Solution Synthesis of NdTe Magnetic Nanosheets

Overview

Journal Chem Mater

Date 2024 Jul 29

PMID 39070667

Authors

Joel Swanson

Salah Eddin El Jamal

Tyler Hartman

Orlando C Stewart

Priscilla Glaser

Adam J Biacchi

DaVonne Henry

Amy Liu

Sarah L Stoll

Affiliations

Soon will be listed here.

Abstract

Neodymium tritelluride is a layered van der Waals material, with correlated electronic properties including high electronic mobility, charge density waves, and antiferromagnetism. We developed a solution synthesis method to form free-standing nanosheets of NdTe, with nanosheet lateral dimensions of 200-400 nm. The morphology of the nanosheet was influenced by the neodymium precursor. When Nd[(N(SiMe)] was used as the metal source the nanosheet thickness average was 12 ± 2.5 nm, alternatively the combination of NdCl and Li(N(SiMe)) led to thicker nanosheets, approximately 19 ± 2.4 nm. We believe that the difference in thickness and changes in surface chemistry point to the role of chloride in accelerating nanocrystal growth for the synthesis with NdCl (and Li(N(SiMe)). Both types of nanosheets exhibit charge density wave (CDW) distortions as measured using electron diffraction and investigated using variable temperature Raman scattering. Interestingly, the magnetic studies suggest a distinct change in properties between 12 and 19 nm thickness in antiferromagnetic NdTe.

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