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The terminal velocity of a bowl of petunias (or any object) depends on various factors such as its size, shape, mass, and the medium through which it is falling (e.g., air or a liquid). However, it is important to note that terminal velocity is typically associated with the fall of objects in a fluid medium like air.

Assuming we are considering the bowl of petunias falling through the air and neglecting any effects such as air resistance or the specific shape and mass distribution of the bowl of petunias, we can make a general estimation based on the concept of terminal velocity.

The terminal velocity is the constant velocity that an object reaches when the drag force due to the fluid medium equals the gravitational force pulling the object downward. At terminal velocity, there is no net acceleration.

For simplicity, let's assume the bowl of petunias is a spherical object falling through air. The terminal velocity can be estimated using Stokes' Law, which applies to small, slow-moving objects in a viscous medium like air. According to Stokes' Law, the terminal velocity (Vt) can be calculated using the following formula:

Vt = (2 * r^2 * g * (ρp - ρa)) / (9 * η)

Where: r = radius of the spherical object (bowl of petunias) g = acceleration due to gravity (approximately 9.8 m/s^2 on Earth) ρp = density of the spherical object (bowl of petunias) ρa = density of the air η = dynamic viscosity of the air

It's important to note that obtaining accurate values for the density and dynamic viscosity of air and the specific properties of the bowl of petunias would require precise measurements and information, which may not be readily available.

Considering the above information, without specific values for the bowl of petunias or the environment, it is not possible to provide an exact value for the terminal velocity of a bowl of petunias.

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