Yes, the density of a liquid can affect the refraction angles. A change in density can lead to a change in the speed of light as it passes through the liquid, resulting in a change in the angle of refraction according to Snell's Law.
The value for the refractive index of Deuterium at 24.2K and at 3200 Angstrom, is given as 1.1321. As measured using the Cerenkov effect.
Boy can find the refractive index of a liquid using a refractometer or by measuring the angle of refraction using a laser pointer. By measuring the critical angle of total internal reflection, he can calculate the refractive index of the liquid. Alternatively, he can use Snell's Law in conjunction with the angles of incidence and refraction to determine the refractive index.
The shape of the container, the size of the container, and the density of the liquid do not affect the pressure at a point beneath the surface of a liquid. The pressure at a point in a liquid is only dependent on the depth of the point and the density of the liquid above it.
Most liquids are incompressible (or nearly so), therefore ordinary pressures have only a negligibly small effect on the density of a liquid. However, if you consider enormous pressures like those that may exist at the core of the sun, then a liquid's density will be increased by pressure under these extreme conditions.
An object with lower density than the liquid will float, one with more density will sink. Anything with the same density will stay at the depth where it is placed. If it is placed half submerged it would sink until submerged.
The value for the refractive index of Deuterium at 24.2K and at 3200 Angstrom, is given as 1.1321. As measured using the Cerenkov effect.
The increase in density will decrease the rate of diffusion. There is an inverse relation between density and rate of diffusion.
Boy can find the refractive index of a liquid using a refractometer or by measuring the angle of refraction using a laser pointer. By measuring the critical angle of total internal reflection, he can calculate the refractive index of the liquid. Alternatively, he can use Snell's Law in conjunction with the angles of incidence and refraction to determine the refractive index.
Pressure and Temperature will affect volume and thus also density. However the effect is much smaller than on gases (about 100-1000 times), it is mostly a bit bigger than the effect on solids.
it is called refraction
The shape of the container, the size of the container, and the density of the liquid do not affect the pressure at a point beneath the surface of a liquid. The pressure at a point in a liquid is only dependent on the depth of the point and the density of the liquid above it.
Most liquids are incompressible (or nearly so), therefore ordinary pressures have only a negligibly small effect on the density of a liquid. However, if you consider enormous pressures like those that may exist at the core of the sun, then a liquid's density will be increased by pressure under these extreme conditions.
An object with lower density than the liquid will float, one with more density will sink. Anything with the same density will stay at the depth where it is placed. If it is placed half submerged it would sink until submerged.
refraction
The flow rate of liquid from a dropper typically increases with higher liquid density. This is due to the increased weight of the liquid causing it to flow more quickly through the dropper. Conversely, lower density liquids flow more slowly from a dropper.
Yes, a liquid of higher density will displace a liquid of lower density when the two liquids are immiscible. This is because the liquid with the higher density will sink below the other liquid due to gravity, displacing it.
The density of a liquid affects the buoyancy of an object by determining whether the object will float or sink in that liquid. If the density of an object is greater than the density of the liquid, the object will sink. If the density of the object is less than the density of the liquid, the object will float.