2006-09-26 10:12:12 · 6 answers · asked by sugargirldaddy 1 in Science & Mathematics ➔ Biology
They would diffuse forming an equal concentration of ink in water throughout the whole beaker.
2006-09-26 10:18:32 · answer #1 · answered by bobobob 4 · 0⤊ 0⤋
All things in this universe are made up of tiny particles. These particles are constantly in motion, vibrating, and running into each other like bumper cars. This is actually where we get heat. The hotter the substance, the faster these molecules are vibrating. Absolute zero is when the molecules completely stop moving, and is the coldest that anything can ever get....
Now on to the question. Since the ink is dropped in the water, it is constantly bumped and moved around. The ink will diffuse (spread out) untill the concentration of ink is the same around the whole beaker. This is called diffusion (the moving particles are called thermo-dynamics)
2006-09-26 11:57:15 · answer #2 · answered by shawn_b_c 2 · 0⤊ 0⤋
Ink Drop In Water
2016-11-12 07:44:05 · answer #3 · answered by ? 4 · 0⤊ 0⤋
diffusion. The molecules of ink diffuse into the water until they are evenly distributed throughout the beaker. The link below has a cool video of the process with food coloring dropped into water.
This assumes the ink is water-soluble, otherwise the ink would just sink to the bottom, as it is probably more dense than the water.
2006-09-26 10:20:02 · answer #4 · answered by tevansmd 2 · 1⤊ 0⤋
The ink molecules would be bombarded from all sides by the water molecules, which would scatter them throughout the water, a process known as passive diffusion.
2006-09-26 10:41:34 · answer #5 · answered by PaulCyp 7 · 0⤊ 0⤋
the temperature of the copper will shrink (zeroth regulation of thermodynamics) because warmth is transferring from the copper to the medium in which it truly is submerged (water) even as the temperature of the water equals the temperature of the copper, situations for thermal equilibrium will be met. Temperature of the beaker must be taken under consideration, besides as warmth embarked on the ambience.
2016-12-02 03:06:33 · answer #6 · answered by ? 3 · 0⤊ 0⤋