Re-Doped MoSe₂ Crystals

Description

Re-Doped MoSe₂ Crystals (Rhenium-Doped Molybdenum Diselenide)

Re-doped MoSe₂ is a layered transition metal dichalcogenide (TMDC) with a van der Waals structure. Rhenium doping introduces n-type conductivity, enhances carrier dynamics, and modifies the electronic and optical properties of MoSe₂. These features make Re-doped MoSe₂ highly valuable for optoelectronics, quantum materials research, and energy-related applications.

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: Facilitates exfoliation into thin layers for 2D material studies.
N-Type Conductivity: Rhenium doping introduces free electrons, enhancing electronic performance.
Enhanced Catalytic Efficiency: High activity for hydrogen evolution reactions (HER) and electrocatalytic processes.
Tunable Bandgap: Rhenium doping adjusts the band structure, improving photoluminescence and optical absorption.

Crystal Structure:
Type: Hexagonal layered structure
Features: Cleavable layers, ideal for thin-film fabrication and nanoscale studies.

Degree of Exfoliation:
Ease of Use: Readily exfoliates into monolayers or few-layer sheets for advanced research and device integration.

Other Characteristics:
Quantum Research Potential: Enables studies of doping-induced electronic transport and quantum effects.
Optoelectronic Properties: Strong photoluminescence and carrier mobility for high-performance devices.
Energy Applications: Promising for catalytic and energy conversion technologies.

Applications:
Optoelectronics:
Ideal for photodetectors, light-emitting diodes, and photovoltaic devices.
Quantum Materials Research:
Suitable for studying quantum phenomena and doping effects in TMDCs.
Energy Applications:
High catalytic activity for HER and electrocatalytic applications.
2D Material Studies:
Perfect for integration into van der Waals heterostructures and nanoscale devices.
Spintronics:
Promising for exploring spin-based devices and spin-orbit coupling effects.