All Tables

• Table 1: Spectroscopic measurements of the ground vibrational state of CH₃CHDCN, CH₂DCH₂CN and CH₃CH₂C¹⁵N.
• Table 2: Spectroscopic constants of the ground vibrational state of CH₃CHDCN, CH₂DCH₂CN and CH₃CH₂C¹⁵N.
• Table 3: Measured transitions of the ground vibrational state of CH₃CH₂C¹⁵N.
• Table 4: Measured transitions of the ground vibrational state of CH₃CHDCN.
• Table 5: Measured transitions of the ground vibrational state of CH₂DCH₂CN in-plane.
• Table 6: Measured transitions of the ground vibrational state of CH₂DCH₂CN out-of-plane.
• Table 7: Sample table of the predicted transitions of the ground vibrational state of CH₃CH₂C¹⁵N.
• Table 8: Sample table of the predicted transitions of the ground vibrational state of CH₃CHDCN.
• Table 9: Sample table of the predicted transitions of the ground vibrational state of CH₂DCH₂CN in-plane.
• Table 10: Sample table of the predicted transitions of the ground vibrational state of CH₂DCH₂CN out-of-plane.
• Table 11: Observed transitions of CH₃CH₂C¹⁵N (without high blend) in the frequency range of the Orion KL survey. Column 1 indicates the transition, Col. 2 provides the assumed rest frequency, Col. 3 the line strength, Col. 4 the energy of the upper level, Col. 5 the observed (centroid) frequencies assuming that the radial velocities relative to LSR are 5 km s^-1, Col. 6 the observed peak line temperature of main beam, and Col. 7 indicates the main beam temperature derived from the model.