Match the following kinds of lights in order from the longest wavelength to the shortest wavelength on the EM spectrum:
Group of answer choices
1

2

3

4

5

6

7

Answers
radio
infrared
gamma ray
microwave
x-ray
ultraviolet
visible

To find the mass attached to a spring when the frequency of oscillation is known, use the formula for the frequency of SHM (f = (1/2π) ∙ √(k/m)) and rearrange it to solve for mass.

To determine the mass attached to a horizontal spring where the frequency of oscillation is known, we can use the formula for the frequency of a mass-spring system undergoing simple harmonic motion (SHM), which is f = (1/2π) ∙ √(k/m), where f is the frequency, k is the spring constant, and m is the mass. Given a spring constant 9 N/m and a frequency 0.9 Hz, we can rearrange the formula to solve for the mass (m = k / (2πf)^2). Plugging in the values, we get the mass m = 9 N/m / (2π ∙ 0.9 Hz)^2, which we can calculate to find the mass of the object attached to the spring.

Using the frequency equation for a mass-spring system, the mass can be determined to be approximately 0.28 kg.

To find the mass attached to the spring, we can use the equation for the frequency of a mass-spring system:

Where:

This equation can be rearranged to solve for mass:

Plugging in the provided values:

First, simplify the expression inside the brackets:

Then:

Thus, the mass attached to the spring is approximately 0.28 kg.

Answer:

Explanation:

Given

Length of each wire [tex]L=1.3\ m[/tex]

On wire A second harmonic frequency is given by

[tex]f_2_{a}=2\times (\frac{v}{2L})[/tex]

where f=frequency

v=velocity of wave

L=length of wire

[tex]v_a=f_2\times L[/tex]

[tex]v_a=640\times 1.3=832\ m/s[/tex]

For wire B third harmonic is given by

[tex]f_3_{b}=3\times (\frac{v}{2L})[/tex]

[tex]v_b=\frac{2L}{3}\cdot f_3_{b}[/tex]

[tex]v_b=\frac{2\times 1.3}{3}\times 640=554.66\ m/s[/tex]

Answer:

F= 12 N

Explanation:

Given that

Work done by student ,W= 60 J

The mass of the box ,m = 3 kg

Length ,x = 5 m

We know that ,The work done by a force a force F is given as

W= F .x

x=Displacement

F=Force

W=Work

Now by putting the values

60 = F x 5

[tex]F=\dfrac{60}{5}\ N[/tex]

F= 12 N

That is why the magnitude of the force will be 12 N.

The magnitude of the force applied to the box to do the work is 12 N

Workdone is defined as the product of force and distance moved in the direction of the force. Mathematically, it can be expressed as:

Workdone (Wd) = force (F) × distance (d)

Wd = Fd

With the above formula, we can obtain the force used to do the work.

•Workdone (Wd) = 60 J

•Distance (d) = 5 m

•Force (F) =?

Wd = Fd

60 = F × 5

Divide both side by 5

F = 60 / 5

F = 12 N

Thus, 12 N is required to do the work.

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Answer:

The equation that will relate all the given parameters, in other to calculate the potential energy of charge A is:

∆V = ∆U/q, ∆V is potential at charge A position, q is magnitude of charge A, ∆U will be made the subject of the relation, which is the Potential Energy of charge A. The notation "∆" show, the quantities have both in values and final values, in the electric field.(Change in Electric potential and potential energy, due to the effect of the field)

Explanation:

The potential energy of a charged particle (Charge A) in an electric field depends on the magnitude of the charge(Known as stated in the question). However, the potential energy per unit charge has a unique value at any point in the electric field.

Answer:

Explanation:

Check attachment

The total electric potential in the center of the square due to 4 chargers at its corners is given by V_total= (4 * ke * Q) / sqrt( a^2/2 ), and the work needed to bring a fifth charge p from infinity to that point is W = p * (4 * ke * Q) / sqrt( a^2/2 ).

The electric potential at a particular point (center in this case) because of a point charge follows the formula V = k*Q / r where:

For four charges Q at corners of a square of side length a, the distance from the charge to the center of square would be sqrt(a^2/2), so:

V_total= (4 * ke * Q) / sqrt( a^2/2 )

The work done to bring a charge from infinity to a point is given by W = q * V_total where q is the charge being moved. So, under given circumstances:

W = p * (4 * ke * Q) / sqrt( a^2/2 )

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Answer:

[tex]a=4.2524\ m.s^{-2}[/tex]

Explanation:

Given:

two workers push a crate.

(Assuming that both the workers push in the same direction.)

We know that,

Acceleration is given as:

[tex]a=\frac{F}{m}[/tex]

[tex]a=\frac{F_1+F_2}{m}[/tex]

[tex]a=\frac{543+333}{206}[/tex]

[tex]a=4.2524\ m.s^{-2}[/tex]

The value of steam iron resistance is [tex]20ohm[/tex].

The relation between voltage, current and resistant shown below,

                      [tex]V=IR\\\\R=\frac{V}{I}[/tex]

Where V is voltage and I is current .

 Given that,  [tex]I=6A,V=1.20*10^{2}[/tex]

Substitute values in above relation.

                  [tex]R=\frac{1.2*10^{2} }{6}=20ohm[/tex]

Hence, the value of steam iron resistance is [tex]20ohm[/tex].

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The resistance of the steam iron can be calculated using Ohm's Law, expressed as the formula R = V/I. With a current of 6.00 A and a voltage of 1.20 ✕ 102 V, the steam iron has a resistance of 20.0 Ohms.

The electrical characteristics of a device, including resistance, can usually be determined using Ohm's Law, which states that the current through a conductor between two points is directly proportional to the voltage across the two points. It can be expressed in the formula R = V/I, where R is resistance, V is voltage, and I is current.

In this case, our steam iron has a current (I) of 6.00 A and a voltage (V) of 1.20 ✕ 102 V. Substituting these values into the Ohm's Law formula gives us: R = (1.20 x 102 V) / 6.00 A.

This calculates to a resistance (R) of 20.0 Ohms for the steam iron.

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Answer:

a) 0.069 acres

b) 0.114acres

c) 17.78acres

Explanation:

1 dot=1/36sqin

a) 1 sqin= 330×330=108900ft^2

1 dot=108900/36 =3025ft^2

Converting to acre,divide by43560

3025/43560 =0.069acre

b) 1 chain =22 yards

25×22=550yards

Converting to acre divide by 4840

550/4840 =0.114acre

c)1 sqmile =640acres

(1/36) ÷ 640

640/36

17.78acres

To calculate the area represented by each dot on the dot grid, you need to consider the scale of the map. With a scale of 330 ft. per inch, 1 dot represents (330^2 / 43,560) acres. With a scale of 25 chains per inch, 1 dot represents ((25 chains)^2 / 10) acres. And with a scale of 1 mile per inch, 1 dot represents ((1 mile)^2 / 640) acres.

Explanation:

The conversion from dots to acres varies depending on the scale:

Answer:

Precipitation is the formation of a solid from a solution. It is necessary to centrifuge the precipitate to exert sufficient forces of gravity to bring the solid particles in the solution to come together and settle

Explanation:

When you centrifuge precipitate it enables the nucleation to form.

Centrifuging the precipitate helps in determining whether a certain element is present in a solution or not.

Final answer:

Centrifuging out the precipitate formed in an unknown solution prevents it from interfering with the analysis of remaining ions. The separated supernatant can then be further tested to identify other ions while avoiding unwanted reactions and ensuring precise characterizations of the substances involved.

Explanation:

It is necessary to centrifuge out any precipitate formed in the unknown solution during a chemical analysis for several reasons. The process of centrifugation uses inertia to separate particles in the fluid, so when the precipitate forms due to the reaction of different ions, it needs to be removed to isolate the remaining supernatant. The purpose is to ensure that subsequent testing only involves the dissolved substances, without interference from solids that have already reacted. Moreover, analysis of the residue is crucial after centrifugation and sometimes after supernatant evaporation to dryness, followed by reconstitution of the residue. This allows for a detailed study of the precipitate itself.

The remaining solution, after centrifugation, contains the supernate which may still contain ions or molecules of interest. If the precipitate is not removed, the solids could skew the results of further tests by hiding the presence of other ions or reacting further in unwanted ways. The separated liquid, or supernatant, can then be subjected to additional tests to identify other ions that may be present. For instance, if one is testing for the presence of barium sulfate in a mixture, tests like the precipitin ring test or radial immunodiffusion assay can be used, which demonstrates the presence of specific substances without the interference from the precipitate removed by centrifugation.

Answer:

Neural processing

Explanation:

Neural processing- it is referred to as the unit that is responsible for the implementation of arithmetic logic which is crucial for the execution of machine learning algorithms.

it is used to operate the artificial neural network in designing and can be helpful to enhance the efficiency of machine learning applications like artificial language.

To find the approximate value of the effective spring stiffness of the interatomic bond, calculate the stiffness constant of the titanium wire using Young's modulus.

To find the approximate value of the effective spring stiffness of the interatomic bond, we need to calculate the stiffness constant of the titanium wire. The stiffness constant, or Young's modulus (Y), is given by the formula Y = F/A/L, where F is the force applied, A is the cross-sectional area of the wire, and L is the original length of the wire.

First, we need to find the force applied. The force can be calculated using the equation F = mg, where m is the mass and g is the acceleration due to gravity.

Next, we need to calculate the cross-sectional area of the wire. The cross-sectional area can be calculated using the formula A = π(r^2), where r is the radius of the wire.

Finally, we can substitute the values into the formula Y = F/A/L to find the Young's modulus of the titanium wire.

Answer:

a. FTh = 30 N

b. Fw = 30 N

c. a = 200 m/s2

Explanation:

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The magnitude of squid thrust force, magnitude of force on the water and the acceleration experienced by the water is required.

The magnitude of squid thrust force and magnitude of force on the water is 30 N.

The acceleration is [tex]200\ \text{m/s}^2[/tex]

m = Mass

a = Acceleration

m = 1.5 kg

a = [tex]20\ \text{m/s}^2[/tex]

Thrust force

[tex]F=ma\\\Rightarrow F=1.5\times 20\\\Rightarrow F=30\ \text{N}[/tex]

The magnitude of squid thrust force will be equal to the magnitude of force on the water from the third law of motion.

F = 30 N

m = 0.15 kg

Acceleration is given by

[tex]a=\dfrac{F}{m}\\\Rightarrow a=\dfrac{30}{0.15}\\\Rightarrow a=200\ \text{m/s}^2[/tex]

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Answer:

Explanation:

given that

Radius =0.75m

Cnet=0.13nC

a. Electric field inside the sphere located 0.5m from the center of the sphere.

The electric field located inside the sphere is zero.

b. The electric field located 0.25m beneath the sphere.

Since the radius is 0.75m

Then, the total distance of the electric field from the centre of the circle is 0.75+0.25=1m

Then

E=kq/r2

K=9e9Nm2/C2

q=0.13e-9C

r=1m

Then,

E= 9e9×0.13e-9/1^2

E=1.17N/C. Q.E.D

Answer:

Magnitude of Electric field E at at point 0.50m which is within the sphere is Zero( i.e E = 0)

Explanation:

It is understand from Guass' law, the electric field in a region enclosed by a conducting sphere is Zero.

It is given that the radius of the sphere is 0.75m, therefore, a point located at 0.50m from the sphere centre 0.25m before the sphere surface still falls inside the sphere, therefore making the electric field at that point zero in magnitude.

Answer:

A. describes how an object accelerates when a force is applied

Explanation:

Newton's second law of motion concerns the behavior of objects that do not have a stability between all established forces. The second law states that an object's acceleration depends on two factors: the net force on the entity and the entity's mass.

Answer:

We need 4 times more force to keep the car in circular motion if the velocity gets double.

Explanation:

Lets take the mass of the car = m

The radius of the arc = r

[tex]F=\frac{m\times v^2}{r}[/tex]

Given that speed of the car gets double ,v' = 2 v

Then the force on the car = F'

[tex]F'=\frac{m\times v'^2}{r}[/tex]  ( radius of the arc is constant)

[tex]F'=\frac{m\times (2v)^2}{r} [/tex]

[tex]F'=4\times \frac{m\times v^2}{r}[/tex]

We know that [tex]F=\frac{m\times v^2}{r}[/tex]

Therefore F' = 4 F

So we can say that we need 4 times more force to keep the car in circular motion if the velocity gets double.

The magnitude of centripetal force will become four times with the twice the greater speed of car.

Given data:

The magnitude of centripetal force on car is, Fc.

The force acting on any object undergoing the motion around the circular path, such that the motion is balanced is known as centripetal force. It is also known as the center-seeking force. And the expression for the centripetal force is given as,

Fc = mv²/r

Here,

m is the mass of car.

v is the speed of car.

r is the radius of circular track.

If the speed of car is twice as great, then the new centripetal force is given as,

F'c = m(2v)²/r

F'c = 4 × mv²/r

F'c = 4 × Fc

Thus, we can conclude that the magnitude of centripetal force will become four times with the twice the greater speed of car.

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Answer:

880Hz

Explanation:

A violin string is an example of an open pipe. An open pipe is open at both ends.

The fundamental frequency is the first harmonic.In an open pipe the second harmonic is twice the fundamental frequency.

Hence, second harmonic = 2Fo

Fo=440Hz

Second harmonic = 2*440Hz

Second harmonic = 880Hz

Answer: relative motion between observer and the sound source.

Explanation: The Doppler effect states that when there is a relative motion between an observer and a sound source the frequency of sound perceived by the observer is different in frequency from the original from the source.

The mathematical back up for this claim is given below.

f' = (v+v') /(v-vs) × f

Where f' = observed frequency

v = speed of sound in air

v' = velocity of observer

vs = velocity of source

f = frequency of sound source.

From the formulae, it can be seen that a change in the value of the velocity of observer (v') and source (vs) produces different value of observed frequency (f').

Note, frequency of sound (f) is a constant.

Explanation:

Let upper direction be positive

We have equation of motion v = u + at

     Initial velocity, u = 11 m/s

     Final velocity, v = ?

     Time, t = 2 s

     Acceleration,a = -9.81 m/s²

     Substituting

                      v = u + at  

                      v = 11 + -9.81 x 2

                      v = -8.62 m/s

    Speed of ball after 2 seconds is 8.62 m/s downward.

Option 4 ( R2 and R3 ) is the correct answer.

Explanation:

Hence we can conclude that Resistor R2 and R3 are the ones that are connected in parallel.

Answer:

10.12square feet

Explanation:

Pressure exerted on the object is defined as the ratio of the force exerted on it to its unit area. Mathematically, Pressure = Force/Area

Given the force = 170kN

Pressure = 180KPa

Area = Force /Pressure

Area = 170kN/180KPa

Area = 0.94N/Pa

Note that 1Newton/Pascal = 10.764square feet

Therefore 0.94N/Pa = x

x = 0.94× 10.764

x = 10.12square feet

Therefore the area upon which this pressure is exerted is 10.12sqft.

Final answer:

Match the correct statistical methods to their definitions as follows: Frequency counts are A (applied to categorical values), Frequency distribution is B (applied to quantitative values), Measurements of central tendency are C (mean, median, and mode), and Measurements of spread are D (max, min, percentiles, and standard deviation).

Explanation:

When examining statistical methods, it is important to correctly match each concept with its definition to understand data analysis better. Here are the correct matches:

These matches are crucial in the proper analysis and interpretation of data whether you are dealing with categorical or quantitative data. It's important to apply the correct statistical method for the level of measurement being dealt with, such as nominal, ordinal, interval, or ratio scales.

Answer:

Δp=2.0×10⁴N/cm²

Explanation:

We can write the bulk modulus formula and we solve pressure difference Δp

So

B=Δp(V₀ / ΔV)

Δp=B( ΔV / V₀)

As ΔV / V₀ is given as 9.05×10⁻²

So

Δp=B(9.05×10⁻²)

Δp=(0.22×10¹⁰)(9.05×10⁻²)

Δp=2.0×10⁸ N/m²

Δp=2.0×10⁸ N/m²×(1m²/10⁴cm²)

Δp=2.0×10⁴N/cm²

Answer:

2.0×10⁸ N/m².

Explanation:

Bulk modulus, B is defined as the ratio of the infinitesimal pressure increase to the resulting relative decrease of the volume

B = -V₀ * (Δp/ΔV)

Given:

ΔV/V₀ = 9.05×10⁻²

Bw = 0.22×10¹⁰

Δp = -B * (ΔV/V₀)

= (0.22×10¹⁰) * (9.05×10⁻²)

= 2.0×10⁸ N/m².

Explanation:

(a)  Formula for average translational kinetic energy of a particle is as follows.

                   U = [tex]\frac{3}{2}(\frac{RT}{N})[/tex]

where,   R = Reydberg's constant

              T = absolute temperature

              N = Avogadro's number

Therefore, we will calculate value of average translational kinetic energy as follows.

                 U = [tex]\frac{3}{2}(\frac{RT}{N})[/tex]

                    = [tex]\frac{3}{2}(\frac{8.314 J/mol K \times 6000 K}{6.023 \times 10^{23} mol^{-1}})[/tex]

                    = [tex]1.24 \times 10^{-19}[/tex] J

Therefore, value of average translational kinetic energy is [tex]1.24 \times 10^{-19}[/tex] J.

(b)   Formula for average kinetic energy is as follows.

             K.E = [tex]\frac{1}{2}(\frac{M}{N})v^{2}_{rms}[/tex]

Here,   M = molar mass = 1 kg/K mol

And, the average kinetic energy is equal to the average translational kinetic energy.

Hence,   K.E = U

     [tex]\frac{1}{2}(\frac{M}{N})v^{2}_{rms}[/tex] = [tex]\frac{3}{2}(\frac{RT}{N})[/tex]

            [tex]v^{2}_{rms} = \frac{3RT}{M}[/tex]

            [tex]v = \sqrt{\frac{3RT}{M}}[/tex]

therefore, we will calculate r.m.s speed of the given atom as follows.

              [tex]v = \sqrt{\frac{3RT}{M}}[/tex]

              [tex]v = \sqrt{\frac{3 \times 8.314 J/mol K \times 6000 K}{1 kg/K mol}}[/tex]

              = 386.84 m/s

Hence, value of r.m.s speed of the given atom is 386.84 m/s.

Following are the solution to the given points:

Given:

Temperature [tex]= 6000\ K[/tex]

To find:

kinetic energy =?

rms speed of the atoms=?

Solution:

For point a)

[tex]\to Avg \ KE =\frac{3}{2}\ KT \\\\[/tex]

[tex]\to KE_{avg} =1.5 \times 1.38 \times 10^{-23} \times 6000 \\\\[/tex]

                [tex]=1.5 \times 1.38 \times 10^{-23} \times 6000 \\\\=2.07 \times 10^{-23} \times 6000 \\\\=2.07 \times 10^{-23} \times 6000 \\\\=12.420 \times 10^{-20}\ J[/tex]

For point b)

[tex]\to[/tex] rms speed [tex]V_{rms}[/tex]:  

[tex]\to v_{rms}=\sqrt{\frac{3RT}{M}}[/tex]

             [tex]=\sqrt{\frac{3 \times 8314 \times 6000}{1}} \\\\=\sqrt{\frac{24942\times 6000}{1}} \\\\=\sqrt{149652000}\\\\=12233.233\\\\ = 12233\ \frac{m}{s}[/tex]

Therefore, the final answer is "[tex]12.420 \times 10^{-20} \ J\ \ and \ \ 12233 \ \frac{m}{s}[/tex]".

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Answer:

C. software

Explanation:

software, is a collection of data or computer instructions that tell the computer how to work. This is in contrast to physical hardware, from which the system is built and actually performs the work.

Answer:gbji

Explanation:

hbbju

Explanation:

We know from newton's 2nd law that F= m/a. That is force directly proportional to mass and inversely proportional to acceleration. F is same for the skier and Earth but mass is different for both. m for earth is way larger than the m for skier. So, for constant Force , a of Earth must very small as compared with a of the skier.

Skiers and skateboarders accelerate due to action-reaction force pairs in accordance with Newton's third law, but the Earth's immense mass leads to negligible acceleration, rendering its movement imperceptible.

Understanding Force and Acceleration

When discussing the action-reaction force pair between the Earth and a skier, Newton's third law of motion is essential. This law states that for every action, there is an equal and opposite reaction. When the skier accelerates, the force exerted on them by the Earth (gravity) is met with an equal and opposite force exerted by the skier back onto the Earth. The reason the Earth does not seem to move while the skier accelerates is due to the massive difference in mass between the Earth and the skier. Since acceleration is calculated as force divided by mass (F = ma), the much larger mass of the Earth compared to the skier results in a negligible acceleration of the Earth. This is similar to why stationary skater A does not move when pushing skater B; if skater A has more contact with the surface or better frictional grip, they may not move significantly despite exerting force.

Furthermore, when objects like a skateboarder jump off a building, both the Earth and the skateboarder exert mutual forces on each other. Despite experiencing the same total change of momentum, the Earth's massive size means its acceleration is imperceptible, while the skateboarder moves considerably more.

Answer:

0.26087 rad/s

Explanation:

mass of the child (m) = 40 kg

velocity (v) = 3 m/s

distance (r) = 1.5 m

moment of inertia (I) = 600 kg.m^{2}

rotational momentum of the child = Iω

where

rotational momentum of the child = Iω = 90 x 2 = 180 kg[tex]m^{2}[/tex]/s

from the conservation of momentum the initial momentum of the child must be the same as the final momentum of the child

initial momentum of the child = final momentum of the child

180 = (90 + 600) ω

180 = 690 ω

ω = 180 / 690 = 0.26087 rad/s

The angular or rotational momentum is the conserved quantity that has both magnitude and direction. It is given by:

[tex]\rm L = mvr[/tex]

Where,

L = rotational/angular momentum, m = mass, v = velocity and r = radius

The angular speed will be 0.26087 rad/s.

The speed can be estimated as:

Given,

Rotational momentum is calculated by Iω.

Where,

[tex]\begin{aligned}&= 40 \times (1.5)^{2} \\&= 90 \rm kg/m^{2}\end{aligned}[/tex]

[tex]\begin{aligned}&= \dfrac{3 }{1.5} \\&= 2 \rm rad/s\end{aligned}[/tex]

Rotational momentum of the child = Iω

[tex]\begin{aligned} \rm I\omega &= 90 \times 2 \\\\&= 180 \;\rm kgm^{2}/s\end{aligned}[/tex]

The final and the initial momentum would be the same according to the conservation law.

Initial momentum = Final momentum

180 = (90 + 600) ω

180 = 690 ω

Solving further:

[tex]\begin{aligned}\omega &= \dfrac{180}{690}\\\\&= 0.26087 \;\rm rad/s\end{aligned}[/tex]

Therefore, 0.26087 rad/s is the angular speed.

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Answer:q=3.536+10^-6C

Explanation:

Answer:

False

Explanation:

The ‘sigma’ refers to the Greek letter used to denote standard deviation, so ‘six sigma’ means that the error rate lies beyond six standard deviations from the mean.

Answer: Relative motion

Explanation: If two objects are moving either towards or away from each other with both having their velocities in a reference frame and someone is outside this reference frame seeing the motion of the two objects.

The observer ( in his own frame of reference) will measure a different velocity as opposed to the velocities of the two object in their own reference frame. p

Both the velocity measured by the observer in his own reference frame and the velocity of both object in their reference is correct.

Velocities of this nature that have varying values based on motion referenced to another body is known as relative velocity.

Motion of this nature is known as relative motion.

Note that the word reference frame is simply any where the motion is occurring and the specified laws of motion is valid

For this example of ours, the reference frame of the companion is the train and the telephone poles has their reference frame as the earth.

The companion will measure the velocity of the telephone poles relative to him and the velocity of the telephone pole relative to an observer outside the train will be of a different value.

Answer:

An object can have both kinetic and potential energy at the same time.

Explanation:

For example, an object which is falling, but has not yet reached the ground has kinetic energy because it is moving downwards, and potential energy because it is able to move downwards even further than it already has.

Final answer:

An object can have both kinetic and potential energy at the same time, such as a ball thrown in the air. The sum of these two types of energy in a closed system remains constant unless non-conservative forces are present.

Explanation:

Yes, an object can indeed have kinetic and potential energy at the same time. Consider a ball thrown upward; at any point in its trajectory, except the peak, the ball will have both kinetic energy due to its motion and potential energy due to its height above the ground. To address whether the sum of kinetic energy and potential energy can change without work being done on the object: In a closed system where no external work is applied, the sum of kinetic and potential energies remains constant because of the conservation of mechanical energy. However, if non-conservative forces like friction are involved, they can convert mechanical energy into thermal energy, thus decreasing the total mechanical energy without any external work being performed.