Formation of Small-Scale Condensations in the Molecular Clouds via Thermal Instability

A systematic study of the linear thermal instability of a self-gravitating magnetic molecular cloud is carried out for the case when the unperturbed background is subject to local expansion or contraction. We consider the ambipolar diffusion, or ion-neutral friction on the perturbed states. In this way, we obtain a non-dimensional characteristic equation that reduces to the prior characteristic equation in the non-gravitating stationary background. By parametric manipulation of this characteristic equation, we conclude that there are, not only oblate condensation forming solutions, but also prolate solutions according to local expansion or contraction of the background. We obtain the conditions for existence of the Field lengths that thermal instability in the molecular clouds can occur. If these conditions establish, small-scale condensations in the form of spherical, oblate, or prolate may be produced via thermal instability.Comment: 16 page, accepted by Ap&S

Crystal-field splitting in Pr dideuteride

From inelastic neutron scattering experiments, it is concluded that the crystal-field splitting in PrD/sub 1.95/ is 41 meV. Because of this high value, the antiferromagnetic ordering below T/sub N/ = 2.3 K is ascribed to a magnetic ground state, probably GAMMA/sub 5/, of the Pr/sup 3 +/ ions