Use the worked example above to help you solve this problem. A ball is thrown upward from the top of a building at an angle of 30.0° to the horizontal and with an initial speed of 15.0 m/s. The point of release is h = 46.0 m above the ground.(a) How long does it take for the ball to hit the ground?
(b) Find the ball's speed at impact.
(c) Find the horizontal range of the ball.
Answers
Answer:
B
Explanation:
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Answers
Answer:
The speed of the arrow immediately after it leaves the bow is 38.73 m/s
Explanation:
given information:
force, F = 150 N
x = 50 cm = 0.5 m
mass of arrow, m = 50 g = 0.05 kg
We start from the force of the spring
F = kx
k =
=
= 300 N/m
The potential energy, EP of the spring is
EP =
the kinetic energy, EK of the spring
EK =
According to conservative energy,
EP = EK
=
=
=
v =
=
= 38.73 m/s
Final answer:
Using Hooke's Law, we can determine the speed of the arrow. The speed of the arrow immediately after it leaves the bow is approximately 38.7 m/s.
Explanation:
In this problem, we can use Hooke's Law to determine the speed of the arrow. Hooke's Law states that the force exerted by a spring is proportional to the displacement of the spring:
F = -kx
Where F is the force, x is the displacement, and k is the spring constant.
In this case, the force exerted by the bow on the arrow is acting like a spring force. The force of the bow is 150N, and the displacement is 50cm (which is equivalent to 0.5m). So we can set up the equation as:
150N = -k * 0.5m
Now we can solve for k:
k = -150N / 0.5m = -300 N/m
Now that we have the spring constant, we can use it to find the potential energy stored in the bow:
PE = 0.5kx^2 = 0.5*(-300N/m)*(0.5m)^2 = 37.5 J
Next, we can use the conservation of energy to find the kinetic energy of the arrow right after it leaves the bow. The potential energy stored in the bow is converted into kinetic energy:
KE = PE = 37.5 J
The kinetic energy is given by the equation:
KE = 0.5mv^2
Where m is the mass of the arrow and v is its velocity. Rearranging the equation, we can solve for v:
v = sqrt(2KE/m) = sqrt(2*37.5 J / 0.05 kg) = sqrt(1500) m/s ≈ 38.7 m/s.
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A. sideways
B. up and down
C. back and forth
D. all of the above
Answers
Answer: D i am pretty sure
Explanation:
Answer:
all
Explanation:
Answers
Answer:
A) m2 = 98.71g
B) v_f2 = 1.86 m/s
Explanation:
We are given;
Mass of cart; m1 = 340g
Initial speed; v_i1 = 1.2 m/s
Final speed; v_f1 = 0.66 m/s
A)Since the collision is elastic, we can simply apply the conservation of momentum to get;
m1•(v_i1) = m1•(v_f1) + m2•(v_f2) - - - - - (eq1)
From conservation of kinetic energy, we have;
(1/2)m1•(v_i1)² = (1/2)m1•(v_f1)² + (1/2)m2•(v_f2)² - - - - eq(2)
Let's make v_f2 the subject in eq 2;
Thus,
v_f2 = √([m1•(v_i1)² - m1•(v_f1)²]/m2)
v_f2 = √([m1((v_i1)² - (v_f1)²)]/m2)
Let's put this for v_f2 in eq1 to obtain;
m2 = {m1((v_i1) - (v_f1))}/√([m1((v_i1)² - (v_f1)²)]/m2)
Let's square both sides to give;
(m2)² = {m1•m2((v_i1) - (v_f1))²}/([(v_i1)² - (v_f1)²]
This gives;
m2 = {m1((v_i1) - (v_f1))²}/([(v_i1)² - (v_f1)²]
Plugging in the relevant values to get;
m2 = {340((1.2) - (0.66))²}/([(1.2)² - (0.66)²]
m2 = 98.71g
B) from equation 1, we have;
m1•(v_i1) = m1•(v_f1) + m2•(v_f2)
Making v_f2 the subject, we have;
v_f2 = m1[(v_i1) - (v_f1)]/m2
Plugging in the relevant values to get;
v_f2 = 340[(1.2) - (0.66)]/98.71
v_f2 = 1.86 m/s
Final answer:
To determine the mass of the second cart and its speed after impact, we can use the principle of conservation of momentum. The initial momentum of the first cart is equal to its final momentum plus the momentum of the second cart. After calculating the mass of the second cart, we can use the conservation of momentum again to find its speed by equating the final velocity of the combined carts to the initial velocity of the first cart.
Explanation:
To determine the mass of the second cart, we can use the principle of conservation of momentum. The initial momentum of the first cart, with a mass of 340 g and an initial velocity of 1.2 m/s, is equal to its final momentum plus the momentum of the second cart. Using this equation, we can solve for the mass of the second cart.
After calculating the mass of the second cart, we can use the conservation of momentum again to find its speed after the impact. Since the two carts stick together after the collision, the final velocity of the combined carts is equal to the initial velocity of the first cart. Using this equation, we can solve for the speed of the second cart.
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Answers
Para resolver este problema es necesario aplicar los conceptos de Fuerza, dados en la segunda Ley de Newton y el concepto de Trabajo, como expresión de la fuerza necesaria para realizar una actividad en una distancia determinada.
El trabajo se define como
W = F*d
Where,
F = Force
d = Distance
At the same time we have that the Force by second's Newton law is equal to
F = mg
Where,
m = mass
g = Gravitational acceleration
PART A) Using our values and replacing we have that
PART B) Using Newton's Second law we have that,
Answers
Final answer:
To calculate the quantity of heat that must be removed from 6.1 g of 100°C steam, we need to consider both the change in temperature and the phase change from steam to liquid. The specific heat of water is used to calculate the heat required to lower the temperature, while the heat of vaporization is used to calculate the heat required to condense the steam. Adding these two heat values together gives us the total amount of heat that must be removed from the steam, which is approximately 3.61164 kcal.
Explanation:
When steam at 100°C condenses and its temperature is lowered to 46°C, heat must be removed from the steam. To calculate the amount of heat, we can use the specific heat of steam and the latent heat of vaporization. First, we calculate the heat required to lower the temperature of the steam from 100°C to 46°C using the specific heat of water. We then calculate the heat required to condense the steam using the latent heat of vaporization. Finally, we add these two heat values together to obtain the total amount of heat that must be removed from the steam.
Given:
- Mass of steam = 6.1 g
- Temperature change = 100°C - 46°C = 54°C
- Specific heat of water = 1.00 kcal/(kg · °C)
- Heat of vaporization = 539 kcal/kg
Calculations:
- Heat required to lower the temperature of the steam:
Q1 = mass × specific heat × temperature change
= 6.1 g × (1.00 kcal/(kg · °C) ÷ 1000 g) × 54°C - Heat required to condense the steam:
Q2 = mass × heat of vaporization
= 6.1 g × (539 kcal/kg ÷ 1000 g) - Total heat required:
Q = Q1 + Q2
Calculation:
- Q1 = 0.32874 kcal
- Q2 = 3.2829 kcal
- Q = Q1 + Q2 = 0.32874 kcal + 3.2829 kcal = 3.61164 kcal
Therefore, the quantity of heat that must be removed from 6.1 g of 100°C steam to condense it and lower its temperature to 46°C is approximately 3.61164 kcal.
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Final answer:
To condense and cool 6.1 g of 100°C steam to 46°C, 3.2879 kcal must be removed for condensation, and 0.3304 kcal for cooling, for a total of 3.6183 kcal.
Explanation:
Calculating the Quantity of Heat for Condensation and Cooling
To calculate the quantity of heat that must be removed from 6.1 g of 100°C steam to condense it and lower its temperature to 46°C, we need to consider two processes: condensation and cooling. For condensation, we use the heat of vaporization, and for cooling, we use the specific heat of water.
- Calculate the heat released during condensation of steam into water at 100°C:
Heat = mass × heat of vaporization
Heat (in kcal) = (6.1 g) × (539 kcal/kg) × (1 kg / 1000 g)
Heat = 3.2879 kcal - Calculate the heat released when the water cools from 100°C to 46°C:
Heat = mass × specific heat × change in temperature
Heat (in kcal) = (6.1 g) × (1.00 kcal/kg°C) × (1 kg / 1000 g) × (100°C - 46°C)
Heat = 0.3304 kcal
Total heat removed is the sum of the heat from both steps: 3.2879 kcal + 0.3304 kcal = 3.6183 kcal.
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B.) perception.
C.) similarity.
D.) continuity.
Answers
Answer:
C
Explanation:
Similarity