Considering linearized motion about a resting basic state, we derive analytical solutions of the equatorial -plane primitive equations under the assumption that the o w is steady in a reference frame moving eastward with a diabatic forcing resembling a super cloud cluster. The solutions are analyzed in terms of potential vorticity (PV) dynamics. Because the diabatic source term for PV contains a factor y, the diabatic heat source is ineectiv e at generating a PV anomaly at the equator but maximizes the PV response near the poleward edges of the heat source. In this way a moving heat source can produce two ribbons of lower tropospheric PV anomaly, a positive one o the equator in the northern hemisphere and a negative one o the equator in the southern hemisphere, with oppositely signed PV anomalies in the upper troposphere. Associated with these PV anomalies are geopotential anomalies that are shifted several hundred kilometers poleward. In the lower troposphere these zonally elongated geopotential anomalies resemble ITCZ trough zones, which demonstrates the close connection between the MJO wake dynamics and the formation of double ITCZs. To demonstrate that the MJO wake response can be described by simple PV dynamics, we propose an invertibility principle relating the PV to the streamfunction, which in turn is locally related to the geopotential. This equatorial invertibility principle accurately recovers the balanced wind and mass elds found in the MJO wake in the primitive equation model. However, while the invertibility principle highlights the ability of simple PV dynamics to accurately describe the o w in the wake of an MJO super cloud cluster, it also clearly illustrates the inability of such dynamics to describe the Kelvin-like o w pattern ahead of the cluster.