Mass is a property of matter that is independent of gravitational pulls and pushes. If a ball with a mass of let's say 13 kg, were to be put on Mars or in the <span>Mariana Trench</span>, the mass would still stay the same. Hope this helps!
This is an arithmetic sequence (graph is a line), so function:
a(n) = First term + (n-1) * Common Difference
Here First term = 42 and Common difference = 34 - 36 = -2 so
![a(n)=42+(n-1)\cdot(-2)\\\\\boxed{a(n)=42-(n-1)\cdot2}](https://tex.z-dn.net/?f=a%28n%29%3D42%2B%28n-1%29%5Ccdot%28-2%29%5C%5C%5C%5C%5Cboxed%7Ba%28n%29%3D42-%28n-1%29%5Ccdot2%7D)
Answer B.
Answer:
I’m pretty sure that it goes 0.2, 0.24, 0.3, 0.26, and it can be considered equally likely.
Step-by-step explanation:
Answer:
<em>24 minutes</em>
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Step-by-step explanation:
Given:
Distance per lap = 2 miles
Speed of Lou Lambert = 160 miles/hr
Speed of Ralph Redding = 170 miles/hr
Speed difference between the two = 170 - 160 = 10 miles/hr
Therefore, we can say that <em>Ralph gains 10 miles in 60 minutes </em>over Lou<em>.</em>
We have to find the time in which Ralph will gain 2 laps i.e. 2
2 = 4 miles.
Let us use unitary method to find the required time.
10 miles are gained by Ralph in 60 minutes
1 mile will be gained in ![\frac{60}{10} = 6\ minutes](https://tex.z-dn.net/?f=%5Cfrac%7B60%7D%7B10%7D%20%3D%206%5C%20minutes)
4 miles will be gained in 6
4 = <em>24 minutes</em>
you multiply length times width times height.