Title: Electronic nematicity in the absence of charge density waves in a new titanium-based kagome metal

Abstract: Layered crystalline materials that consist of transition metal atoms laid out on a kagome network emerged as a versatile platform to study novel electronic phenomena. Within this realm, vanadium-based kagome superconductors AV3Sb5 (A=K, Cs, Rb) recently attracted a large interest for various exotic electronic states. These states arise within a parent charge density wave (CDW) phase that appears to simultaneously break both the translational and the rotational symmetry of the lattice. We use spectroscopic-imaging scanning tunneling microscopy to study a newly synthesized kagome metal CsTi3Bi5, which is isostructural to AV3Sb5 but with a titanium atom kagome network. In sharp contrast to its vanadium-based counterpart, CsTi3Bi5 does not exhibit detectable CDW states. By imaging the scattering and interference of electrons, we obtain momentum-space information about the low-energy electronic structure of CsTi3Bi5. A comparison to our density functional theory calculations reveals substantial electronic correlation effects at low-energies in this material. Remarkably, by comparing the amplitudes of scattering wave vectors along different directions, we discover a pronounced electronic anisotropy that breaks the six-fold symmetry of the lattice, arising from both in-plane and out-of-plane titanium-derived d orbitals. Our experiments reveal the emergence of a genuine electronic nematic order in CsTi3Bi5, the first among the "135" family of kagome metals, which is in contrast to the vanadium-based AV3Sb5 where rotation symmetry breaking appears to be intertwined with the CDW. Our work also uncovers the significant role of electronic orbitals in the kagome metal CsTi3Bi5, suggestive of a hexagonal analogue of the nematic bond order in Fe-based superconductors.