Elementary excitations in the spin-ice compound Dy 2 Ti2O7 can be described as magnetic monopoles propagating independently within the pyrochlore lattice formed by magnetic Dy ions. We studied the magnetic-field dependence of the thermal conductivity κ(B) for B || [001] and observe clear evidence for magnetic heat transport originating from the monopole excitations. The magnetic contribution κmag is strongly field-dependent and correlates with the magnetization M (B). The diffusion coefficient obtained from the ratio of κmag and the magnetic specific heat is strongly enhanced below 1 K indicating a high mobility of the monopole excitations in the spin-ice state.PACS numbers: 75.40.Gb, The recent prediction of magnetic monopoles in the spin-ice compounds has attracted a lot of interest [1][2][3][4][5][6][7][8][9][10]. Spin ice is a geometrically frustrated spin system, which is realized in Dy 2 Ti 2 O 7 by a sublattice of corner-sharing Dy 3+ tetrahedra. Due to a strong Ising anisotropy, the magnetic moments of Dy 3+ point either in or out of a tetrahedron. The magnetic dipole energy is minimized, when two spins point in and two out of a tetrahedron (2in-2out), what is realized by 6 out of 2 4 = 16 possible configurations for a single tetrahedron. In this respect, the spin orientation of Dy 3+ corresponds to the hydrogen displacement in water ice [11] and the ground state is highly degenerate with a residual entropy S 0 = N k B /2 ln(3/2) for T → 0 K [12-15]. Excited states can be created by flipping one spin, resulting in two adjacent tetrahedra with configurations 3in-1out and 1in-3out, respectively. In zero magnetic field, such a dipole excitation can fractionalize into two individual excitations, a monopole (3in-1out) and an anti-monopole (1in-3out), which can propagate independently. This can be visualized by flipping, e.g., another in-pointing spin of the 3in-1out tetrahedron such that it relaxes back to (another) 2in-2out ground state configuration, while the 3in-1out state has moved to a neighboring tetrahedron.The model of magnetic monopoles has been widely used to describe many experimental observations of Dy 2 Ti 2 O 7 [1-10]. Nevertheless, there are basic properties of the spin-ice materials, which are far from being understood. For example, the specific heat c p of Dy 2 Ti 2 O 7 has a pronounced maximum around 1.2 K resulting from the magnetic excitations and the corresponding entropy is close to the expected S 0 = 1.68 J K −1 mol −1 Dy [2,14,16,17]. Below ∼ 600 mK, however, c p (T ) data published by several groups differ by almost an order of magnitude, see figure 1 [2, 16-18]. Very recently it became clear that in this low-temperature regime the magnetic subsystem of Dy 2 Ti 2 O 7 enters a region of very slow dynamics with relaxation processes that may extend over extremely long time scales [10,17]. Another open issue is the dynamics of the magnetic monopoles.The possible observation of a monopole current in an external magnetic field is currently under strong debate [8, 9, 19]. In this context, i...
