NiI₃ Crystals

Description

NiI₃ Crystals (Nickel Triiodide)

NiI₃ is a layered transition metal halide with a van der Waals structure, known for its unique magnetic and electronic properties. As a two-dimensional material, NiI₃ exhibits antiferromagnetic ordering and is highly sought after for quantum material research, spintronics, and advanced 2D applications. Our NiI₃ crystals are synthesized using high-temperature vapor transport methods to ensure high purity, exceptional structural quality, and reliable physical properties.

Sample Size Options:
Crystals larger than 10 mm²
Crystals larger than 25 mm²
Crystals larger than 100 mm²

Material Properties:
Layered Van der Waals Structure: Suitable for exfoliation into thin layers.
Magnetic Properties: Intrinsic antiferromagnetic ordering.
Semiconducting Behavior: Suitable for electronic and optoelectronic studies.
Environmental Sensitivity: Requires storage and handling in an inert environment to maintain stability.

Crystal Structure:
Type: Layered monoclinic structure
Features: Cleavable into thin layers, ideal for 2D material research.

Degree of Exfoliation:
Ease of Use: Easily exfoliates into monolayers or few-layer sheets for advanced device fabrication.

Other Characteristics:
Magnetic Ordering: Displays antiferromagnetic properties below its Néel temperature (~20–30 K).
Optoelectronic Potential: Exhibits unique optical absorption properties suitable for nanoscale devices.
Chemical Stability: Stable under inert conditions, requiring vacuum or argon storage.

Applications:
Spintronics:
Promising for spin-based devices and quantum magnetic applications.
Quantum Materials Research:
Enables exploration of low-dimensional magnetism and electronic correlations in layered materials.
2D Material Studies:
Ideal for exfoliation into thin layers for heterostructures and van der Waals assembly.
Optoelectronics:
Suitable for light-sensing and nanoscale photonic devices.
Sensors:
High sensitivity to environmental stimuli, making it ideal for magnetic and optical sensing applications.