Abstract

Abstract The group IVB 2D transition metal dichalcogenides are considered to be stable in the high symmetry trigonal octahedral structure due to the lack of unpaired d ‐electrons on the metal site. It is found that multilayer epitaxial TiTe 2 is an exception adopting a commensurate 2 × 2 × 2 charge density wave (CDW) structure at room temperature with an ABA type of stacking as evidenced by direct lattice imaging and reciprocal space mapping. The CDW is stabilized by highly anisotropic strain imposed by the substrate with an out‐off‐plane compression which reduces the interlayer van der Waals gap increasing the coupling between TiTe 2 layers. A weaker 2 × 2 CDW is also confirmed at room temperature for epitaxial monolayer TiTe 2 . The addition of epitaxial strained TiTe 2 to the family of CDW materials will enable real world applications that take advantage of a CDW ground state at room temperature.