“…While many efforts have been focused on studying transition metal trihalides (e.g., CrI 3 ), ,,− they have often been shown to be unstable and degrade within minutes in air and/or when exposed to light, requiring either in situ measurements in an oxygen-free environment or encapsulation between protective layers to prevent deterioration. , Conversely, transition metal telluride compounds are expected to be relatively more stable in ambient conditions. Among various vdW magnetic tellurides, the binary chromium telluride 1T-CrTe 2 has a ferromagnetic ordering temperature T c above room temperature, − which is significantly higher than that of the previously studied ternary chromium tellurides Cr 2 X 2 Te 6 (X = Si, Ge). ,,− Furthermore, a colossal anomalous Hall conductivity was recently observed in 1T-CrTe 2 with simultaneously large anomalous Hall angles and electrical conductivities distinct from other anomalous Hall materials, making it an excellent candidate for spintronics applications. , By intercalating Cr atoms into the vdW gap between the CrTe 2 layers, as shown in Figure a, different chromium telluride compounds Cr 1+δ Te 2 (0 < δ ≤ 1) are created. These different Cr 1+δ Te 2 phases have a broad range of magnetic ordering temperatures and novel magnetic phases. ,,,− For example, CrTe (or Cr 2 Te 2 ) thin films have been reported to exhibit the topological Hall effect, noted as strong evidence of a magnetic skyrmion phase .…”