite. Nature 649, 612–620 (2026). https://doi.org/10.1038/s41586-025-09949-1
Image Credits: AI Generated
DOI: 10.1038/s41586-025-09949-1
Keywords: two-dimensional perovskites, lateral heterostructures, strain-induced etching, epitaxial growth, mosaic heterostructures, lead halide perovskites, optoelectronics, light-emitting devices, nanoscale patterning, crystallographic anisotropy, soft ionic lattices, rapid solvent evaporation.
Tags: 2D perovskites fabricationatomic plane interfacesenhancing device efficienciesheterostructure synthesis challengeslead halide perovskiteslight-emitting devicesmosaic lateral heterostructuresnanoscale voids in materialsoptoelectronic devicespatterned templates for growthquantum phenomena in nanosciencestrain-induced etching mechanism
