if a ball is thrown with a velocity of 25 m/s at an angle of 37 degrees above the horizontal,evaluate the projectile for it's horizontal component of the velocity​

Answer:

The ball rolled a distance of 54 m.

Explanation:

Given:

Initial velocity of the ball is, [tex]u=5\ m/s[/tex]

Final velocity of the ball is, [tex]v=7\ m/s[/tex]

Time for rolling is, [tex]t=9\ s[/tex]

The distance of rolling is, [tex]S=?[/tex]

First, let us find the acceleration of the ball using Newton's equation of motion as:

[tex]v=u+at\\a=\frac{v-u}{t}\\a=\frac{7-5}{9}=\frac{2}{9}\ m/s^2[/tex]

Now, displacement of the ball can be determined using the following equation of motion:

[tex]v^2=u^2+2aS[/tex]

Rewriting the above in terms of 'S', we get

[tex]S=\frac{v^2-u^2}{2a}[/tex]

Plug in the known values and solve for 'S'. This gives,

[tex]S=\frac{7^2-5^2}{2\times \frac{2}{9}}\\\\S=\frac{49-25}{\frac{4}{9}}\\\\S=\frac{9\times 24}{4}\\\\S=9\times 6=54\ m[/tex]

Therefore, the ball rolled a distance of 54 m.

The board is 2.50m high.

Why?

We can calculate how high was the board applying the Law of Conservation of Mechanical Energy. This Law states that the mechanical energy (kinematic and potential) will be conserved during the motion.

It can be described with the following formula:

[tex]E_{M_{1}}=E_{M_{2}}\\\\PE_{1}+KE_{1}=PE_{2}+KE_{2}[/tex]

[tex]PE=m*g*h\\KE=\frac{1}{2}m*v^{2}[/tex]

At the top of the boar, the kinetic energy is equal to 0.

At the water, the potential energy is equal to 0.

So,

[tex]PE_{1}=KE_{2}\\\\m*g*h=1450J\\\\59.3kg*9.8\frac{m}{s^{2}}*h=1450J\\ \\h=\frac{1450J}{59.3kg*9.8\frac{m}{s^{2}}}=2.50m[/tex]

Hence, we have that the board is 2.50m high.

Have a nice day!

The mass of the marble is 0.067 kg

Explanation:

The momentum of an object is given by the equation

[tex]p=mv[/tex]

where

p is the momentum

m is the mass

v is the velocity

For the marble in this problem, we have:

p = 0.10 kg m/s is its momentum

v = 1.5 m/s is its velocity

Solving the equation for m, we can find the mass of the marble:

[tex]m=\frac{p}{v}=\frac{0.10}{1.5}=0.067 kg[/tex]

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The mass of the marble is 0.067 kg.

To find the mass of the marble, we can use the formula for momentum (p), which is the product of mass (m) and velocity (v):

[tex]\[ p = m \times v \][/tex]

Given that the momentum (p) is 0.10 kg.m/s and the velocity (v) is 1.5 m/s, we can rearrange the formula to solve for the mass (m):

[tex]\[ m = \frac{p}{v} \][/tex]

Substituting the given values:

[tex]\[ m = \frac{0.10 \text{ kg.m/s}}{1.5 \text{ m/s}} \][/tex]

[tex]\[ m = \frac{0.10}{1.5} \][/tex]

[tex]\[ m \approx 0.0667 \text{ kg} \][/tex]

 Rounding to three decimal places, the mass of the marble is 0.067 kg.

Answer:

A steep slope on a displacement vs. time graph indicates a large velocity.

Explanation:

Gravitational potential energy is converted into kinetic energy

Explanation:

There are two forms of energy involved in the situation described in the problem:

In this problem, Sonja and the bike starts from the top of the hill and they ride downhill. As they go downhill, their altitude from the ground (h) decreases, so their gravitational potential energy decreases; at the same time, since the total energy is conserved (in absence of friction or air resistance), the speed of the bike and Sonja increases, and their kinetic energy increases. Therefore, there is a conversion of energy from gravitational potential to kinetic.

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Answer:

0.241

Explanation:

resolving weight into two components and calculating force of friction in terms of coefficient of friction and then applying Newton 's law we get the value .This all has been explained in attachment

Final answer:

To calculate the coefficient of friction for a box sliding down a ramp, we consider the forces acting on the box, including gravity, normal force, and friction. The frictional force equals the coefficient of friction times the normal force that comes out to be 0.24

Explanation:

To find the coefficient of friction for a 10 kg box accelerating down a ramp at 2 meters per second² at an angle of 25 degrees, we can use the following physics concepts. First, we identify the forces acting on the box: gravity, normal force, friction, and the resultant force causing the acceleration. We can calculate the component of the gravitational force parallel to the ramp (which is mg sin(25°)), and the normal force (which is mg cos(25°), where m is the mass of the box and g is the acceleration due to gravity).

The frictional force ([tex]F_{f}[/tex]) opposes the motion and can be expressed as [tex]F_{f}[/tex] = μN, where μ is the coefficient of static friction and N is the normal force. Since the box is accelerating, we set up Newton's second law of motion in the direction of the incline: [tex]F_{parallel}[/tex] - [tex]F_{f}[/tex] = ma, where a is the acceleration. Substituting the expressions for [tex]F_{parallel}[/tex], [tex]F_{f}[/tex], and N and solving for μ gives us the coefficient of friction.

Given: Mass (m) = 2 kg, Incline angle (θ) = 25°, Frictional force ([tex]F_{f}[/tex]) = 4.86 N . We get that by using the formula [tex]F_{f}[/tex] = μ * m * g * cos(θ), where g = 10 m/s² .

Now from[tex]F_{f}[/tex] = μN

Substitute the values to find μ = 0.24.

Answer:

Option A

A model

Explanation:

Modelling is the process where the designer simulate elements that resemble the actual product and put on a scale that the computers can easily simulate and then the simulations are related directly to the actual product. The use of computer simulations to help solve problems is known as modelling since it uses a model.

Final answer:

The use of computer simulations in engineering, such as for bridge design, is characterized as a model. These simulation models are used for testing hypotheses and making predictions, acting as pivotal tools in design and decision-making processes.

Explanation:

The use of computer simulations, such as the ones employed in designing the Millennium Bridge in London, is best described as a model. These simulation models use numerical techniques to visualize and analyze complex relationships and scenarios in various designs and systems. They are built around hypotheses and can be used to test these hypotheses, as well as to make predictions about the system under study. Moreover, simulations are a substitute for experimentation and the results should be verified through experimentation or observational data.

Computer models, which have been verified against data, are incredibly useful in aiding decision-making processes, including those in engineering. For instance, they help in modeling high-altitude winds for planning airliner flight paths or storm paths for emergency procedures, as well as designing solutions to reduce friction or drag, such as in making cars more fuel-efficient. Therefore, a computer simulation in engineering functions both as a predictive tool and a virtual experiment.

Answer:

Cementation---precipitation of bonding agents between grains.

Recrystallization---contact pressure causing grains to "fuse" together.

Compaction---increase in density due to weight of overburden.

Explanation:

I hope this helps you! Good luck and have a great day. ❤️✨

The net force is 6 N East

Explanation:

First of all, we start by noticing that all the forces act along the direction East-West, so we can simply find the net force by using algebraic addition.

In order to find the net force on the wheelchair, we need to define a positive direction and write down all the force with the proper sign.

Let's choose East as positive direction. Therefore, we have the following forces:

[tex]F_1 = +10 N[/tex] (east), the force applied by Ms. PB

[tex]F_2 = +5 N[/tex] (east), the force applied by Mr. Rigney

[tex]F_f = -2 N[/tex] (west), the frictional force, acting in the opposite direction

[tex]F_r = -7 N[/tex] (west), the air resistance, acting in the opposite direction

Taking into account the correct signs, we can now find the net force on the wheelchair:

[tex]F=F_1+F_2+F_f+F_r = +10 + 5 +(-2) + (-7) = +6 N[/tex]

And the positive sign tells us that the direction of the net force is East.

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the mass of 1cm3 of mercury is 13.6g because

the formula of density is mass/volume and when paste the number in it. you get the answer

746 joules per second = 746 watts = 1 horsepower

340 joules per second = 340 watts = (340/746) = 0.456 horsepower

Power is a RATE or a SPEED of doing work.  

How long you do it doesn't matter.  

Just like 30 miles per hour doesn't change whether you do it for an hour or for 10 minutes.

If one horsepower is equal to 746 watts, and a highly trained athlete generate by doing 340 joules of work per second for an hour is 0.456 horsepower.

This measure unit can measure "work" or "force". In the SI correspond to move up 75 Kg, to 1 meter high,  in one second.

1 HP = (330 lb) x (100 feet)/1min = 33000 lb x feet/min

Is a practical unit, because reduce the amount of digits in a specific value. Also, it is more used specially in mechanical applications.

1 HP= 746 W (0,746 kW)

746 joules per second = 746 watts = 1 horsepower

340 joules per second = 340 watts = (340/746) = 0.456 horsepower

Thus, For a trained athlete, the value is 0.456 horsepower.

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Answer:

According the law of conservation of mass, the mass of  the reactant should be equal to the products in an chemical reaction. so we go far balancing the chemical reactions.

1)    [tex]S +O_2 \rightarrow SO_2[/tex]

2)   [tex]2Na + O_2 \rightarrow Na_2O_2[/tex]

3)   [tex]2Hg + O_2 \rightarrow 2HgO[/tex]

4)   [tex]2Ag_2O \rightarrow 4Ag + O_2[/tex]

5)   [tex]Ba(OH)_2 + H_3PO_4 \rightarrow BaHPO_4+ 2H_2O[/tex]

6)   [tex]2NaOH + H_3PO_4 \rightarrow Na_2HPO_4 +2H_2O[/tex]

7)   [tex]C_4H_8 + 6O_2\rightarrow 4CO_2+4H_2O[/tex]

8)   [tex]C_3H_8 + 5O_2\rightarrow3CO_2+4H_2O[/tex]

9)   [tex]2Fe + 3Cl_2\rightarrow 2FeCl_3[/tex]

10)  [tex]2Al+6HCl \rightarrow2 AlCl_3 +3H_2[/tex]

11)   [tex]2H_2 +O_2 \rightarrow 2H_2O[/tex]

12)   [tex]N_2 + 3H_2 \rightarrow 2NH_3[/tex]

The question relates to the presence of isotopes 12C and 14C in living organisms and how the half-life of 14C is used for radiometric or carbon-14 dating. After an organism's death, its ratio of 14C to 12C decreases, and this shift can be compared to ratios in currently living organisms to estimate the age of the object. The accuracy of this method can somewhat be affected by human activities, so corrections are applied.

In living organisms, a small fraction, which is 1.30 × 10-12, of 12C is comprised of the radioactive isotope 14C. The half-life of 14C is 5730 years, meaning after around 5730 years, half of the starting concentration of 14C will decay to 14N. This property makes it useful in aging formerly living objects, a process known as radiometric dating or carbon-14 dating.

When an organism dies, its 14C is no longer replenished so the ratio of 14C to 12C begins to decrease. By comparing this ratio to the ratio in living organisms, the amount of 14C that has not decayed can be determined, which enables the calculation of the age of the object to about 50,000 years.

The ratio in the atmosphere, and hence in living organisms, is slightly altered due to human activities such as the burning of fossil fuels. Corrections based on other data sources, including tree ring dating, are used to correct the current 14C/12C ratio to that from the past era when the organism was alive.

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Answer:90×55=4950km

Explanation:d=s×t

Answer:

4950 miles

Explanation:

Answer:

20 meters.

Explanation:

mgh = 1/2mv^2

gh = 1/2v^2

10(h) = 1/2(20)^2

10h = 1/2(400)

10h = 200

(10h)/10 = 200/10

h = 20

Answer:

20 meters

Explanation:

Answer:

B. chemical only.

Explanation:

In the process of respiration which is a chemical process where organic compound is released. In this process exergonic reaction takes place in which compound changes into different ones.

Following are the two types of respiration:-

1] Aerobic respiration:- In this type of respiration requirement of oxygen is more and energy released is more.

2] Anaerobic respiration:- In this type of respiration oxygen requirement is less and energy released is also less.

Final answer:

A low melting point is not a common property of ionic compounds; they are characterized by high melting points, being hard and brittle, and conducting electricity when molten but not as a solid.

Explanation:

The property that is not common to ionic compounds is having a low melting point. Ionic compounds are known for their distinctive characteristics, which include being hard, brittle, and capable of conducting electricity as a liquid but not as a solid.

They typically have high melting points and high boiling points. When they are solid, the ionic compounds have ions that are held in place and cannot move, which means they do not conduct electricity. However, when these compounds are in a molten state (liquid), the ions can move freely, and this allows the compound to conduct electricity.

Answer:

3.57 units

Explanation:

[tex]x =\sqrt{ (-1.55)^2+(3.22)^2} = 3.57 units[/tex]

Answer:

The magnitude of the vector is 3.57 units.

Explanation:

The x component of the vector, [tex]v_x=-1.55\ \text{units}[/tex]

The y component of the vector is [tex]v_y=3.22\ \text{units}[/tex]

We need to find the magnitude of the vector. We know that the magnitude of the vector is given by :

[tex]v=\sqrt{v_x^2+v_y^2}[/tex]

[tex]v=\sqrt{(-1.55)^2+(3.22)^2}[/tex]

[tex]v=3.57\ \text{units}[/tex]

So, the magnitude of the vector is 3.57 units. Hence, this is the required solution.

(i) Doubling the mass of one object doubles the gravitational force.

(ii) Doubling the distance reduces the force to one-fourth; tripling reduces it to one-ninth.

(iii) Doubling both masses quadruples the force.

Let's analyze each scenario:

(i) If the mass of one object is doubled:

According to Newton's law of universal gravitation, the gravitational force (F) between two objects is directly proportional to the product of their masses (m1 and m2) and inversely proportional to the square of the distance (r) between their centers:

[tex]\[ F = G \frac{m1 \cdot m2}{r^2} \][/tex]

where G is the gravitational constant.

If we double the mass of one object (let's say m1), the force becomes:

[tex]\[ F' = G \frac{2m1 \cdot m2}{r^2} \][/tex]

Comparing F' with F, we see that F' is doubled. Therefore, doubling the mass of one object doubles the gravitational force between them.

(ii) If the distance between the objects is doubled and tripled:

Let's denote the original distance between the objects as r.

- If the distance is doubled (2r), the force becomes:

[tex]\[ F' = G \frac{m1 \cdot m2}{(2r)^2} = \frac{1}{4} \cdot \frac{G \cdot m1 \cdot m2}{r^2} \][/tex]

Comparing F' with F, we see that F' is one-fourth of the original force. Therefore, doubling the distance reduces the gravitational force to one-fourth of its original value.

- If the distance is tripled (3r), the force becomes:

[tex]\[ F' = G \frac{m1 \cdot m2}{(3r)^2} = \frac{1}{9} \cdot \frac{G \cdot m1 \cdot m2}{r^2} \][/tex]

Comparing F' with F, we see that F' is one-ninth of the original force. Therefore, tripling the distance reduces the gravitational force to one-ninth of its original value.

(iii) If the masses of both objects are doubled:

If we double the masses of both objects (m1 and m2), the force becomes:

[tex]\[ F' = G \frac{2m1 \cdot 2m2}{r^2} = 4 \cdot \frac{G \cdot m1 \cdot m2}{r^2} \][/tex]

Comparing F' with F, we see that F' is quadrupled. Therefore, doubling the masses of both objects quadruples the gravitational force between them.

The Correct question is:

What happens to the gravitational force between two objects, if

(i) the mass of one object is doubled?

(ii) the distance between the objects is doubled and tripled?

(iii) the masses of both objects are doubled? give ans with indetail calculation

Answer:

Decreases

Explanation:

Ideal gas law:

PV = nRT

where P is absolute pressure,

V is volume,

n is number of moles,

R is gas constant,

and T is absolute temperature.

If V is constant and T decreases, then P must decrease.

In accordance with Boyle's Law, if the volume of a scuba tank remains constant and its temperature decreases, then the pressure of the air within the tank would increase. This principle is applied in underwater activities to ensure safe ascension and descension by divers.

The scenario you're describing falls under the principles of Boyle's law in physics, which applies to scenarios where gases are held at a constant volume. Boyle's law states that the pressure and temperature of a gas have an inverse relationship when held at a constant volume. If we apply this to your question, it implies that if the volume of air in the scuba tank remains constant and its temperature decreases, the pressure within the tank would increase.

For instance, if divers descend into the deep waters, the increase in water pressure compresses the air pocket within the scuba tank, and this increase in pressure subsequently raises the tank's temperature. A reverse scenario will occur during ascent. As divers begin to ascend and water pressure reduces, the air pocket within the scuba tank expands, resulting in a decrease in pressure, subsequently causing the tank's temperature to decrease as well.

The relationship between temperature, volume, and pressure is crucial in subaquatic activities to prevent potential mishaps like ruptured lungs or eardrums due to rapid pressure change.

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Explanation:

Force=Mass*acceleration or F=MA. To find acceleration can be rewritten as A=F/M. If you input the numbers ypu can rewrite as A= 10N/5kg, A=2

The acceleration is 2 meters per sec.

Before the collision, the total momentum of the system is the sum of the momentum of the truck and the car. After the collision, the truck and the car move together with a final velocity of 0.8 m/s.

Before the collision, the total momentum of the system is the sum of the momentum of the truck and the car:

Total momentum before = (mass of truck × velocity of truck) + (mass of car × velocity of car)

Total momentum before = (4800 kg × 4.0 m/s) + (1200 kg × -12 m/s)

Total momentum before = 19200 kg·m/s - 14400 kg·m/s = 4800 kg·m/s

After the collision, the truck and the car move together. They have the same final velocity. To find this velocity, we can use the principle of conservation of momentum:

Total momentum after = (mass of the combined system × final velocity)

4800 kg·m/s = (6000 kg × final velocity)

Final velocity = 4800 kg·m/s / 6000 kg = 0.8 m/s

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The final velocity is (4800 kg ×7 m/s) ×7 (6000 kg) = 0.8 m/s.

The subject question is concerned with momentum conservation in a collision between a truck and a car, a fundamental concept in physics. To fill in the before-and-after collision table, we calculate the initial momentum of each vehicle and use conservation of momentum to find the final velocity of the entangled masses.

The initial momentum of the truck is the product of its mass and velocity, which is (4800 kg) ×(4.0 m/s) = 19200 kg ×7 m/s directed 'positive'. For the car, it is (1200 kg)  ×(-12 m/s) = -14400 kg ×7 m/s directed 'negative'. The total initial momentum of the system is the sum of the individual momenta: 19200 kg ×7 m/s - 14400 kg ×7 m/s = 4800 kg ×7 m/s.

After the collision, since the truck and car move together, we must find their combined mass and solve for the final velocity using the equation: (Total Initial Momentum) = (Total Mass) ×(Final Velocity). The total mass is (4800 kg + 1200 kg) = 6000 kg.

Answer:

[tex]t=12.25\ seconds[/tex]

Explanation:

Diagonal Launch

It's referred to as a situation where an object is thrown in free air forming an angle with the horizontal. The object then describes a known path called a parabola, where there are x and y components of the speed, displacement, and acceleration.

The object will eventually reach its maximum height (apex) and then it will return to the height from which it was launched. The equation for the height at any time t is

[tex]x=v_ocos\theta t[/tex]

[tex]\displaystyle y=y_o+v_osin\theta \ t-\frac{gt^2}{2}[/tex]

Where vo is the magnitude of the initial velocity, [tex]\theta[/tex] is the angle, t is the time and g is the acceleration of gravity

The maximum height the object can reach can be computed as

[tex]\displaystyle t=\frac{v_osin\theta}{g}[/tex]

There are two times where the value of y is [tex]y_o[/tex] when t=0 (at launching time) and when it goes back to the same level. We need to find that time t by making [tex]y=y_o[/tex]

[tex]\displaystyle y_o=y_o+v_osin\theta\ t-\frac{gt^2}{2}[/tex]

Removing [tex]y_o[/tex] and dividing by t (t different of zero)

[tex]\displaystyle 0=v_osin\theta-\frac{gt}{2}[/tex]

Then we find the total flight as

[tex]\displaystyle t=\frac{2v_osin\theta}{g}[/tex]

We can easily note the total time (hang time) is twice the maximum (apex) time, so the required time is

[tex]\boxed{t=24.5/2=12.25\ seconds}[/tex]

Answer:

the ray is reflected infinite number of times by 2 plane mirrors placed parallel to each other as each reflected ray would be the incident ray for the other.

Explanation:

the ray is reflected infinite number of times by 2 plane mirrors placed parallel to each other as each reflected ray would be the incident ray for the other.

Placing one mirror at an angle causes reflections to curve.

Two parallel plane mirrors result in an infinite number of reflections for a light ray due to the Law of Reflection.

When two plane mirrors are placed parallel and facing each other, a light ray entering this setup will undergo multiple reflections between the mirrors. The number of reflections theoretically can be infinite, as each reflection leads to another unless the mirrors are not perfectly aligned or have imperfections. This principle is based on the Law of Reflection, which states that the angle of incidence is equal to the angle of reflection.

Here's a step-by-step explanation:

This phenomenon can be commonly observed in simple experiments using two parallel mirrors, creating the effect of an infinite tunnel of reflections.

Answer:

(a) [tex]R_5=9\ \Omega[/tex]

(b) Potential Difference = 11.584 V

(c) [tex]R_1=0.40\ \Omega[/tex]

Explanation:

Given:

[tex]\textrm{Current in A₁,}I_1=0.4\ A\\\textrm{Current in A₂,}I_2=0.64\ A\\R_2=5.6\ \Omega\\R_3=6.2\ \Omega\\R_4=8.2\ \Omega\\\textrm{EMF of the battery,}E= 12 V[/tex]

(a)

The resistances [tex]R_3\ and\ R_4[/tex] are in series. So, equivalent resistance is the sum of the two.

[tex]R_s=R_3+R_4=8.2+6.2=14.4\ \Omega[/tex]

Now, [tex]R_s\ and\ R_5[/tex] are in parallel. So, potential difference across both the terminals is same. Therefore,

[tex]I_1R_s=I_2R_5\\\\R_5=\frac{I_1}{I_2}R_s\\\\R_5=\frac{0.4}{0.64}\times 14.4=9\ \Omega[/tex]

(c)

Now, since the resistances are in parallel, the equivalent resistance is given as:

[tex]\frac{1}{R_p}=\frac{1}{R_s}+\frac{1}{R_5}\\\\R_p=\frac{R_s\times R_5}{R_s+R_5}\\\\R_p=\frac{14.4\times 9}{14.4+9}\\\\R_p=\frac{129.6}{23.4}=5.54\ \Omega[/tex]

Now, resistances [tex]R_1,R_2\ and\ R_p[/tex] are in series. Therefore, equivalent resistance is given as:

[tex]R_{eq}=R_1+R_2+R_p\\R_{eq}=R_1+5.6+5.54\\R_{eq}=R_1+11.14-----1[/tex]

Now, from Ohm's law, we know that,

[tex]E=(I_1+I_2)R_{eq}\\\\R_{eq}=\frac{E}{I_1+I_2}\\\\R_{eq}=\frac{12}{0.4+0.64}\\\\R_{eq}=11.54\ \Omega[/tex]

Plug in [tex]R_{eq}[/tex] value in equation (1). This gives,

[tex]11.54=R_1+11.14\\R_1=11.54-11.14=0.40\ \Omega[/tex]

(b)

Now, potential difference across the terminals of the battery is given as:

[tex]V=E-(I_1+I_2)R_1\\V=12-(0.4+0.64)0.4\\V=12-0.416=11.584\ V[/tex]

Answer:

51.25 mph

Explanation:

[tex]Speed=\frac {Distance}{Time}[/tex]

Total distance= 100 miles + 30 miles + 75 miles=205 miles

Total time=2 hours+1 hour+1 hour= 4 hours

Average speed, [tex]s=\frac {205 m}{4 h}=51.25 mph[/tex]

The answer is 51

Explanation: Edg2020

D. the rate at which a person slides down a rope.

This indicates speed because the person is timing people on how fast they will slide down a rope.

Answer:

Decreases

Explanation:

Answer:

B. Decreases

Explanation:

According to differential reinforcement theory, one of the social learning theories, when behaviors are rewarded with the certain positive actions or positive outcomes then it is called positive enforcement. Positive enforcement increases the criminal actions. On the other hand, negative enforcement increases the actions which reduce the criminal activities.  

According to theory explained above Studies have shown that viewing violent actions in the media decreases the inhibition against performing those actions when behavior is rewarded with the positive enforcement.

Answer:

10.0 J

Explanation:

The work done equals the change in energy.  Since there's no friction, and the table is horizontal, the only change in energy is kinetic.

The total kinetic energy gained by the object of  20 Newton weight is 10.0 joules.

According to the law of conservation of energy, energy cannot be created or destroyed. It can, however, be transformed from one form to another. When all forms of energy are considered, the total energy of an isolated system remains constant. The law of energy conservation applies to all forms of energy.

In summary, the law of energy conservation states that the total energy of a closed system, that is, a system that is isolated from its surroundings, is conserved.

Total work done on the object is 10.0 joules.

Weight if the object = 20 Newton.

Hence, total kinetic energy gained by the object = Total work done on the object

= 10.0 joules.

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Answer:

1) Current decreases; 2) Inverse proportionally; 3) 1[A]

Explanation:

1)

As we can see as the resistance increases the current decreases, if we take two points as an example, when the resistance is equal to 50 [ohms] the current is equal to 1[amp] and when the resistance is equal to 200 [ohms] the current tends to have a value below 0.5 [amp]. Thus demonstrating the decrease in current.

2)

Inverse proportionally, by definition we know that the law of ohm determines the voltage according to resistance and amperage. This is the voltage will be equal to the product of the voltage by the resistance.

[tex]V=I*R\\V = voltage [volts]\\I = current[amp]\\R = resistance [ohms][/tex]

where:

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

And whenever we have in a fractional number the denominator the variable we are interested in, we can say that this is inversely proportional to the value we are interested in determining. In this case, we can see from the two previous expressions that both the current and the resistance appear in the denominator, therefore they are inversely proportional to each other.

3)

If we place ourselves on the graph on the resistance axis, we see that at 50 [ohm] will correspond a current value equal to 1 [A].

Answer:

1. A. decrease

2. C. Inverse proportionally

3. B. 1 A

Explanation: