The researchers performed simultaneous measurements of tunneling spectroscopy and transport properties in magic-angle twisted trilayer graphene (MATTG).2[1] They found the coexistence of two V-shaped gaps with different energy scales: a low-energy superconducting gap, which disappears at a superconducting critical temperature and magnetic field, and a higher-energy pseudo-gap.[2][1] The superconducting gap exhibits linear filling as a function of temperature and magnetic field and displays the Volovik effect, which is consistent with the nodal order parameter.[2][1] Both gaps depend on the doping level similarly to the superconducting critical temperature.The low-energy gap fills rapidly in the scale of the critical magnetic field Bc,⊥, while the higher ∆HG gap is insensitive to it even at fields much larger than Bc,⊥.1 These observations confirm the non-conventional nature of the superconducting gap in moiré graphene.[2][3