Answer:
The ways through which the minerals form include the following order:
2. a warm solution flows through a crack in the rocks there
1. a solution forms from a liquid and dissolved substances
3. elements and compounds leave as the solution cools
4. elements and compounds crystallize
Explanation:
From the explanations above, it could be seen that a warm solution (most probably water)<em> flows through the cracks in the rocks leading to dissolution of substances to form liquid. When the liquid cools, the elements leaves and crystallize as compounds.</em>
Typically, a cell electric potential across the cell membrane varies between -40mV and -80mV. The electric potential in cells such as the neuron enable the cells to transduce the electric signal from stimuli across the nervous system. In other cells, the electric potential powers the running of molecular devices such as the flagella motor in sperm cells
Answer: Hypertonic, Hypotonic, Colloid
Explanation:
Osmosis is a process whereby a solvent moves through a cell membrane from a solution of lower concentration to a solution of higher concentration.
Hypertonic solution has more solutes than the bloodstream this causes solutes, it moves from intracellular fluid to extracellular fluid when a hypertonic solution is used.
A hypotonic solution has a lower solute concentration than the bloodstream, and this causes fluid to move from extracellular spaces into the cells, causing cells to swell.
Oncontic pressure is the opposite force that pulls fluid colloids such as albumin to move into the capillaries. When hydrostatic pressure is greater, fluid will leave the capillaries, when onctoic pressure is greater fluid will enter the capillaries.
No fluid shift is observed in an isotonic solution, because an isotonic solution, has the same solute concentration as blood, meaning an isotonic IV solution is equal in concentration to the blood and hence no fluid shift.
A decomposition reaction<span> is a type of chemical </span>reaction<span> in which a single compound breaks down into two or more elements or new compounds. These </span>reactions<span> often involve an energy source such as heat, light, or electricity that breaks apart the bonds of compounds.</span>