Nyah explains to Arman the importance of decomposers in an ecosystem. Which sentence(s) should she use in her explanation? Select all that apply.


A.) Decomposers provide food for consumers.


B.) An ecosystem cannot function without decomposers.

C.) Most ecosystems have only one type of decomposer.


D.) Decomposers help to recycle nutrients in an ecosystem

E.) Fungi, plants, and insects are examples of decomposers.

Whatever amount of force each person exerts on the box, THAT's the amount of force the box exerts on him.  There's no reason the forces of each person have to be equal.

Let's say . . .

-- Mr. Smith pushes on the box with 499.99 newton's of force.

-- Mr. Jones is actually a fly; he pushes on the box with 0.01 newton of force.

The total of their forces is 500 Newtons on the box.

The box exerts 499.99 newtons of force back on Mr. Smith, and 0.01 newton of force back on Mr. Jones, the fly.

according to newton's second law , net force on an object is the product of mass of the object and the acceleration of the object. the formula is given as

F = ma               where F = net force , m = mass and a = acceleration

so acceleration can be given as

a = F/m

for same net force , the acceleration depends on the mass of the object .

greater the mass , smaller will be the acceleration and vice versa.

Since the mass of electron is smaller as compared to the mass of proton, hence the electron will accelerate more as compared to proton.

A) The electron will accelerate more than the proton

A) the electron will accelerate more than the proton.

If the net force is greater than one, SOOO Newton’s second law of motion, an object will accelerate. The mass is inversely proportional to the acceleration. The lower the mass, the faster the acceleration,

hope this helps! :)

Answer:

Light wave can travel in a vacuum and travel at a contest speed even if the light source is moving

Explanation:

Light waves are electromagnetic waves and they need no medium to travel. The speed of light is constant and does not change with the movement of source.

Electromagnetic waves are transfer of energy through vacuum. These electromagnetic waves are associated with specific wavelength, frequency and energy.

Visible light is in between IR and UV waves in electromagnetic spectrum. Light is the fastest moving thing in the world and  it does need a medium to travel. The waves which need a medium to propagate is called mechanical waves.

Therefore, the true statement about light is light waves can travel in a vacuum and travel at a constant speed even if the light source is moving. Thus, option B is correct.

To find more on electromagnetic waves, refer here:

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Work is defined as a force acting on a body in the direction of a displacement. The unit for displacement is the meter, and the unit for a force is the Newton. Therefore, the unit for work is the Newton-meter or joule.

Answer:

A. 1560 Hz

Explanation:

The Doppler effect occur when a source of a wave (like sound) is moving relative to an observer (or when the observer is moving relative to the source). When this happens, the apparent frequency of the sound as heard by the observer is shifted with respect to the real frequency, according to the formula:

[tex]f'=\frac{v}{v-v_s}f[/tex]

where

f' is the apparent frequency

v is the speed of the wave

vs is the velocity of the source relative to the observer (positive if the source is moving towards the observer, negative if it is moving away from the observer)

f is the real frequency of the wave

In this problem, we have the following data:

f = 1100 Hz is the original frequency of the sound

v = 340 m/s is the speed of the sound wave

[tex]v_s = 100 m/s[/tex] is the velocity of the car approaching the pit crew

Substituting these numbers into the formula, we can find the frequency heard by the pit crew:

[tex]f'=\frac{340 m/s}{340 m/s-100 m/s}(1100 Hz)=1558 Hz \sim 1560 Hz[/tex]

Answer:  option A. 1560 Hz

Explanation:

Doppler effect is the phenomenon wherein the frequency of the source of the sound is different from what is received. This happens when either of the source or observer or both are relatively in motion.

In the given question, the observer is stationary and the source of sound is moving at the speed of [tex]v_s = 100 m/s[/tex] towards the observer. The frequency of the sound emitted is [tex]f_s = 1100 Hz[/tex]. The frequency heard by the pit crew member would be given by:

[tex]f_o = \frac{V}{V-v_s}f_s[/tex]

[tex]f_o = \frac{340 m/s}{340m/s - 100 m/s}\times 1100 Hz = 1558.3 Hz = 1560 Hz (approx)[/tex]

Thus, the frequency heard by the pit crew would be 1560 Hz. Correct option is A.

Answer:

12.3 years

Explanation:

The equation of the radioactive decay can be written as follows:

[tex]\frac{N(t)}{N_0}=(\frac{1}{2})^{\frac{t}{\tau_{1/2}}}[/tex] (1)

where

N(t) is the amount of radioactive sample left at time t

N0 is the amount of radioactive sample at time t=0

t is the time passed

[tex]\tau_{1/2}[/tex] is the half-life of the isotope

The problem tells us that after t=36.9 y, the amount of sample which has become stable is 7/8. This means that 7/8 of the sample has already decayed, so the amount of radioactive sample left is

[tex]\frac{N(t)}{N_0}=1-\frac{7}{8}=\frac{1}{8}[/tex]

We can now re-arrange equation (1) by using this information and by substituting t=36.9 y we find:

[tex]\frac{t}{\tau_{1/2}}=log_{1/2} (\frac{N(t))}{N_0})\\\tau_{1/2}=\frac{t}{log_{1/2}(\frac{N(t)}{N_0})}=\frac{36.9 y}{log_{1/2}(1/8)}=\frac{36.9 y}{3}=12.3 y[/tex]

So, the answer is

12.3 years

Answer:

A. 12.3 years

Explanation:

transparent --> translucent --> opaque

A. Is the correct answer

Answer:

A is the correct answer :)))

Explanation:

Two forces pull on an object at the same time. Their resultant force is least when the angle between the forces is 180°.

Answer: Option D

Explanation:

When two forces are acting on an object, two possibilities are there.

(i) Forces acting on the same direction.

(ii) Forces acting o the opposite direction.

When two forces are acting on the same direction, their resultant force will be maximum, but when they are acting on the opposite direction, minimum resultant force will be the outcome (i.e) they are 180 degrees apart.

-4.73 m/s²

Each jumper represents about 1/2 of 1% of the mass of the train, so together they total about 3.5% of the mass of the train. If the mass decreases by 3.5% and the braking force remains the same, the acceleration (magnitude) will increase by about 3.5%.

The acceleration will be about 0.17 m/s² more (in magnitude) than it was, or about -4.73 m/s².

No, temperature change in the Earth's atmosphere is related to the distance from the sun, and temperature generally decreases altitude.

Answer:

This is true for some layers of the Earth's atmosphere.

Explanation:

As a counterexample: in the lowest layer of the atmosphere, with the highest density of gases, aka the Troposphere, the temperature decreases with increasing altitude. This relates to the sun heating up the surface some of which radiates back into the Troposphere.

However, the  temperature increases with altitude in the Stratosphere (effect of ozone absorbing Sun rays), and it also increases with altitude in the Thermosphere (due to UV rays absorption).

The Mesosphere is another counterexample where the temperature decreases with increasing altitude.

The answer is periosteum. Hope this helps!

The periosteum is the thin, dense membrane that covers the outer layer of bones, providing nourishment and playing a key role in bone growth, repair, and remodeling, excluding areas where bones form joints.

The thin, dense membrane that covers the outer layer surface of the bone is called the periosteum. This membrane is vitally important as it contains blood vessels, nerves, and lymphatic vessels that nourish the compact bone beneath it. Notably, the periosteum connects to the bone with strong collagen fibers known as Sharpey's fibers, which are integral in the attachment of tendons and ligaments. Although it covers most of the bone's surface, the periosteum does not cover the areas where bones form joints; these areas are protected by a different type of tissue. The function of the periosteum is not only protective; it also plays a crucial role in bone growth, repair, and remodeling due to its layer of bone-forming cells.

D. because Isotopes will have the same atomic number because they are the same element but have a different atomic mass because they contain a different number of neutrons.

Isotopes of the same element differ in the number of neutrons they contain, which leads to different atomic weights but doesn't change the chemical properties of the element.

Isotopes are variations of a particular chemical element, which means they will always have the same number of protons and the same atomic number. However, isotopes of the same element differ in their number of neutrons. This can lead to different physical properties, such as mass, but the chemical properties remain largely unaffected because chemical behavior is determined by the number of electrons, which remains constant in isotopes of the same element. For example, Carbon-12 (12C) and Carbon-14 (14C), are both isotopes of Carbon where the number refers to the atomic weight, which changes due to the different numbers of neutrons.

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False

If the object weighs more than the buoyant force then the object will sink.

This is because the buoyant force "pushes" the object upwards and the weight of the object "pushes" the object downwards.  Since the force downwards is greater than the force upwards the item will sink, so this statement is False.

~~~Brainliest would be appreciated~~~

Answer

40 degrees

Explanation

When waves hit a surface they get reflected. The law of reflection states that the angle of incidence is equal to the angle of reflection. In this case, the law of reflection tells us that if the angle of incidence is 40 degrees, the angle of reflection is 40 degrees.

Answer:

[tex]2Mg + O_2 \rightarrow 2MgO + heat[/tex] (2 atoms on the product side)

Explanation:

Due to the law of conservation of mass, in every chemical reaction the number of atoms of each element on the reactant side must be equal to the number of atoms of the same element on the product side.

In this case, on the product side we have magnesium (which has two valence electrons) and oxygen (which has two vacancies in its outer shell). This means that they combine in a ratio 1:1, so the product of the reaction is

[tex]MgO[/tex]

However, we must put a coefficient 2 in front of it in order to balance the number of atoms of each element: in fact, on the reactant side we have 2 atoms of magnesium and 2 of oxygen, so we must have two atoms of magnesium and 2 of oxygen on the product side as well. Therefore, the complete reaction is

[tex]2Mg + O_2 \rightarrow 2MgO + heat[/tex]

Friction always acts opposite to the motion.  (B)

The answer is B.one plate slides beneath another due to gravitational pull.

Answer:

Its B

Explanation:

took the test 2020

Answer:

(A) 18 km/h

Explanation:

[tex]4.9\frac{m}{s}=4.9\cdot \frac{\frac{1}{1000}km}{\frac{1}{3600}h}=4.9\cdot3.6\frac{km}{h}=17.64\frac{km}{h}\approx18\frac{km}{h}[/tex]

1) 5 N

The crate is initially moving, so we must calculate the force of kinetic friction, which is given by:

[tex]F_f = \mu_k mg[/tex]

where

[tex]\mu_k=0.2[/tex] is the coefficient of friction between the crate (made of wood) and the floor (made of wood). The coefficient of kinetic friction between wood and wood is about 0.2.

[tex]mg=25 N[/tex] is the weight of the crate

Substituting the numbers into the formula, we find

[tex]F_f=(0.2)(25 N)=5 N[/tex]

2) 5 N

There are two forces acting on the crate along the horizontal direction:

- The force that pushes the crate toward the right, of magnitude [tex]F=10 N[/tex]

- The force of friction, which acts in the opposite direction (so, towards the left), of magnitude [tex]F_f = 5 N[/tex]

Since the two forces are in opposite directions, the net force is given by their difference:

[tex]F_{net}=F-F_f = 10 N-5 N=5 N[/tex]

3) Yes

The crate is accelerating. In fact, according to Second Newton's Law:

[tex]F_{net}=ma[/tex] (1)

where Fnet is the net force on the crate, m is its mass, a is its acceleration. We can immediately see that since Fnet is not zero, the acceleration is also non-zero, so the crate is accelerating.

We can even calculate the magnitude of the acceleration. In fact, the mass of the crate is given by:

[tex]m=\frac{Weight}{g}=\frac{25 N}{9.8 m/s^2}=2.55 kg[/tex]

And by using (1) we find

[tex]a=\frac{F_{net}}{m}=\frac{5 N}{2.55 kg}=1.96 m/s^2[/tex]

Exact calculations for solving this physics problem are hindered by a lack of information on the coefficient of friction, but it can be asserted that the net force acting on the crate is 10N, and the crate should be accelerating due to this net force.

In this scenario we're dealing with the concepts of force, friction, and acceleration from the field of physics. Let's go step by step.

1) The frictional force equals the weight of the crate times the coefficient of friction. But since we are not given the coefficient of friction, we cannot calculate it. However, to calculate it, you would use the following formula: Force of Friction = µ * Weight

2) The net force is simply the sum of all forces. Here, there's only one force acting on the crate in horizontal direction - the force of 10N to the right. Therefore, the Net Force = 10 N.

3) If there's a net force acting on an object, it means the object is accelerating, as per Newton's Second Law of Motion(F=ma). This suggests that the crate is indeed accelerating.

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Answer:

A) 37 m

Explanation:

When the driver slams on the brakes, the force of friction acting on the car provides the deceleration that will cause the car to stop, according to Newton's second law:

[tex]-\mu mg = ma[/tex]

where

[tex]\mu = 0.80[/tex] is the coefficient of friction

m = 1000 kg is the mass of the car

g = 9.8 m/s^2

a is the deceleration

Substituting into the formula, we find the deceleration:

[tex]a=- \mu g=-(0.80)(9.8 m/s^2)=-7.84 m/s^2[/tex]

Now we can find the length of the skid with the SUVAT equation:

[tex]v^2 - u^2 = 2ad[/tex]

where

v = 0 is the final velocity of the car

u = 24 m/s is the initial velocity

d is the length of the skid

Substituting, we find

[tex]d=\frac{v^2 -u^2}{2a}=\frac{0-(24 m/s)^2}{2(-7.84 m/s^2)}=36.7 m \sim 37 m[/tex]

a) Speed: It is the ratio of distance covered and time interval to cover that distance

it is given as [tex]speed = \frac{distance}{time}[/tex]

b) Direction: it will define for vector quantities and shows the required direction for it

c) Velocity : It is rate of change in position or it is ratio of displacement and time

d) Vector : it is a type of physical quantity which will be defined by magnitude and direction both

e) Position : it is defined as the distance with respect to a given reference or origin

f) Acceleration : it is defined by rate of change in velocity.

[tex]a = \frac{v_f - v_i}{\Delta t}[/tex]

g) Force = it is push or pull on an object which will create acceleration to the object

F = ma

it is product of mass and acceleration

h) Newton : it is SI unit of force or we measure force in this unit

Sometimes, because acceleration due to gravity on Earth depends on how close you are to the Earth's center.

The root-mean-square (rms) speed of nitrogen molecules in a given volume and pressure can be calculated using the formula V_rms = sqrt(3kBT/m), where V_rms is the rms speed, T is the temperature in kelvin, k is the Boltzmann constant, and m is the mass of a nitrogen molecule. To solve this problem, we first need to find the temperature using the ideal gas law equation PV = nRT. Once we have the temperature, we can substitute it into the rms speed equation to find the final answer in m/s.

The root-mean-square (rms) speed of nitrogen molecules in a given volume and pressure can be calculated using the formula:

Vrms = √( 3kBT/m ), where Vrms is the rms speed, T is the temperature in kelvin, k is the Boltzmann constant (1.38 × 10-23 J/K), and m is the mass of a nitrogen molecule.

In this case, we are given the volume (8.5 m3), pressure (3.5 atm), and total amount of nitrogen (1900 mol). To find the temperature, we need to use the ideal gas law equation: PV = nRT, where P is the pressure, V is the volume, n is the number of moles, R is the gas constant (0.0821 atm·L/mol·K), and T is the temperature.

Using the ideal gas law, we can solve for T:

T = PV/(nR)

Substituting the given values, T = (3.5 atm × 8.5 m3)/(1900 mol × 0.0821 atm·L/mol·K) = 16.573 K

Now we can calculate the rms speed:

Vrms = √( 3 × 1.38 × 10-23 J/K × 16.573 K / (28.0067 × 10-3 kg/mol) )

Calculating this expression will give us the rms speed of the nitrogen molecules in m/s.

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The rms speed of nitrogen molecules can be calculated using Boltzmann's constant, nitrogen's molar mass, and the given temperature in Kelvin. By substituting these values into the formula, we can compute the nitrogen molecules' speed.

The rms speed (root mean square speed) of nitrogen molecules can be calculated using the formula:

Vrms = sqrt(3kT/m')

where k stands for Boltzmann's constant, T is the temperature in Kelvin, and m' represents the molar mass of nitrogen (N₂) molecule. According to the periodic table, the molar mass of nitrogen N₂ is 2(14.0067)x10-3 kg/mol. Plugging in the values and doing the calculation should give you the rms speed of the nitrogen molecules.

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Answer:

5.7 m/s^2

Explanation:

First of all, we need to calculate the resultant force on the crate. We have:

- A force of +210 N in the positive direction

- The frictional force of -74 N in the opposite direction

So, the resultant force is

F = 210 N - 74 N= 136 N

So now we can apply Newton's second law to find the acceleration:

[tex]F=ma[/tex]

where m=24 kg is the mass of the crate. Re-arranging the equation, we get:

[tex]a=\frac{F}{m}=\frac{136 N}{24 kg}=5.7 m/s^2[/tex]

Answer:

7.3 kg m/s

Explanation:

First of all, let's calculate the gravitational potential energy of the stone as it reaches its highest point:

[tex]U=mgh=(0.28 kg)(9.8 m/s^2)(34.3 m)=94.1 J[/tex]

For the law of conservation of energy, this is equal to the initial kinetic energy of the stone at ground level (where the potential energy is zero), just after the stone leaves your hand:

[tex]K=\frac{1}{2}mv^2=94.1 J[/tex]

From this equation we can find the velocity of the stone as it leaves your hand:

[tex]v=\sqrt{\frac{2K}{m}}=\sqrt{\frac{2(94.1 J)}{0.28 kg}}=25.9 m/s[/tex]

The initial velocity of the stone (before leaving your hand) is zero:

[tex]u=0[/tex]

The impulse received by the stone is equal to its change in momentum, so:

[tex]I=\Delta p=m\Delta v=m(v-u)=(0.28 kg)(25.9 m/s-0)=7.3 kg m/s[/tex]

The magnitude of the impulse the stone received from your hand while being thrown is approximately 17.22 kg*m/s, calculated by considering the conversion of its gravitational potential energy into kinetic energy, and consequently finding the change in momentum.

Given the mass of the stone (m = 0.28 kg) and the height to which the stone rises (h = 34.3 m), the impulse can be calculated using the relationship between impulse, momentum, and energy.

Firstly, as we're considering a height and a resultant vertical motion, we can approach this in terms of gravitational potential energy for simplicity. The stone's kinetic energy is converted to gravitational potential energy at the highest point of its trajectory. So, the potential energy at peak is mgh, which is equal to 0.28 kg * 9.8 m/s^2 * 34.3 m = 93.0284 Joules.

Considering that the kinetic energy the stone started with (K=0.5mv^2) is equivalent to this potential energy (as no energy is lost, only converted), we can derive the initial velocity using v= sqrt(2*K/m).

Now, plug the knowns in to solve for velocity: v= sqrt((2*93.0284Joules)/0.28kg), which gets us v≈61.5 m/s. The magnitude of the impulse is given by the change in momentum, which in this case is the stone's momentum as it leaves the hand (because it starts at rest). So finally, the impulse is equal to the product of the mass of the object and the change in its velocity (Impulse = mv): Impulse = 0.28 kg * 61.5 m/s = approximately 17.22 kg*m/s (rounded).

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1) 29.8 C

At the beginning, the metal is at higher temperature (70.4 C) while the water is at lower temperature (23.6 C). When they are put in contact, the metal transfers heat to the water, until they reach thermal equilibrium: at thermal equilibrium the two objects (the metal and the water have same temperature). Therefore, since the temperature of the water at thermal equilibrium is 29.8 C, the final temperature of the metal must be the same (29.8 C).

2) 6.2 C

The temperature change of the water is given by the difference between its final temperature and its initial temperature:

[tex]\Delta T = T_f - T_i[/tex]

where

[tex]T_f = 29.8 C\\T_i = 23.6 C[/tex]

Substituting into the formula,

[tex]\Delta T=29.8 C-23.6 C=6.2 C[/tex]

And the positive sign means that the temperature of the water has increased.

3) -40.6 C

The temperature change of the metal is given by the difference between its final temperature and its initial temperature:

[tex]\Delta T = T_f - T_i[/tex]

where

[tex]T_f = 29.8 C\\T_i = 70.4 C[/tex]

Substituting into the formula,

[tex]\Delta T=29.8 C-70.4 C=-40.6 C[/tex]

And the negative sign means the temperature of the metal has decreased.

Answer:

29.8, 6.2, -40.6

Explanation:

refraction is the right answer

Answer: Refraction.

Explanation: The lenses are used to "transmit" the light that hits the lens in a certain way.

The phenomena in which the light penetrates a medium (where the medium, in this case, is the lens) is called diffraction.

Reflection would be more related to mirrors, difraction is the change of the velocity of the light waves when they are in different mediums, and interference refers to the interaction between two coherent waves (it can be destructive interference, where the waves cancel each other, or constructive interference, where the waves add to each other)

Thrust force due to ejection of water on the cart is counter balanced by spring force on the cart

so we can write

[tex]F_t = v \frac{dm}{dt}[/tex]

here we have

[tex]\frac{dm}{dt}[/tex] = rate of mass ejection

[tex]\frac{dm}{dt} = \rho a\frac{dx}{dt} = \rho a v[/tex]

now from above formula

[tex]F_t = \rho a v(v) = \rho av^2[/tex]

Now by force balance equation

[tex]F_t = F_s[/tex]

[tex]\rho a v^2 = kx[/tex]

by rearranging the terms now

[tex]v= \sqrt{\frac{kx}{\rho a}}[/tex]

Basically a distance multiplied by a weight that is equal to the distance that is going to be multiplied by the weight. (for the equation we will use X for the distance).

equation: 4 x1 20 = ? x 80

Now step one: 4(120) = X(80)  

Or another way is 480 = 80X  

480/80 = X  

48/8= X  

X = 6

I hope this could help! Sorry if it didn't make much sense otherwise!

n physics, the kinetic energy of an object is the energy that it possesses due to its motion. It is defined as the work needed to accelerate a body of a given mass from rest to its stated velocity. Having gained this energy during its acceleration, the body maintains this kinetic energy unless its speed changes.

Final answer:

A pendulum swinging back and forth is an example where the amounts of potential and kinetic energy change, but the total mechanical energy remains constant.

Explanation:

An example of a real-world scenario where the amount of potential and kinetic energy change, but the total amount of mechanical energy stays the same is when a pendulum swings back and forth. As the pendulum swings to its highest point, it has maximum potential energy and minimum kinetic energy. As it swings down, the potential energy decreases and the kinetic energy increases until it reaches its lowest point, where it has maximum kinetic energy and minimum potential energy. However, the total mechanical energy of the pendulum remains constant throughout its motion because there is no significant energy loss due to friction.