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2 years ago

Need help answering this question for #30

Physics

2 answers:

frozen [14]2 years ago

8 0

Add all your numbers up and that would be your answer

dezoksy [38]2 years ago

6 0

I think u would add them all up and then write down your answers

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The law of conservation of energy states...

iris [78.8K]

Can neither be created or destroyed.

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2 years ago

Read 2 more answers

Determine the angle of an incline that would yield a constant velocity, given the coefficient of kinetic friction is 0.10.

azamat

Answer:

$\theta=5.71^{o}$

Explanation:

In order to solve this problem, we mus start by drawing a free body diagram of the given situation (See attached picture).

From the free body diagram we can now do a sum of forces in the x and y direction. Let's start with the y-direction:

$\sum F_{y}=0$

$-W_{y}+N=0$

$N=W_{y}$

so:

$N=mgcos(\theta)$

now we can go ahead and do a sum of forces in the x-direction:

$\sum F_{x}=0$

the sum of forces in x is 0 because it's moving at a constant speed.

$-f+W_{x}=0$

$-\mu_{k}N+mg sen(\theta)=0$

$-\mu_{k}mg cos(\theta)+mg sen(\theta)=0$

so now we solve for theta. We can start by factoring mg so we get:

$mg(-\mu_{k} cos(\theta)+sen(\theta))=0$

we can divide both sides into mg so we get:

$-\mu_{k} cos(\theta)+sen(\theta)=0$

this tells us that the problem is independent of the mass of the object.

$\mu_{k} cos(\theta)=sen(\theta)$

we now divide both sides of the equation into $cos(\theta)$ so we get:

$\mu_{k}=\frac{sen(\theta)}{cos(\theta)}$

$\mu_{k}=tan(\theta)$

so we now take the inverse function of tan to get:

$\theta=tan^{-1}(\mu_{k})$

so now we can find our angle:

$\theta=tan^{-1}(0.10)$

$\theta=5.71^{o}$

8 0

2 years ago

Homeostasis is necessary for these organisms to survive.

alexandr1967 [171]

Answer:

B, unicellular

Explanation:

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1 year ago

Does anyone know who to do this

Whitepunk [10]

Is it science ? cause the word blocks you just need to see which matches up with each word and make its way down

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2 years ago

How does Newton describe the dependence of acceleration of a body on its mass and the net applied force?

tatiyna

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2 years ago