Reply to "Origin of logarithmic resistance correction in graphene"

Chen et al. reply —

We reported¹ that irradiation-induced vacancies in graphene have local moments that couple to conduction electrons through the Kondo effect, with a resistivity increasing logarithmically with decreasing temperature and saturating at low temperature. The local moment of graphene vacancies has since been verified in susceptibility measurements²; however, that experiment was agnostic on the Kondo effect, which would be difficult to probe magnetically as vacancies significantly outnumbered carriers. Weber et al. comment that our resistivity data might be confounded by Altshuler–Aronov corrections³, recently measured in graphene on SiO₂ (ref. 4) and SiC (refs 5, 6, 7). The Altshuler–Aronov effect gives graphene's resistivity as:

where ρ_xx,0 is the uncorrected longitudinal resistivity, A ≤ 1 a constant, e the elemental charge, T temperature, μ the charge carrier mobility, B the magnetic field, and τ_tr the transport momentum relaxation time. Here we show that equation (1) cannot explain the magnitude of the logarithmic resistivity and magnetoresistance, or the saturation of the resistivity at low temperature for our devices.

Figure 1a shows fits of equation (1) to our ρ_xx(B) for 1 T < B < 6 T at T = 300 mK, for four different gate voltages (V_g); the global fit parameter is A = 0.32 (A is systematically smaller, and magnetoresistance overestimated, for small V_g − V_g,min). Our devices are etched Hall bars with an aspect ratio exceeding three; geometric errors in ρ_xx are at most a few per cent. A = 0.32 is reasonably consistent with other experiments; Kozikov et al.⁴ analysed ρ_xx(T) and found 0.35 < A < 1.05 for graphene on SiO₂, and Jobst et al.⁷ found that 0.35 < A < 0.92 for graphene on SiC. The Kondo effect itself also produces negative magnetoresistance, so we consider A = 0.32 to be an upper bound. Figure 1b shows ρ_xx(T) for the same four V_g and the Altshuler–Aronov correction from equation (1) with A = 0.32. The Altshuler–Aronov effect accounts for at most 12–16% of the logarithmic divergence of the resistivity in our data. Likewise, had we had fit ρ_xx(T), we would find 1.9 < A < 2.5, and would drastically overestimate the observed magnetoresistance. A > 1 is unphysical and a priori rules out the Altshuler–Aronov effect as the sole source of logarithmic ρ_xx(T).

Figure 1: Temperature and magnetic-field dependent resistivity of graphene with defects.

a, Magnetoresistance of graphene sample Q6 with defects at a temperature T = 300 mK and at gate voltages V_g − V_g,min = −15.3 V (blue stars), −25.3 V (purple triangles), −35.3 V (red circles) and −45.3 V (green crosses); V_g,min = 5.3 V is the gate voltage of minimum conductivity. b, Temperature-dependent resistivity of graphene under 1 T of transverse magnetic field and at the same four V_g values in a. In a and b the solid lines are equation (1) with A = 0.32, chosen to fit the data in a. c, Experimentally determined Kondo temperatures (T_K) for sample Q6 (red squares) and L2 (blue circles). The solid lines are the expected T_sat from the Altshuler–Aronov effect for samples Q6 (red) and L2 (blue). Data taken from ref. 1.

Now we discuss the saturation of ρ_xx(T). The Thouless length L_T sets the scale for Altshuler–Aronov corrections, which become T independent for L_T > l_sample (l_sample is the shortest sample dimension)⁸. Assuming⁹

the saturation temperature (T_sat) is

where v_F is the Fermi velocity and E_F is the Fermi energy. We reported data for two samples: Q6 (μ = 2,000 cm² Vs⁻¹ and l_sample = 2.0 μm) and L2 (μ = 1,100 cm² Vs⁻¹ and l_sample = 6.5 μm). Figure 1c plots the experimentally determined Kondo temperature and the T_sat predicted by Altshuler–Aronov theory as a function of gate voltage V_g ∝ E_F². Altshuler–Aronov theory predicts these two samples should show T_sat differing by a factor of 35 and strongly V_g dependent; neither is observed. Notably, saturation of ρ_xx(T) is not observed down to T = 0.2 K in exfoliated graphene on SiO₂ (ref. 4) or 1.5 K in graphene with l_sample = 5 μm on SiC (ref. 5). Thus the observed resistivity saturation is novel, and strong evidence for the Kondo effect in graphene with lattice defects. Other saturation mechanisms (such as coherence length l_Ф = l_sample as in weak localization) are also inconsistent with the data.