We report on the observation of Feshbach resonances in an ultracold mixture of two fermionic species, 6 Li and 40 K. The experimental data are interpreted using a simple asymptotic bound state model and full coupled channels calculations. This unambiguously assigns the observed resonances in terms of various s-and p-wave molecular states and fully characterizes the ground-state scattering properties in any combination of spin states.PACS numbers: 34.50. 05.30.Fk Fermion pairing and Fermi superfluidity are key phenomena in superconductors, liquid 3 He, and other fermionic many-body systems. Our understanding of the underlying mechanisms is far from being complete, in particular for technologically relevant high-T c superconductors. The emerging field of ultracold atomic Fermi gases has opened up unprecedented possibilities to realize versatile and well-defined model systems. The control of interactions, offered in a unique way by Feshbach resonances in ultracold gases, is a particularly important feature. Such resonances have been used to achieve the formation of bosonic molecules in Fermi gases and to control pairing in many-body regimes [1,2,3,4,5].So far all experiments on strongly interacting Fermi systems have been based on two-component spin mixtures of the same fermionic species, either 6 Li or 40 K [1, 2]. Control of pairing is achieved via a magnetically tunable s-wave interaction between the two states. After a series of experiments on balanced spin mixtures with equal populations of the two states, recent experiments on 6 Li have introduced spin imbalance as a new degree of freedom and begun to explore novel superfluid phases [6,7]. Mixing two different fermionic species leads to unprecedented versatility and control. Unequal masses and the different responses to external fields lead to a large parameter space for experiments and promise a great variety of new phenomena [8,9,10,11,12]. The combination of the two fermionic alkali species, 6 Li and 40 K, is a prime candidate to realize strongly interacting FermiFermi systems.In this Letter, we realize a mixture of 6 Li and 40 K and identify heteronuclear Feshbach resonances [14,15,16]. This allows us to characterize the basic interaction properties. Figure 1 shows the atomic ground-state energy structure. We label the energy levels Li|i and K|j , counting the states with rising energy. The hyperfine splitting of 6 Li is (3/2)a Li hf /h = 228.2 MHz. For 40 K, the hyperfine structure is inverted and the splitting amounts to (9/2)a K hf /h = −1285.8 MHz [17]. For the low-lying states with i ≤ 3 and j ≤ 10, the projection quantum numbers are given by m Li = −i + 3/2 and m K = j − 11/2. A Li|i K|j mixture can undergo rapid decay via spin relaxation if exoergic two-body processes exist that preserve the total projection quantum number M F = m Li + m K = −i + j − 4. Whenever one of the species is in the absolute ground state and the other one is in a low-lying state (i = 1 and j ≤ 10 or j = 1 and i ≤ 3), spin relaxation is strongly suppressed [18].
