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3 years ago

What characteristics determine how easily two substances change temperature

1 answer:

4 0

Amount of time the two substances are in contact. area in contact between the two substances. amount of heat needed to raise the temperature one degree Celsiusof the material that makes up the substances. density of the two substances in contact.J

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Which of these materials is permeable?

kogti [31]

Correct answer is letter B. sandstone

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3 years ago

The free body diagram shows a box being pulled to the left up a 25-degree incline. A free body diagram with 4 forces vectors. Th

Bezzdna [24]

Answer:

the answer is 150

Explanation:

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3 years ago

Mike walks 100 meter north, then walks 30 meters south. after this, he walks another 10 meters north.

Liono4ka [1.6K]

Answer:

The answer is 80

Explanation:

because 100-30+10 is 80

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3 years ago

Read 2 more answers

You collect some data on horse racing along a straight track. You are able to fit the motion of the horse to a function during t

Digiron [165]

Answer:

The equation is missing in the question. The equation is $10 m + 5(m/s^2)t^2+3(m/s^3)t^3$

a). $v=10 t +9t^2$ , the horse will not turn.

b). a(t) = 10 + 18t

Explanation:

Given :

$x(t)=10 m + 5(m/s^2)t^2+3(m/s^3)t^3$

∴ At t =0, x = 10 m

a). Velocity as a function of time

$v = \frac{dx}{dt}$

= $10 t +9t^2$

Turning velocity must be zero.

v(t) = 0

$10 t +9t^2=0$

$\therefore t = 0 \text{ or}\ t =-\frac{10}{9}$

Taking the positive value of time.

The horse will not turn.

b). Acceleration as a function of time.

$a(t)=\frac{dv}{dt}$

= 10 + 18t

∴ a(t) = 10 + 18t

6 0

4 years ago

A diffraction grating, ruled with 300 lines per mm, is illuminated with a white light source at normal incidence.

Vera_Pavlovna [14]

the expression for diffraction grating allows to find the results for the questions for the angular separation are:

i) The third order is Δθ = 0.203 rad.

ii) The first order with water is Δθ = 0.046 rad.

The diffraction grating is a system formed by a large number of equally spaced lines whose diffraction is given by the expression.

d sin θ = m λ

Where d is the distance between two lines, θ is the angle of diffraction, the order of diffraction and λ is the wavelength.

i) Let's start by looking for the separation between two lines

Let's use a rule of direct proportions. If there are 300 lines in 1 mm, what distance is there between two lines.

d = 1 lines (1 mm / 300 lines) = 3,333 10⁻³ mm

d = 3.333 10⁻⁶ m

Let's find the angle of diffraction for the third order (m = 3) for each wavelength.

λ₁ = 400 nm = 400 10⁻⁹ m

sin θ₁ = $\frac{m \ \lambda }{d}$ m λ/ d

sin θ₁ = $\frac{3 \ 400 \ 10^{-9} }{3.333 \ 10^{-6} }$

θ₁ = sin⁻¹ 0.3600

θ₁ = 0.368 rad

λ₂ = 600 nm = 600 10⁻⁹ m

sin θ₂ = $\frac{3 \ 600 \ 10^{-9} }{3.333 \ 10^{-6} }$

θ₂ = sin⁻¹ 0.5401

θ₂ = 0.571 rad

The angular separation is

Δθ = θ₂ - θ₁

Δθ = 0.571 - 0.368

Δθ = 0.203 rad

ii) In this case, the separation between the network and the observation screen is filled with water.

When the rays leave the network they undergo a refraction process, for which they must comply with the relationship.

$n_i \ sin \theta_1 = n_r \ sin \theta_r$

The incident side is in the air, therefore its refractive index is n_i = 1 and when it passes into the water with refractive index n_r = 1.33.

Let's start looking for the incident angles for the first order of diffraction.

m = 1

λ₁ = 400 nm

θ₁ = sin⁻¹ $\frac{1 \ 400 \ 10^{-9}}{3.33 \ 10^{-6}}$