Animation of Figure 6: by peridiocally varying the rotation rate of the system the fluid oscillates back and forth over two circular obstacles, generating inertial waves, Rossby waves, lee vortices and Taylor columns. Time is compressed by a factor of approximately 10 in this and succeeding videos.

Animation of Figure 6: by peridiocally varying the rotation rate of the system the fluid oscillates back and forth over two circular obstacles, generating inertial waves, Rossby waves, lee vortices and Taylor columns. Time is compressed by a factor of approximately 10 in this and succeeding videos.

Animation of Figure 11: Kelvin waves and inertial waves generated by high-frequemcy oscillation of the table rotation with a shallow fluid layer (H = 5 cm). rate, in the presence of a small (1 cm high) spherical-cap mountain near 6 o'clock. The Kelvin waves propagate with the speed of long gravity waves anticlockwise about the cylinder, trapped along the outer boundary. Note the inertial wave crests moving opposite to the group velocity, hence toward their source. The circular crests are the inertial wave reflected from the circular boundary, whose energy propagates inward toward the center. There are also visible small, cyclonic eddies left of the forcing region which are shed from the oscillating mountain. At larger amplitude these become a dominant part of the response.

Animation of Figure 11: Kelvin waves and inertial waves generated by high-frequemcy oscillation of the table rotation with a shallow fluid layer (H = 5 cm). rate, in the presence of a small (1 cm high) spherical-cap mountain near 6 o'clock. The Kelvin waves propagate with the speed of long gravity waves anticlockwise about the cylinder, trapped along the outer boundary. Note the inertial wave crests moving opposite to the group velocity, hence toward their source. The circular crests are the inertial wave reflected from the circular boundary, whose energy propagates inward toward the center. There are also visible small, cyclonic eddies left of the forcing region which are shed from the oscillating mountain. At larger amplitude these become a dominant part of the response.

Animation of Figure 13: Monochrome imaging of surface elevation of a rotating fluid, using optical altimetery (full colour altimetry with quantitative velocity, vorticity and potential vorticity has now been achieved, Afanasyev et al., 2007). Rossby waves on a polar beta-plane generated by periodically oscillating the table rotation rate with a single frequency, in the presence of a spherical cap mountain at 8 o'clock. Note the short Rossby waves to the east, and long Rossby waves to the west (clockwise), which spiral into the North Pole, and fleeting, very short inertial waves to the west, yet not to the east. A dark radial line (the image of a wire near the light source) distorts, showing the azimuthal slope of the free surface (and hence the radial component of geostrophic velocity). Time compression: 12x. Omega = 2.23 ^-1; oscillation frequency = 0.16 s^-1. At smaller amplitude this experiment generates waves of this same frequency; however at the present amplitude we are making time-dependent lee waves to the east of the mountain (the short waves), with a spectrum of intrinsic frequencies, while the long waves west of the mountain are in fact nearly a sharp response at the forcing frequency.

Animation of Figure 13: Monochrome imaging of surface elevation of a rotating fluid, using optical altimetery (full colour altimetry with quantitative velocity, vorticity and potential vorticity has now been achieved, Afanasyev et al., 2007). Rossby waves on a polar beta-plane generated by periodically oscillating the table rotation rate with a single frequency, in the presence of a spherical cap mountain at 8 o'clock. Note the short Rossby waves to the east, and long Rossby waves to the west (clockwise), which spiral into the North Pole, and fleeting, very short inertial waves to the west, yet not to the east. A dark radial line (the image of a wire near the light source) distorts, showing the azimuthal slope of the free surface (and hence the radial component of geostrophic velocity). Time compression: 12x. Omega = 2.23 ^-1; oscillation frequency = 0.16 s^-1. At smaller amplitude this experiment generates waves of this same frequency; however at the present amplitude we are making time-dependent lee waves to the east of the mountain (the short waves), with a spectrum of intrinsic frequencies, while the long waves west of the mountain are in fact nearly a sharp response at the forcing frequency.

Animation of Figure 14: eastward (anticlockwise) flow over a spherical cap mountain at 2 o'clock. Development of lee Rossby waves, jet-like concentration of flow, spiral flow above the mountain (an arrested topographic Rossby wave), and an upstream (eastward, clockwise) blocking of the circulation. A growing cyclonic wake involving eastward counter-flow forms behind the mountain. The table rotation is steadily ramped downward to maintain the zonal flow, which accounts for the gradually change of the lighting, as the parabolic free surface relaxes. We have left the glass top from the experiment to promote evaporative convection, which produces the mottled pattern of tiny convective cyclones upstream of the mountain. Note how these show the larger scale flow field. In regions of strong shear we see instead convective sheets (tall 'rolls') which thus outline regions of strong shear. The fluid surface deformation is of order 1 micron (10^-6 m. in these features, and is of order 1 mm. in the most intense flows.

Animation of Figure 14: eastward (anticlockwise) flow over a spherical cap mountain at 2 o'clock. Development of lee Rossby waves, jet-like concentration of flow, spiral flow above the mountain (an arrested topographic Rossby wave), and an upstream (eastward, clockwise) blocking of the circulation. A growing cyclonic wake involving eastward counter-flow forms behind the mountain. The table rotation is steadily ramped downward to maintain the zonal flow, which accounts for the gradually change of the lighting, as the parabolic free surface relaxes. We have left the glass top from the experiment to promote evaporative convection, which produces the mottled pattern of tiny convective cyclones upstream of the mountain. Note how these show the larger scale flow field. In regions of strong shear we see instead convective sheets (tall 'rolls') which thus outline regions of strong shear. The fluid surface deformation is of order 1 micron (10^-6 m. in these features, and is of order 1 mm. in the most intense flows.