Motivated by the recent results of \citet{Lesur_Ogilvie10} on the transport
properties of incompressible convection in protoplanetary discs, in this paper
we study the role of compressibility and hence of another basic mode -- spiral
density waves -- in convective instability in discs. We analyse the linear
dynamics of non-axisymmetric convection and spiral density waves in a Keplerian
disc with superadiabatic vertical stratification using the local shearing box
approach. It is demonstrated that the shear associated with Keplerian
differential rotation introduces a novel phenomenon, it causes these two
perturbation modes to become coupled: during evolution the convective mode
generates (trailing) spiral density waves and can therefore be regarded as a
new source of spiral density waves in discs. The wave generation process
studied here owes its existence solely to shear of the disc's differential
rotation, and is a special manifestation of a more general linear mode coupling
phenomena universally taking place in flows with an inhomogeneous velocity
profile. We quantify the efficiency of spiral density wave generation by
convection as a function of azimuthal and vertical wavenumbers of these modes
and find that it is maximal and most powerful when both these length-scales are
comparable to the disc scale height. We also show that unlike the convective
mode, which tends to transport angular momentum inwards in the linear regime,
the spiral density waves transport angular momentum outwards. Based on these
findings, we suggest that in the non-linear regime spiral density waves
generated by convection may play a role in enhancing the transport of angular
momentum due the convective mode alone, which is actually being changed to
outward by non-linearity, as indicated by above-mentioned recent developments.Comment: 17 pages, 8 figures, accepted for publication in MNRA