Detection of chiral anomaly and valley transport in Dirac semimetals

Chiral anomaly is a non-conservation of chiral charge pumped by the topological nontrivial gauge field. As an analogy to the similar phenomenon in high-energy physics, the chiral anomaly in condensed matter is predicted to exist in the emergent quasiparticle excitations in Dirac and Weyl semimetals. However, the current understanding of such concept mostly remains in the theoretical consideration, which lacks of convincing experimental identification. Here, for the first time, we experimentally observe the existence of the chiral anomaly and the related valley transport in Cd3As2. We find that the chiral imbalance induced by external electric and magnetic fields leads to a non-zero gyrotropic coefficient {\gamma}, which can be confirmed by the field-generated Kerr effect. By applying B along the current direction, we observe a negative magnetoresistance despite the giant positive one at other directions, a clear indication of the chiral anomaly. Remarkably, a robust nonlocal response from valley diffusion originated from the chiral anomaly is observed up to room temperature when B is parallel to E. Our discovery of the chiral anomaly in Cd3As2 Dirac semimetal opens up a brand-new route to understand its fundamental properties with a controllable chiral imbalance through external fields and utilize the chiral fermions in valleytronic applications.