A novice scuba diver practicing in a swimming pool takes enough air from his tank to fully expand his lungs before abandoning the tank at depth L and swimming to the surface. He ignores instructions and fails to exhale during his ascent. When he reaches the surface, the difference between the external pressure on him and the air pressure in his lungs is 9.3 kPa. From what depth does he start?
Answers
Answer:
11.625 m.
Explanation:
Difference of pressure will be due to hydro-static pressure due to column of water of height L.
Pressure of water column = L d g , where L is depth ,
d is density of water = 1000kg /m³
g = 9.8 ms²
Pressure difference = 9.3 kPa = 9300 Pa
So Ldg = 9300
L X 1000 X 0.8 =9300
800 L = 9300
L = 11.625 m.
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Answers
Answer:
D. 39 N m
Explanation:
m = mass of the weight used in crossfit workout = 7.0 kg
Force due to the weight used is given as
F = mg
F = (7.0) (9.8)
F = 68.6 N
d = distance of point of action of weight from shoulder joint = 0.57 m
τ = Torque about the shoulder joint due to the weight
Torque about the shoulder joint due to the weight is given as
τ = F d
Inserting the values
τ = (68.6) (0.57)
τ = 39 Nm
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.
Learn more about conservation of momentum here:
#SPJ11
Answers
Answer:
a) 8.99*10³ V b) 4.5*10⁻² J c) 0 d) 0
Explanation:
a)
- The electrostatic potential V, is the work done per unit charge, by the electrostatic force, producing a displacement d from infinity (assumed to be the reference zero level).
- For a point charge, it can be expressed as follows:
- As the electrostatic force is linear with the charge (it is raised to first power), we can apply superposition principle.
- This means that the total potential at a given point, is just the sum of the individual potentials due to the different charges, as if the others were not there.
- In our case, due to symmetry, the potential, at any corner of the triangle, is just the double of the potential due to the charge located at any other corner, as follows:
- The potential at point C is 8.99*10³ V
b)
- The work required to bring a positive charge of 5μC from infinity to the point C, is just the product of the potential at this point times the charge, as follows:
- The work needed is 0.045 J.
c)
- If we replace one of the charges creating the potential at the point C, by one of the same magnitude, but opposite sign, we will have the following equation:
- This means that the potential due to both charges is 0, at point C.
d)
- If the potential at point C is 0, assuming that at infinity V=0 also, we conclude that there is no work required to bring the charge of 5μC from infinity to the point C, as no potential difference exists between both points.
Answers
Answers
Answer:
a) x = 5.48 10⁻² m and b) 0.05 m
Explanation:
a) For a system in oscillatory motion the mechanical energy conserves and is described by the equation
Em = ½ k A²
Where k is the spring constant and at the amplitude of the movement
When the spring has the greatest extent, the kinetic energy is zero
Em = U = ½ k x²
Therefore, the amplitude of the movement is the same amplitude of the spring
Let's calculate
A = √ (2Em / k)
A = √ (2 0.12 / 80)
A = 0.0548 m = 5.48 10⁻² m
b) In this case the spring has kinetic energy that becomes elastic potential energy, let's calculate the mechanical energy before and after compressing the spring
Initial
Em = K = ½ m v²
Final
Em = Ke = ½ k x²
½ m v² = ½ k x²
x = √(m/k) v
x = 2 √(0.50 /800.0)
x = 0.05 m
Answer:
a) The greatest extension of the spring is 0.055 m
b) The spring compress 0.05 m
Explanation:
Please look at the solution in the attached Word file
Answers
Answer:
-384.22N
Explanation:
From Coulomb's law;
F= Kq1q2/r^2
Where;
K= constant of Coulomb's law = 9 ×10^9 Nm^2C-2
q1 and q2 = magnitudes of the both charges
r= distance of separation
F= 9 ×10^9 × −7.97×10^−6 × 6.91×10^−6/(0.0359)^2
F= -495.65 × 10^-3/ 1.29 × 10^-3
F= -384.22N