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An aquifer receives [tex]$20 m^3$[/tex] of precipitation and loses [tex]$2 m^3$[/tex] of water through natural movement. If the water budget must be balanced, how much water can be pumped from the aquifer?

A. [tex][tex]$22 m^3$[/tex][/tex]
B. [tex]$36 m^3$[/tex]
C. [tex]$18 m^3$[/tex]
D. [tex][tex]$20 m^3$[/tex][/tex]

Sagot :

GinnyAnsweridn
Let's solve this problem step by step.

1. Understand the Water Budget Concept:
The water budget equation can be summarized as:

[tex]\[ \text{Water In} - \text{Water Out} = \text{Change in Storage} \][/tex]

In this scenario:
- Water In is the precipitation the aquifer receives.
- Water Out includes natural loss and the amount of water that can be pumped.

2. Given Data:
- Precipitation (Water In) = [tex]\(20 \, m^3\)[/tex]
- Natural loss (part of Water Out) = [tex]\(2 \, m^3\)[/tex]

3. Balancing the Water Budget:
We aim to find out how much water can be pumped, which we'll call [tex]\(W\)[/tex].

The water budget equation, considering the aquifer's water storage doesn't change (i.e., balanced budget), becomes:

[tex]\[ \text{Precipitation} - (\text{Natural Loss} + W) = 0 \][/tex]

4. Plug in the Given Values:

[tex]\[ 20 \, m^3 - (2 \, m^3 + W) = 0 \][/tex]

Simplify the equation:

[tex]\[ 20 \, m^3 - 2 \, m^3 - W = 0 \][/tex]

[tex]\[ 18 \, m^3 = W \][/tex]

5. Conclusion:
The amount of water that can be pumped from the aquifer, considering the balance in the water budget, is:

[tex]\[ \boxed{18 \, m^3} \][/tex]

So, the correct answer is [tex]\(18 \, m^3\)[/tex].
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