Cut a ball of mercury with a knife it forms into other balls

In summary, mercury forms into other balls when cut with a knife due to its fluid nature and the forces acting upon it, such as gravity, air pressure, and cohesion between atoms. The original "ball" is formed by the opposition of these forces, resulting in a spherical shape. When the mass is cut into smaller pieces, each piece is still influenced by the same forces and therefore tends to form a similar shape. The surface tension and cohesive forces of mercury, being extremely large, also contribute to its tendency to form into a ball shape. This is why a drop of mercury will always ball up, unlike other substances.
  • #1
bozo the clown
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If I cut a ball of mercury with a knife it forms into other balls why is this
 
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  • #2
Because mercury is a fluid, and has no rigid shape. Therefore, its form is determined moment-by-moment by the forces acting upon it. These include outside forces like gravity and air pressure, and internal forces such as the cohesion of the mercurial atoms to one another. The original "ball" of mercury is formed by the opposition of forces like gravity gravity pushing down on the substance while the cohesion of the atoms resists being spread out. When the blob of mercury reaches a point where these two forces are equal, it ceases to change shape incomes to rest. Since this point of equilibrium is the same distance from the center of the blob in all directions, the mercury forms into a roughly spherical shape. Separate the original message into two masses, and both are being acted upon by all the same forces as the original mass, and therefore tend to arrive at a very similar final "shape".
 
  • #3
I would assume the surface tension in mercury is extremely large (compared to other substances), so that its contact area with the external world becomes as small as possible (i.e., spherical shape for a given volume), more easily than for other substances.
 
  • #4
Also, Hg is a metal. That means the interatomic forces (cohesive) are HUGE. Insert this into LURCH's explanation to understand why a drop of Hg always balls up.

PS : Surface tension is a result of cohesive forces - so would also be large. Hence, Hg columns always have a convex meniscus, unlike water columns, which have a concave meniscus.
 

1. How is it possible for a ball of mercury to form into other balls when cut with a knife?

This phenomenon occurs due to mercury's unique physical properties, specifically its high surface tension and low cohesive forces. When a knife is used to cut a ball of mercury, the surface tension pulls the mercury back together, forming smaller balls due to the lack of cohesive forces to keep it in one large mass.

2. Is it safe to cut a ball of mercury with a knife?

No, it is not safe to cut a ball of mercury with a knife. Mercury is a toxic substance and should only be handled by trained professionals in a controlled environment.

3. Why does mercury have such high surface tension?

Mercury has a high surface tension due to its unique atomic structure. The atoms in mercury are tightly packed, creating strong intermolecular forces that result in a high surface tension.

4. Can other liquids behave similarly when cut with a knife?

Yes, other liquids with high surface tension and low cohesive forces can exhibit similar behavior when cut with a knife. Examples include gallium, water, and some oils.

5. Are there any practical applications for this phenomenon?

While this phenomenon may seem like a simple curiosity, it has practical applications in fields such as microfluidics and nanotechnology. The ability to manipulate small droplets of mercury or other liquids can be useful in creating miniaturized devices and systems.

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