A mass of 50.00g hangs from a 7.00cm-long spring that is rigidly attached to a ceiling. The mass is pulled down slightly, let go, and is observed to make 8 round trips (up and back down) in 14.00s. What is the stiffness constant for this spring

Answer:

F=49.48 N

Explanation:

Given that

Diameter , d= 30 mm

Holding pressure = 70 % P

P=Atmospherics pressure

We know that

P= 1 atm = 10⁵ N/m²

The force per unit area is known as pressure.

[tex]P=\dfrac{F}{A}[/tex]

[tex]F=P\times A[/tex]

[tex]F=0.7\times 10^5\times \dfrac{\pi}{4}\times 0.03^2\ N[/tex]

Therefore the force will be 49.48 N.

F=49.48 N

Answer:

(a) the mechanical energy of the system, U = 0.1078 J

(b) the maximum speed of the object, Vmax = 0.657 m/s

(c) the maximum acceleration of the object, a_max = 15.4 m/s²

Explanation:

Given;

Amplitude of the spring, A = 2.8 cm = 0.028 m

Spring constant, K = 275 N/m

Mass of object, m = 0.5 kg

(a) the mechanical energy of the system

This is the potential energy of the system, U = ¹/₂KA²

U = ¹/₂ (275)(0.028)²

U = 0.1078 J

(b) the maximum speed of the object

[tex]V_{max} =\omega*A= \sqrt{\frac{K}{M} } *A\\\\V_{max} = \sqrt{\frac{275}{0.5} } *0.028\\\\V_{max} = 0.657 \ m/s[/tex]

(c) the maximum acceleration of the object

[tex]a_{max} = \frac{KA}{M} \\\\a_{max} = \frac{275*0.028}{0.5}\\\\a_{max} = 15.4 \ m/s^2[/tex]

The characteristics of the simple harmonic motion allows to find the results for the questions of the oscillating mass are:

     a) The total energy is: Em = 0.1078 J

     b) The maximum speed is: v = 0.657 m / s

    c) the maximum acceleration is: a = 15.4 m / s²

Given parameters

To find

    a) Mechanical energy

    b) Maximum speed

    c) Maximum acceleration

the simple harmonic movement is an oscillatory movement where the restoring force is proportional to the displacement, it is described by the expression:

         x = A cos (wt + Ф)

         w² = k / m

Where x is the displacement, A the amplitude w the angular velocity, t the time, Ф a phase constant, k the spring constant and m the mass.

A) The mechanical energy is

        Em = ½ k A²

Let's calculate.

       Em = ½ 275 (2.8 10⁻²) ²

       Em = 0.1078 J

b) Velocity is defined as the change of position with respect to time.

       v = [tex]\frac{dx}{dt}[/tex]  = - Aw sin ( wt + fi)

To obtain the maximum velocity, the sine function must be ±1

        [tex]v_{max}[/tex] = w A

Let's calculate

        w = [tex]\sqrt{\frac{275}{0.5} }[/tex]  

        w = 23.45 rad / s

        [tex]v_{max}[/tex] = 23.45 2.8 10⁻²

        [tex]v_{max}[/tex] = 0.657 m / s

c) maximum acceleration.

Acceleration is defined as the change in velocity withtrspect to time.

       a = [tex]\frac{dv}{dt}[/tex]  = - A w² cos (wt + fi)

To have the maximum value, the cosine function must be maximum, that is ±1

      a = A w²

let's calculate

       a = 2.8 10⁻²  23.45²

       a = 15.4 m / s²

In conclusion using the characteristics of the simple harmonic motion we can find the results for the questions of the oscillating mass are:

     a) The total energy is:  Em = 0.1078 J

     b) The maximum speed is:  v = 0.657 m / s

     c) the maximum acceleration is: a = 15.4 m / s²

Learn more here:  brainly.com/question/17315536

Answer:

For [tex]a > 0[/tex], at [tex]t = a \; \text{second}[/tex], the particle should have a velocity of [tex]\displaystyle -\frac{8}{a^3}\; \rm m \cdot s^{-1}[/tex].

Explanation:

Differentiate the displacement of an object (with respect to time) to find the object's velocity.

Note that the in this question, the expression for displacement is undefined (and not differentiable) when [tex]t[/tex] is equal to zero. For [tex]t > 0[/tex]:

[tex]\begin{aligned}v &= \frac{\rm d}{{\rm d}t}\, [s] = \frac{\rm d}{{\rm d}t}\, \left[\frac{4}{t^2}\right] \\ &= \frac{\rm d}{{\rm d}t}\, \left[4\, t^{-2}\right] = 4\, \left((-2)\, t^{-3}\right) = -8\, t^{-3} =-\frac{8}{t^3}\end{aligned}[/tex].

This expression can then be evaluated at [tex]t = 1[/tex], [tex]t = 2[/tex], and [tex]t = 3[/tex] to obtain the required results.

Answer:

a) Angular speed(w) = 2.02rad/sec

b) 73J ( It is Inelastic Collision)

Explanation:

Given:

Mass=45kg

Length on each side = 1.5m side which is hangs vertically from a frictionless pivot at the center of its upper edge.

We need to calculate

(a) What is the angular speed and

(b) To know why the angular momentum conserved but not the linear momentum

CHECK THE ATTACHMENT FOR DETAILED EXPLATION

Answer:

I belive its THAT HELPS US BE A BETTER PERSON

Answer:

Understands the purpose of moral standards and how to best fulfill that.

Explanation:

Answer:

A volume of a cubic meter of water from the surface of the lake has been compressed in 0.004 cubic meters.

Explanation:

The bulk modulus is represented by the following differential equation:

[tex]K = - V\cdot \frac{dP}{dV}[/tex]

Where:

[tex]K[/tex] - Bulk module, measured in pascals.

[tex]V[/tex] - Sample volume, measured in cubic meters.

[tex]P[/tex] - Local pressure, measured in pascals.

Now, let suppose that bulk remains constant, so that differential equation can be reduced into a first-order linear non-homogeneous differential equation with separable variables:

[tex]-\frac{K \,dV}{V} = dP[/tex]

This resultant expression is solved by definite integration and algebraic handling:

[tex]-K\int\limits^{V_{f}}_{V_{o}} {\frac{dV}{V} } = \int\limits^{P_{f}}_{P_{o}}\, dP[/tex]

[tex]-K\cdot \ln \left |\frac{V_{f}}{V_{o}} \right| = P_{f} - P_{o}[/tex]

[tex]\ln \left| \frac{V_{f}}{V_{o}} \right| = \frac{P_{o}-P_{f}}{K}[/tex]

[tex]\frac{V_{f}}{V_{o}} = e^{\frac{P_{o}-P_{f}}{K} }[/tex]

The final volume is predicted by:

[tex]V_{f} = V_{o}\cdot e^{\frac{P_{o}-P_{f}}{K} }[/tex]

If [tex]V_{o} = 1\,m^{3}[/tex], [tex]P_{o} - P_{f} = -10132500\,Pa[/tex] and [tex]K = 2.3\times 10^{9}\,Pa[/tex], then:

[tex]V_{f} = (1\,m^{3}) \cdot e^{\frac{-10.1325\times 10^{6}\,Pa}{2.3 \times 10^{9}\,Pa} }[/tex]

[tex]V_{f} \approx 0.996\,m^{3}[/tex]

Change in volume due to increasure on pressure is:

[tex]\Delta V = V_{o} - V_{f}[/tex]

[tex]\Delta V = 1\,m^{3} - 0.996\,m^{3}[/tex]

[tex]\Delta V = 0.004\,m^{3}[/tex]

A volume of a cubic meter of water from the surface of the lake has been compressed in 0.004 cubic meters.

Answer:

a) The linear acceleration of the car is [tex]4.65\,\frac{m}{s^{2}}[/tex], b) The tires did 7.46 revolutions in 2.50 seconds from rest.

Explanation:

a) A tire experiments a general plane motion, which is the sum of rotation and translation. The linear acceleration experimented by the car corresponds to the linear acceleration at the center of the tire with respect to the point of contact between tire and ground, whose magnitude is described by the following formula measured in meters per square second:

[tex]\| \vec a \| = \sqrt{a_{r}^{2} + a_{t}^{2}}[/tex]

Where:

[tex]a_{r}[/tex] - Magnitude of the radial acceleration, measured in meters per square second.

[tex]a_{t}[/tex] - Magnitude of the tangent acceleration, measured in meters per square second.

Let suppose that tire is moving on a horizontal ground, since radius of curvature is too big, then radial acceleration tends to be zero. So that:

[tex]\| \vec a \| = a_{t}[/tex]

[tex]\| \vec a \| = r \cdot \alpha[/tex]

Where:

[tex]\alpha[/tex] - Angular acceleration, measured in radians per square second.

[tex]r[/tex] - Radius of rotation (Radius of a tire), measured in meters.

Given that [tex]\alpha = 15\,\frac{rad}{s^{2}}[/tex] and [tex]r = 0.31\,m[/tex]. The linear acceleration experimented by the car is:

[tex]\| \vec a \| = (0.31\,m)\cdot \left(15\,\frac{rad}{s^{2}} \right)[/tex]

[tex]\| \vec a \| = 4.65\,\frac{m}{s^{2}}[/tex]

The linear acceleration of the car is [tex]4.65\,\frac{m}{s^{2}}[/tex].

b) Assuming that angular acceleration is constant, the following kinematic equation is used:

[tex]\theta = \theta_{o} + \omega_{o}\cdot t + \frac{1}{2}\cdot \alpha \cdot t^{2}[/tex]

Where:

[tex]\theta[/tex] - Final angular position, measured in radians.

[tex]\theta_{o}[/tex] - Initial angular position, measured in radians.

[tex]\omega_{o}[/tex] - Initial angular speed, measured in radians per second.

[tex]\alpha[/tex] - Angular acceleration, measured in radians per square second.

[tex]t[/tex] - Time, measured in seconds.

If [tex]\theta_{o} = 0\,rad[/tex], [tex]\omega_{o} = 0\,\frac{rad}{s}[/tex], [tex]\alpha = 15\,\frac{rad}{s^{2}}[/tex], the final angular position is:

[tex]\theta = 0\,rad + \left(0\,\frac{rad}{s}\right)\cdot (2.50\,s) + \frac{1}{2}\cdot \left(15\,\frac{rad}{s^{2}}\right)\cdot (2.50\,s)^{2}[/tex]

[tex]\theta = 46.875\,rad[/tex]

Let convert this outcome into revolutions: (1 revolution is equal to 2π radians)

[tex]\theta = 7.46\,rev[/tex]

The tires did 7.46 revolutions in 2.50 seconds from rest.

Answer and Explanation:

The estimation of the mass of the objects is as follows

Given that

The mass of an apple is about 100 g

Just like that, we do some estimation of different objects

A dime is around 1 g

A smartphone is about 100 g

An adult male is approx 100 kg

A college physics textbook is around 1 kg

A ripe banana is around 100 g

A small car is around 1,000 kg

Answer:

    Q = 735 J

Explanation:

In this exercise we must assume that all the mechanical energy of the system transforms into cemite energy.

Initial energy

        Em₀ = U = m g h

final energy

        [tex]Em_{f}[/tex] = Q

        Em₀ = Em_{f}

        m g h = Q

let's calculate

        Q = 30  9.8  2.5

        Q = 735 J

Answer:

I = 0.5A

Explanation:

Hello,

Assuming the transformer is an ideal transformer, we can calculate the value of the current using the formula.

Data;

Power = 60 watt

Primary voltage = 120 volts (rms)

Power (P) = current (I) × voltage (V)

P = IV

This formula is the relationship between power, current and voltage.

Current = power / voltage

I = P / V

I = 60 / 120

I = 0.5A

The current in the primary coil is 0.5A

Answer:

v₀ = 0.5058 m/s

Explanation:

From the question, for the block to hit the bottle, the elastic potential energy of the spring at the bottle (x = 0.08 m) should be equal to the sum of the elastic potential energy of the spring at x = 0.05 m and the kinetic energy of block at x = 0.05 m

Now, the potential energy of the block at x = 0.08 m is ½kx²

where;

k is the spring constant given by; k = ω²m

ω is the angular velocity of the oscillation

m is the mass of the block.

Thus, potential energy of the spring at the bottle(x = 0.08 m) is;

U = ½ω²m(0.08m)²

Also, potential energy of the spring at the bottle(x = 0.05 m) is;

U = ½ω²m(0.05m)²

and the kinetic energy of the block at x = 0.05 m is;

K = ½mv₀²

Thus;

½ω²m(0.08)² = ½ω²m(0.05)² + ½mv₀²

Inspecting this, ½m will cancel out to give;

ω²(0.08)² = ω²(0.05)² + v₀²

Making v₀ the subject, we have;

v₀ = ω√((0.08)² - (0.05)²)

So,

v₀ = 8.1√((0.08)² - (0.05)²)

v₀ = 0.5058 m/s

Answer:

f = 1.69*10^5 Hz

Explanation:

In order to calculate the frequency of the sinusoidal voltage, you use the following formula:

[tex]V_L=\omega iL=2\pi f i L[/tex]         (1)

V_L: voltage = 12.0V

i: current  = 2.40mA = 2.40*10^-3 A

L: inductance = 4.70mH = 4.70*10^-3 H

f: frequency = ?

you solve the equation (1) for f and replace the values of the other parameters:

[tex]f=\frac{V_L}{2\pi iL}=\frac{12.0V}{2\pi (2.4*10^{-3}A)(4.70*10^{-3}H)}=1.69*10^5Hz[/tex]      

The frequency of the sinusoidal voltage is f

Answer:

a) v₃ = 19.54 km, b)  70.2º north-west

Explanation:

This is a vector exercise, the best way to solve it is finding the components of each vector and doing the addition

vector 1 moves 26 km northeast

let's use trigonometry to find its components

         cos 45 = x₁ / V₁

         sin 45 = y₁ / V₁

         x₁ = v₁ cos 45

         y₁ = v₁ sin 45

         x₁ = 26 cos 45

         y₁ = 26 sin 45

         x₁ = 18.38 km

         y₁ = 18.38 km

Vector 2 moves 45 km north

        y₂ = 45 km

Unknown 3 vector

          x3 =?

          y3 =?

Vector Resulting 70 km north of the starting point

           R_y = 70 km

we make the sum on each axis

X axis

      Rₓ = x₁ + x₃

       x₃ = Rₓ -x₁

       x₃ = 0 - 18.38

       x₃ = -18.38 km

Y Axis

      R_y = y₁ + y₂ + y₃

       y₃ = R_y - y₁ -y₂

       y₃ = 70 -18.38 - 45

       y₃ = 6.62 km

the vector of the third leg of the journey is

         v₃ = (-18.38 i ^ +6.62 j^ ) km

let's use the Pythagorean theorem to find the length

         v₃ = √ (18.38² + 6.62²)

         v₃ = 19.54 km

to find the angle let's use trigonometry

           tan θ = y₃ / x₃

           θ = tan⁻¹ (y₃ / x₃)

           θ = tan⁻¹ (6.62 / (- 18.38))

           θ = -19.8º

with respect to the x axis, if we measure this angle from the positive side of the x axis it is

          θ’= 180 -19.8

          θ’= 160.19º

I mean the address is

          θ’’ = 90-19.8

          θ = 70.2º

70.2º north-west

Answer:

The ball dropped in water will reach the bottom of the container first because of the much lower viscosity of water relative to oil.

Explanation:

Oil is more less dense than water. Thus, the molecules that make up the oil are larger than those that that make up water, so they cannot pack as tightly together as the water molecules will do. Hence, they will take up more space per unit area and are we can say they are less dense.

So, we can conclude that the ball filled with water will reach the bottom of the container first this is because oil is less dense than water and so the glass ball filled with oil will be a lot less denser than the one which is filled with water.

Answer:

The coefficient of static friction is  [tex]\mu = 0.474[/tex]

Explanation:

From the question we are told that

   The position of the particle is  [tex]x = 41.00 \ mm = 0.041 \ m[/tex]

     The diameter of the CD is   [tex]d =120 \ mm = 0.12 \ m[/tex]

      The radius of the CD is evaluated as  [tex]r = \frac{d}{2} = \frac{0.12}{2} = 0.06[/tex]

     The angular velocity of the CD  when particle was ejected [tex]w = 84.0 rpm = 84 .0 * \frac{2 * \pi}{60} = 8.7976 \ rad/s[/tex]

At the instant just before the particle is ejected from the CD

    The frictional force of the particle  =  centrifugal force on the particle

So  

         [tex]\mu * m * g = mw^2 r[/tex]

=>       [tex]\mu * g = w^2 r[/tex]

=>       [tex]\mu = \frac{8.7976^2 * 0.06}{ 9.8}[/tex]

=>      [tex]\mu = 0.474[/tex]

Answer:

[tex]\alpha =[/tex] 26.2°(south of west)

Explanation:

Answer:

(a) Fw = 101.01 N

(b) W = 282.82 J

(c) Fg = 382.2 N

(d) N = 368.61 N

(e) Net force = 0 N

Explanation:

(a) In order to calculate the magnitude of the worker's force, you take into account that if the ice block slides down with a constant speed, the sum of forces, gravitational force and work's force, must be equal to zero, as follow:

[tex]F_g-F_w=0[/tex]        (1)

Fg: gravitational force over the object

Fw: worker's force

However, in an incline you have that the gravitational force on the object, due to its weight, is given by:

[tex]F_g=Wsin\theta=Mg sin\theta[/tex]       (2)

M: mass of the ice block = 39 kg

g: gravitational constant =  9.8m/s^2

θ: angle of the incline

You calculate the angle by using the information about the distance of the incline and its height, as follow:

[tex]sin\theta=\frac{0.74m}{2.8m}=0.264\\\\\theta=sin^{-1}(0.264)=15.32\°[/tex]

Finally, you solve the equation (1) for Fw and replace the values of all parameters:

[tex]F_w=F_g=Mgsin\theta\\\\F_w=(39kg)(9.8m/s^2)sin(15.32\°)=101.01N[/tex]

The worker's force is 101.01N

(b) The work done by the worker is given by:

[tex]W=F_wd=(101.01N)(2.8m)=282.82J[/tex]

(c) The gravitational force on the block is, without taking into account the rotated system for the incline, only the weight of the ice block:

[tex]F_g=Mg=(39kg)(9.8m/s^2)=382.2N[/tex]

The gravitational force is 382.2N

(d) The normal force is:

[tex]N=Mgcos\theta=(39kg)(9.8m/s^2)cos(15.32\°)=368.61N[/tex]

(e) The speed of the block when it slides down the incle is constant, then, by the Newton second law you can conclude that the net force is zero.

Answer:

-0.46 C

Explanation:

The relationship between total kinetic energy, KE, and total electric potential, V is:

ΔKE = ΔV * q

where ΔKE = change in kinetic

ΔV = change in voltage

q = charge

The kinetic energy changes from 87.6 J to 57.3 J while the electric potential changes from -48.0 V to 18.0 V.

Therefore:

57.3 - 87.6 = (18.0 - (-48.0)) * q

-30.3 = 66q

=> q = -30.3 / 66

q = -0.46 C

The charge of the particle is -0.46 C.

Answer:

c. [tex]-5. 65 \times 10^6 N m^2/C.[/tex]

Explanation:

The calculation of the electric flux through the sides of the box is shown below:-

Negative charge in insulating pitch ball, [tex]q = 50\times 10^{-6}[/tex]

[tex]Permittivity = 8.854 \times 10^{-12} F/m[/tex]

Now, we are placing the values into the formula which is here below:-

[tex]Flux = \frac{Negative\ charge}{Permittivity}[/tex]

[tex]= \frac{50\times 10^{-6}}{8.854 \times 10^{-12}}[/tex]

= [tex]-5. 65 \times 10^6 N m^2/C.[/tex]

Therefore we divided the negative charge by permittivity to reach out the electric flux through the sides of the box.

Answer:

25.125 N/m

Explanation:

extension on the spring e = 16 cm 0.16 m

mass of hung mass m = 410 g = 0.41 kg

equation for the relationship between force and extension is given by

F = ke

where k is the spring constant

F = force = mg

where m is the hung mass,

and  g is acceleration due to gravity = 9.81 m/s^2

imputing value, we have

0.41 x 9.81 = k x 0.16 = 0.16k

4.02 = 0.16k

spring constant k = 4.02/0.16 = 25.125 N/m

Answer:

factor that the electron's probability of tunneling through the barrier increase 2.02029

Explanation:

given data

kinetic energy = 10.1 eV

height = 18.2 eV

width = 1.00 nm

wavelength = 546 nm

solution

we know that probability of tunneling is express as

probability of tunneling = [tex]e^{-2CL}[/tex]   .................1

here C is = [tex]\frac{\sqrt{2m(U-E}}{h}[/tex]

here h is Planck's constant

c = [tex]\frac{\sqrt{2\times 9.11 \times 10^{-31} (18.2-10.1) \times (1.60 \times 10^{-19}}}{6.626\times 10^{-34}}[/tex]  

c = 2319130863.06

and proton have hf = [tex]\frac{hc}{\lambda } = {1240}{546}[/tex] = 2.27 ev

so electron K.E = 10.1 + 2.27

KE = 12.37 eV

so decay coefficient inside barrier is

c' = [tex]\frac{\sqrt{2m(U-E}}{h}[/tex]

c' = [tex]\frac{\sqrt{2\times 9.11 \times 10^{-31} (18.2-12.37) \times (1.60 \times 10^{-19}}}{6.626\times 10^{-34}}[/tex]  

c' = 1967510340

so

the factor of incerease in transmisson probability is

probability = [tex]e^{2L(c-c')}[/tex]

probability = [tex]e^{2\times 1\times 10^{-9} \times (351620523.06)}[/tex]

factor probability = 2.02029

Answer:

the data must be reliable

Explanation:

Answer:

[tex]53.1\mu C/m^2[/tex]

Explanation:

We are given that

Electric field,E=[tex]3\times 10^6V/m[/tex]

We have to find the value of maximum charge density that can be placed on the surface of the plane before dielectric breakdown of the surrounding air occurs.

We know that

[tex]E=\frac{\sigma}{2\epsilon_0}[/tex]

Where [tex]\epsilon_0=8.85\times 10^{-12}[/tex]

Using the formula

[tex]3\times 10^6=\frac{\sigma}{2\times 8.85\times 10^{-12}}[/tex]

[tex]\sigma=3\times 10^6\times 2\times 8.85\times 10^{-12}[/tex]

[tex]\sigma=5.31\times 10^{-5}C/m^2[/tex]

[tex]\sigma=53.1\times 10^{-6}C/m^2=53.1\mu C/m^2[/tex]

[tex]1\mu C=10^{-6} C[/tex]

Answer & Explanation: Waste management are all activities and actions required to manage waste from its inception to its final disposal. There are several methods of managing waste with its strengths and weaknesses. The strengths include;

* It creates employment

* It keeps the environment clean

* The practice is highly lucrative

* It saves the earth and conserves energy

The weaknesses of the methods of waste management includes;

* The sites are often dangerous

* The process is mostly

* There is a need for global buy-in

* The resultant product had a short life

Answer:

The correct answer is - option b. 90.6

Explanation:

The scalar x-component of a vector can be expressed as the product of its magnitude with the cosine of its direction angle

If you shine a light straight down onto that vector, then the length of its shadow on the x-axis is  -

x-component = 112· cosine(36°)

x-component = 112 · (0.8090)

x-component = 90.60

Thus, The correct answer is - option b. 90.6

Answer:

Explanation:

Momentum = mass*velocity of a body

For a 4.00 kg ball is moving at 4.00 m/s to the EAST, its momentum = 4*4 = 16kgm/s

For a 6.00 kg ball is moving at 3.00 m/s to the NORTH;

its momentum = 6*3 = 18kgm/s

Total momentum = The resultant of both momentum

Total momentum = √16²+18²

Total momentum = √580

total momentum = 24.1kgm/s

For the direction:

[tex]\theta = tan^{-1} \frac{y}{x}\\\theta = tan^{-1} \frac{18}{16}\\ \theta = tan^{-1} 1.125\\\theta = 48.4^{0}[/tex]

The total momentum is 24.1 kg m/s at an angle of 48.4 degrees NORTH of EAST

Answer:

476.82 N

Explanation:

In the given question, the speed of the car is given in mph,

therefore to convert mph in meter per second

= ( 140 x 1609) / 3600

= 62.58

Now, to find the frictional force, convert the power of the car that is hp into watt

we know, 1 hp = 746 W

therefore, 40 x 746

= 29840 watts.

Frictional force,

= power/ speed of car

= 29840/ 62.58

= 476.82 N

Thus, 476.82 N is the correct answer.

Answer:

3m/s²

Explanation:

The slope on a velocity time graph represents the acceleration, so if you simply use the slope formula, you can find the acceleration between those two points.

m=rise/run

m=(60-15)/(20-5)

m=45/15

m=3 m/s ² squared (therefore this is your constant acceleration from those two points).

Answer:

Replacement

Explanation:

in replacements, like ions replace like. in this equation, we can see that Bromine replaced Chlorine. so, the answer is replacement.

Answer:

Single-replacement or replacement

Explanation:

The single-replacement reaction is a + bc -> ac + b, compare them.

NaBr + Cl2 -> 2 NACl + Br.

AB + C -> AC + B

As you can see they are the same ( even though the b is with the a and not with the c. The formula can be switched around a little with the order of b and c ) ((also like ions replace like ions in replacements, which they are in this))

Answer:

(a) Yes, it is possible by raising the object to a greater height without acceleration.

Explanation:

The work-energy theorem states that work done on an object is equal to the change in kinetic energy, and change in  kinetic energy requires a change in velocity.

If kinetic energy will not change, then velocity will not change, this means that there will be constant velocity and an object with a constant velocity is not accelerating.

If the object is not accelerating (without acceleration) and it remains at the same height (change in height = 0, and mgh = 0).

Thus, for work to be done on the object, without changing the kinetic energy of the object, the object must be raised  to a greater height without acceleration.

Correct option is " (a) Yes, it is possible by raising the object to a greater height without acceleration".