Jill is pushing a box across the floor. Which represents the upward force perpendicular to the floor?

A. Fp
B. Ff
C. FN
D. Fg

Answer:

the 5 is because u have to select the currents and volts which gives us 2 and 1 plus 3 is 6 but if we rest 1 is 5, thats the answer

Answer:

HOPE IT HELPS YOU!!!

Explanation:

Mark FadedGirl25 as brainliest

Answer: 1.2%

Explanation:

Given

If one borrows $12,250

and give $147 interest on it

Then the interest is given from the formula

[tex]\Rightarrow S.I=\dfrac{P\times R\times T}{100}\\\\\Rightarrow 147=\dfrac{12,250\times R\times 1}{100}\\\\\Rightarrow R=\dfrac{147}{122.50}\\\\\Rightarrow R=1.2\%[/tex]

Thus, the annual rate of interest  is 1.2%

Answer:

Different surfaces

Answer:

a. 3.09 m/s^2

b. 322.52 N

Explanation:

The computation of the acceleration of the object and the tension of the string is as follows:

The acceleration of the system is a

= (m1 - m2) × g ÷ (m1 + m2)

= (48 - 25) × 9.81 ÷ (48 + 25)

= 3.09 m/s^2

b. The tension in the string is T

= 2 × m1 × m2 × g÷   (m1+m2)

= (2  × 48  × 25  ×  9.81) ÷  (48 + 25)

= 322.52 N

Answer:

a) increases.

b) remains the same.

c) increases.

d) increases.

e) increases.

f) increases.

Explanation:

a)

       [tex]C = \epsilon_{0}*\frac{A}{d} (1)[/tex]

       where ε₀ = permitivitty of  free space

                   A = area of one of the plates

                   d=  plate separation

b)  

        [tex]C = \frac{Q}{V} (2)[/tex]

c)

d)

       [tex]U = \frac{1}{2}* C*V^{2} (3)[/tex]

e)

       [tex]V = E*d (4)[/tex]

f)

       [tex]u = \frac{U}{v} = \frac{\frac{1}{2}* C*V^{2}}{A*d} =\frac{1}{2}* \epsilon_{0}*\frac{A*V^{2} }{A*d*d} = \frac{1}{2} *\epsilon_{0}*E^{2} (5)[/tex]

Answer:

(a) Heat flows out

Work flows in

(b) Heat flow out

work flows in

(c) Heat flow out

work flows out

Explanation:

(a) According to the first law of thermodynamics, the change in internal energy of the system, ΔU is given as follows;

ΔU = Q - W

According to the second law of thermodynamics, heat will flow from a hot body to a cold body however through work input, a refrigerator causes heat to flow from a cold body to a hot body

Therefore;

Heat flows out of the system (the contents of the refrigerator)

Work is inputted, flows in to the system

(b) Given that the refrigerator pumps heat from the content out, the body of the refrigerator becomes hot relative to the room, and according to the second law of thermodynamics

Heat flow out from the hot system, the refrigerator and its content, to the room

h₁ > h₂, h₂ - h₁ = -ve = -w

Therefore, work flows out the system as the refrigerator operates

(c) During a winter day, the temperature of the room relative to the external environment where it is snowing is higher

Therefore, heat will flow out from the system

Work done, -w = h₂ - h₁, where

h₂ = The heat of the environment

h₁ = The heat in the room

Given that h₁ > h₂, h₂ - h₁ = -ve = -w, therefore, work is done by the system which is the room

Work will flow out of the system

Explanation:

to determine light brightness

to determine planet compositition

to determine the ages of p

Answer:

There are six major nutrients: Carbohydrates (CHO), Lipids (fats), Proteins, Vitamins, Minerals, Water.

Explanation:

Explanation:

[tex]which \: language \: is \: this[/tex]

[tex]pls \: write \: in \: english[/tex]

[tex]then \: only \: i \: can \: answer \: u[/tex]

[tex]otherwise \: sry[/tex]

Answer:

The angular velocity of the wheels is 276.314 radians per second.

Explanation:

The wheels are rolling, which is a combination of rotation and translation, whose center of rotation is the point of contact between the wheel and the ground and the geometrical center of the skateboard experiments pure translation. Then, the angular velocity can be found by using the following kinematic expression:

[tex]\omega = \frac{v}{R}[/tex] (1)

Where:

[tex]\omega[/tex] - Angular velocity, in radians per second.

[tex]v[/tex] - Velocity of the wheel at its center, in inches per second.

[tex]R[/tex] - Radius of the wheel, in inches.

If we know that [tex]v = 404.8\,\frac{in}{s}[/tex] and [tex]R = 1.465\,in[/tex], then the angular velocity of the wheels are:

[tex]\omega = \frac{404.8\,\frac{in}{s} }{1.465\,in}[/tex]

[tex]\omega = 276.314\,\frac{rad}{s}[/tex]

The angular velocity of the wheels is 276.314 radians per second.

Answer:

The magnitude of force of the ping-pong ball on the bowling ball , [tex]F_p[/tex] = 3.5 N

Explanation:

Given;

mass of the bowling ball, [tex]m_b[/tex] = 5.4 kg

mass of the ping-pong ball, [tex]m_p[/tex] = 2.7 g = 0.0027 kg

magnitude of force of the bowling ball, [tex]F_b[/tex] = 3.5 N

let the magnitude of force of ping-pong ball = [tex]F_p[/tex]

Apply Newton's third law of motion; action and reaction are equal and opposite.

[tex]F_b = -F_p[/tex]

The force of the ping-pong ball on the bowling ball is equal to that of the bowling ball on ping-pong ball, but in opposite direction.

Thus, the magnitude of force of the ping-pong ball on the bowling ball , [tex]F_p[/tex] = 3.5 N

Answer:

a

Explanation:

Using fences.................................

Answer:

0.913

Explanation:

k.e=1/2mv square

k.e=1/2×0.078g×23.4256m/s square

k.e=0.913J

The kinetic energy when the lemming is 2.00 m above the ground is approximately 2.56 J (Joules).

To calculate the kinetic energy (KE) of the lemming when it is 2.00 m above the ground, we need to consider the change in its potential energy (PE) as it falls.

The potential energy at a height h is given by:

PE = m g h

Where:

m is the mass of the lemming (0.0780 kg)

g is the acceleration due to gravity (9.8 m/s²)

h is the height above the ground

Given:

Height of the cliff (h) = 5.36 m

Velocity of the lemming (v) = 4.84 m/s

Height above the ground (h') = 2.00 m

The lemming will lose potential energy as it falls from the cliff, which is converted into kinetic energy. Therefore, the kinetic energy when it is 2.00 m above the ground is equal to the difference between its total initial kinetic energy and the potential energy at that height.

Initial potential energy at the top of the cliff:

PE_initial = m g h

Potential energy when it is 2.00 m above the ground:

PE_final = m * g * h'

The change in potential energy is given by:

ΔPE = PE_final - PE_initial

The kinetic energy (KE) when it is 2.00 m above the ground:

KE = ΔPE = -ΔPE (due to energy conservation)

Let's calculate the potential energy at the top of the cliff and when it is 2.00 m above the ground:

PE_initial = m ×g × h

= 0.0780 kg × 9.8 m/s² × 5.36 m

PE_initial ≈ 4.09 J

PE_final = m ×g × h'

= 0.0780 kg ×9.8 m/s² ×2.00 m

PE_final ≈ 1.53 J

The change in potential energy (ΔPE) is:

ΔPE = PE_final - PE_initial = 1.53 J - 4.09 J

ΔPE ≈ -2.56 J

Since the change in potential energy is equal to the kinetic energy, the kinetic energy when the lemming is 2.00 m above the ground is approximately 2.56 J (Joules).

To know more about kinetic energy

https://brainly.com/question/999862

#SPJ2

Answer:

E = k q1 q2 / r^2      electric potential

E / q1 = k q2 / r^2 = 9 * 10E9 * 25 * E-9 / ,37^2 = 1644 V

(Gauss Law - charge of sphere equivalent to charge at center)

Answer:

√ [tex]\frac{3}{5} m[/tex]

Explanation:

Hope it helps!.

The change in the length of the spring will be 3.5 cm.Principal of the law of conservation of the momentum is applied in the problem.

According to the law of conservation of momentum, the momentum of the body before the collision is always equal to the momentum of the body after the collision.

According to the law of conservation of momentum;

Momentum before collision =Momentum after collision

Speed after impact is;

[tex]\rm v = \frac{(1.50)(3.5)}{(1.50)+(3)} \\\\ v= 1.1666 \ m/sec[/tex]

From the law of conservation of energy:

[tex]\rm \frac{1}{2} kx^2= \frac{1}{2} (m+M)v^2 \\\\ x= \sqrt{\frac{M+m}{k} } \\\\ x=\sqrt{\frac{4.5}{5000 } }(1.1666)\\\\ x= 0.35 \ m \\\\ x=3.5 \ cm[/tex]

The change in the length of the spring will be 3.5 cm.

To learn more about the law of conservation of momentum refer;

https://brainly.com/question/1113396

#SPJ2

Answer:

Explanation:

The equation for Power is

P = Work/time to do work and the equation for work is

Work = FΔx

We first need to find the amount of work done, then we can find the power it took to do that work.

W = 2000(9.8)(28) so

W = 550,000 N*m

Now we fill that into the power equation:

[tex]P=\frac{550000}{30}[/tex] gives us

P = 18000 Watts. But we need kW, so we divide by 1000 to get

P = 18 kW of power.

Answer:

18.293 kilowatts

Explanation:

Given that, mass (m) = 2000 kg

Height (h) = 28m

Time(t) = 30 seconds

To find: power required in kilowatts

Now required work done will be m*g*h

= 2000*9.8*28=548800 newton

Now power required is given by (P) = work done /(time taken)

= 548800/30 = 18293.333 watts

= (18293.333 / 1000) kilowatts

= 18.293 kilowatts.

Answer:

Explanation:

Use the equation

[tex]v^2=v_0^2+2a[/tex]Δx

In this dimension (the y dimension...the only one we have to care about for this problem), here's what we know:

a = -32 ft/s/s

v₀ = 0 m/s (since someone was holding the stone still before it was dropped)

v = 136 ft/s

Δx = ??

Filling in:

[tex]136^2=0^2+2(-32)[/tex]Δx so

Δx = [tex]\frac{136^2}{2(-32)}[/tex] so

Δx = -289 feet (negative because the stone dropped that many feet below the point from which it was dropped, but you would answer a height question with the positive of this number. If you were asked how far the stone dropped, it would be negative; if you're asked how tall the cliff is, that would be positive)

Answer:

d. In dc steady state conditions, the voltages across the capacitors are constant and the currents through the capacitance are zero. The current through the inductors are constant and the voltage across the inductances are zero.

Explanation:

The current through a capacitor is given by i = CdV/dt where C = capacitance of capacitor and V = voltage across capacitor. At steady state dV/dt = 0 and V = constant. So, i = CdV/dt = C × 0 = 0.

So, in dc steady state, the voltage across a capacitor is constant and the current zero.

The voltage across an inductor is given by V = Ldi/dt where L = inductance of inductor and i = current through inductor. At steady state di/dt = 0 and V = constant. So, V = Ldi/dt = L × 0 = 0.

So, in dc steady state, the voltage across an inductor is zero and the current constant.

So, In dc steady state conditions, the voltages across the capacitors are constant and the currents through the capacitance are zero. The current through the inductors are constant and the voltage across the inductances are zero.

The answer is d.

Answer:

dhfhffuththt9tr8tujtngigjtjrjrjrurur

Answer:

The mass decreases

Explanation:

Just smart

Answer: The voltage needed is 35.7 V

Explanation:

Assuming that the resistors are arranged in parallel combination.

For the resistors arranged in parallel combination:

[tex]\frac{1}{R}=\frac{1}{R_1}+\frac{1}{R_2}+\frac{1}{R_3}[/tex]

We are given:

[tex]R_1=20\Omega\\R_2=20\Omega\\R_3=200\Omega[/tex]

Using above equation, we get:

[tex]\frac{1}{R}=\frac{1}{20}+\frac{1}{20}+\frac{1}{200}\\\\\frac{1}{R}=\frac{10+10+1}{200}\\\\R=\frac{200}{21}=9.52\Omega[/tex]

Calculating the voltage by using Ohm's law:

[tex]V=IR[/tex]         .....(1)

where,

V = voltage applied

I = Current = 3.75 A

R = Resistance = [tex]9.52\Omega[/tex]

Putting values in equation 1, we get:

[tex]V=3.75\times 9.52\\\\V=35.7V[/tex]

Hence, the voltage needed is 35.7 V

There are six different ways to arrange those resistors.

Each way leads to a different answer.

You didn't tell us how you want them connected.

The attached drawing shows them all.

Answer:

The appropriate answer is "3761.69 N/C".

Explanation:

Given that:

Mass,

m = 4.99 g

or,

   = [tex]4.99\times 10^{-3} \ kg[/tex]

Charge,

q = 13 µC

or,

  = [tex]13\times 10^{-6} \ C[/tex]

As we know,

⇒ [tex]F=mg=Eq[/tex]

then,

⇒ [tex]E=\frac{mg}{q}[/tex]

By putting the values, we get

        [tex]=\frac{4.99\times 10^{-3}\times 9.8}{13\times 10^{-6}}[/tex]

        [tex]=3761.69 \ N/C[/tex]

Answer: A quasar is an exceptionally bright active galactic nucleus (AGN) containing a supermassive black hole surrounded by a gaseous accretion disk with a mass ranging from millions to billions of times that of the Sun.

Explanation: Energy is emitted in the form of electromagnetic radiation when gas in the disk descends towards the black hole, which can be seen across the electromagnetic spectrum.

Answer:

A complete third electron shell holds 8 electrons

---------------------------

hope it helps...

have a great day!!

Answer:

8

Explanation:

Answer:

the radio can tune wavelengths between 1.88 and 5.97 m

Explanation:

The signal that can be received is the one that is in resonance as the impedance of the LC circuit.

         X = X_c - X_L

         X = 1 / wC - w L

at the point of resonance the two impedance are equal so their sum is zero

         X_c = X_L

         1 / wC = w L

         w² = 1 / CL

         w = [tex]\sqrt{\frac{1}{CL} }[/tex]

let's look for the extreme values

C = 1  10⁻¹² F

         w = [tex]\sqrt{\frac{1}{ 1 \ 10^{-12} \ 1 \ 10^{-6}} }[/tex]

         w = [tex]\sqrt{1 \ 10^{18}}[/tex]

         w = 10⁹ rad / s

C = 10 10⁻¹² F

         w = [tex]\sqrt{\frac{1}{10 \ 10^{-12} \ 1 \ 10^{-6}} }[/tex]Ra 1/10 10-12 1 10-6

         w = [tex]\sqrt{0.1 \ 10^{18}}[/tex]Ra 0.1 1018

         w = 0.316 10⁹ rad / s

Now the angular velocity and the frequency are related

           w = 2π f

           f = w / 2π

the light velocity  is

           c = λ f

           λ = c / f

we substitute

          λ = c 2π/w

we calculate the two values

 C = 1 pF

          λ₁ = 3 10⁸ 2π / 10⁹

          λ₁= 18.849 10⁻¹ m

          λ₁ = 1.88 m

C = 10 pF

           λ₂ = 3 10⁸ 2π / 0.316 10⁹

           λ₂ = 59.65 10⁻¹ m

           λ₂ = 5.97 m

so the radio can tune wavelengths between 1.88 and 5.97 m

Answer: the iris

Explanation: I looked it up

Answer:

Iris

Explanation:

Because (iris) has muscles that can expand/contract depends to the amount of light that pupil needs to process/figure out images.

Answer:

So logically speaking the question you have asked makes no sense

Explanation:

Zero what? After landing where? How what? before asking a question think about how other people will read it.