Glass is a _____ conductor of heat.

If an object has a mass of 20 grams   its density in g/cm3 is [tex]0.5 g/cm^3[/tex]

The measure of how closely a material is packed together is called its density. The mass per unit volume is how it is defined. Density Formula: ρ = m/V, where ρ is the density, m is the object's mass, and V is its volume. Density Symbol:

[tex]density = \frac{mass}{volume}[/tex]

[tex]Density = \frac{20}{40}[/tex]

=[tex]0.5 g/cm^3[/tex]

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Final answer:

The resulting acceleration of the soccer ball after being kicked in opposite directions by two players is 5 m/s^2, calculated using Newton's Second Law of Motion.

Explanation:

When two soccer players kick the same 2-kg ball in opposite directions with different forces, we calculate the resulting acceleration of the soccer ball by applying Newton's Second Law of Motion, which states that the net force acting on an object is equal to the mass of the object multiplied by its acceleration (F = ma).

In this scenario, one player kicks with a force of 15 N while the other kicks with a force of 5 N in the opposite direction. The net force on the ball is the difference between these two forces because they are applied in opposite directions. Therefore, the net force (Fnet) is:

Fnet = 15 N - 5 N = 10 N

To find the acceleration (a), we rearrange Newton's Second Law to solve for 'a':

a = Fnet / m

Substituting the values, we get:

a = 10 N / 2 kg = 5 m/s2

Answer : Velocity of the wave, v = 1500 m/s.

Explanation :

It is given that,

Wavelength of a wave,  [tex]\lambda=9\ m[/tex]

Time period of wave, [tex]T=0.006\ s[/tex]

We know that the relation between the velocity, the frequency and the wavelength is given by :

[tex]v=\nu\times \lambda[/tex]

[tex]\because\ \nu=\dfrac{1}{T}[/tex]

[tex]v=\dfrac{\lambda}{T}[/tex]

[tex]v=\dfrac{9\ m}{0.006\ s}[/tex]

[tex]v=1500\ m/s[/tex]

Hence, this is the required solution.

Answer:

The speed of the ball one second later is 19.8 m/s.

Explanation:

Given that,

Initial speed of the ball, u = 10 m/s

Let v is the speed of the ball after one second. The ball will move downward under the action of gravity, a = g

Using the first equation of motion as :

[tex]v=u+at[/tex]

[tex]v=u+gt[/tex]

[tex]v=10+9.8\times 1[/tex]

v = 19.8 m/s

So, the speed of the ball one second later is 19.8 m/s. Hence, this is the required solution.

Adoptive optics, in which it’s a lot easier for a computer to constantly monitor and change the shape of multiple thin mirrors than it is to use a telescope with a large thick mirror that has to thermally adjust before being able to focus sharply and even then a large mirror or lens cannot compensate for air turbulence the way telescope with computer controlled adaptive optics can.  

Answer:

Electromagnetic forces are stronger than gravitational forces.

Explanation:

Electromagnetic and gravitational forces both are fundamental forces present in nature. The force that exists between the charged particles are electromagnetic forces while the force that exists between two objects in the universe is called gravitational force.      

The one of the difference between these two forces is that the gravitational force is always attractive while the electromagnetic force can be attractive or repulsive.  

Electromagnetic forces are stronger than gravitational forces. It is approximate 10³⁹ times stronger than gravitational force. Hence, the correct option is (b).

Final answer:

Granite is a silica-rich igneous rock with large crystals, playing a significant role in the composition of the continental crust due to its quartz and feldspar content. It is less dense than the oceanic crust, contributing to the elevation of continental crust.

Explanation:

A silica-rich igneous rock that has large crystals and makes up much of the continental crust is granite. Granite is a coarse-grained, felsic, intrusive rock, characterized by the presence of quartz, which indicates its silica-rich nature. Additionally, granite commonly contains large amounts of salmon pink potassium feldspar and white plagioclase crystals visible cleavage planes, making it a good approximation of the continental crust in terms of density and composition.

The composition of continental crust largely consists of various types of igneous, metamorphic, and sedimentary rocks, with granite playing a significant role due to its less dense characteristics compared to the mafic rocks of the oceanic crust. This relatively low density contributes to the continental crust rising higher on the mantle compared to the oceanic crust. Furthermore, quartz and feldspar, significant components of granite, are the two most abundant minerals in the continental crust, emphasizing granite's fundamental role in the structure of the Earth's crust.

To find the radius of the cylinder that produces the minimum surface area, combine the volume equations and isolate for the radius. Then, use calculus to find the minimum point for the surface area. Round the resulting value to three decimal places.

The subject of this mathematical problem involves the principles of calculus and geometry. The volume of the entire solid is the sum of the volume of the two hemispheres and the volume of the cylinder. Given that the total volume of the solid is 2 cm³, we know that the volume of the cylinder plus two times the volume of one hemisphere is equal to 2 cm³.

By expressing volume in terms of the radius, we can find that the radius equals the cube root of the volume divided by π (since the volume of a sphere is 4/3πr³ and the volume of a cylinder is πr²h, while considering the height of the cylinder equal to the diameter of the hemisphere). The surface area of the solid is the sum of the surface area of the two hemispheres and the surface area of the cylinder without tops (since those are covered by the hemispheres). To minimize the surface area, we need to use calculus, specifically the principles of differentiation and setting the derivative equal to zero to find a minimum. Once calculated, you can round the radius to three decimal places.

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To calculate the force exerted on a crate, divide the work done (40 J) by the distance moved (4 m) to get 10 N.

You have asked how much force is required to push a crate across a floor if it takes about 40 joules (J) to push the crate 4 meters (m). The force can be calculated using the work-energy principle, where the work done on an object is equal to the force applied times the distance over which the force is applied, assuming the force is constant and in the direction of motion. In formula terms, this is expressed as Work (W) = Force (F) × Distance (d).

To find the force, we rearrange the formula for work to solve for F: F = W/d. Substituting the given values, we have F = 40 J/4 m. Therefore, the force exerted on the crate is 10 Newtons (N).

Answer:

d. the electrons in some metals pair up to create a magnetic field.

Explanation:

Magnetism is the property of attraction and repulsion of certain metals and magnets, which have a positive and a negative pole, characterized by “dipole forces”. When magnetism occurs the electrons in some metals come together to create a magnetic field. The Magnetic Field, in turn, is the concentration of magnetism that is created around a magnetic charge in a given space.

It is the electrons of metals that create the magnetic field, just as it is the electric charge and mass that respectively create the electric and gravitational fields.

Solar time and sidereal time are two different ways to understand time. Solar time is based on the position of the Sun in the sky and changes throughout the day, while sidereal time is based on the rotation of the Earth relative to the stars and remains constant. Examples of solar time include a sundial, while examples of sidereal time include a telescope tracking the motion of a star.

There are two different ways to understand time: solar time and sidereal time. Solar time is based on the position of the Sun in the sky and is used to determine the time of day. Sidereal time is based on the rotation of the Earth relative to the stars and is used to track the Earth's motion through space. An example of solar time is the time displayed on a sundial, which changes as the Sun moves across the sky. An example of sidereal time is the time displayed on a telescope tracking the motion of a star, which remains constant as the Earth rotates.

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Answer:

The books slide to the left due to inertia, and then they come to a rest due to the force applied by the car door.

Explanation:

The entire motion of the books can be explained by using the first two laws of Newton:

- 1st Newton's law (also called Law of Inertia): an object at rest stays at rest and an object in motion stays in motion with constant velocity if no unbalanced forces act on it

- 2nd Newton's law: when an object is acted upon unbalanced forces, an acceleration is induced in the motion of the object, according to the equation

[tex]F=ma[/tex]

where F is the net force on the object, m is its mass and a is its acceleration.

Coming back to our problem:

- At the beginning, Argelia makes a sharp turn right. Due to the law of inertia, the books (which are not fixed to the car) continue their motion straight as it was before the curve: so, since the car is moving right, they appear to go the left of the car.

- When the books hit the car door, they stop moving due to the 2nd Newton's law: in fact, the car door applies an unbalanced force against the books, and as a result the books have a negative acceleration (=deceleration), so they slow down and eventually they stop.

The books moved due to the force that was applied and they came to rest due to inertia.

Inertia simply means the tendency to do nothing or to be able to remain unchanged. It is the resistance of any object to any change in the velocity of the object.

The books moved due to the force that was applied and they came to rest due to inertia. The book will be at rest as long as there's no force that acted on them.

In this case, the sharp turn of the car resulted in a force that acted on the car.

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The kinetic energy of the bowling ball is 100.81 J.

Given data:

The mass of bowling ball is, m = 7.26 kg.

The time interval is, t = 3.64 s.

The length of path covered is, L = 19.2 m.

First obtain the speed of ball from the given equation,

[tex]v = \dfrac{L}{t}[/tex]

Here, v is the speed of ball.

Solving as,

[tex]v = \dfrac{19.2}{3.64}\\\\v=5.27 \;\rm m/s[/tex]

Now, the expression for the kinetic energy is,

[tex]KE = \dfrac{1}{2}mv^{2}[/tex]

Solve by substituting the values as,

[tex]KE = \dfrac{1}{2} \times 7.26 \times 5.27^{2}\\\\KE=100.81 \;\rm J[/tex]

Thus, we can conclude that the kinetic energy of the bowling ball is 100.81 J.

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The kinetic energy of the bowling ball is approximately 100.81 Joules, which is calculated using the mass of the ball, the distance it covers, and the time it takes to cover that distance with constant velocity.

The student is asking for the kinetic energy of a bowling ball that has a given mass and travels a certain distance in a specified time with constant velocity. To solve this, we must first calculate the velocity of the ball using distance and time, then use this velocity to determine the kinetic energy.

Step 1: Calculate the velocity.
Velocity (v) = Distance (d) / Time (t)
v = 19.2 m / 3.64 s

v = 5.27 m/s

Step 2: Calculate the kinetic energy (KE). The formula for KE is

[tex]KE = \frac{1}{2} X m X v^2\\KE = \frac{1}{2} X 7.26 \ kg X (5.27 \ m/s)^2\\KE = 100.81 \ Joules[/tex]

Therefore, the kinetic energy of the bowling ball is approximately 100.81 Joules.

Answer:

a) into the direction of the skid

Explanation:

Final answer:

The stability of the atmosphere is determined using various measurements such as temperature and pressure data, weather station and satellite observations, and analyses of natural records like tree rings and ice cores.

Explanation:

To determine the stability of the atmosphere, scientists and meteorologists use various measurements. These include temperature and pressure gradients, the analysis of weather station data, and satellite observations. For instance, observations from mountain summits can provide vital data above the main body of our atmosphere, while meteorological observations of meteors can offer insights into the height of Earth's atmosphere. Additionally, indicators like the annual rings in trees and ice core analysis can predict long-term atmospheric changes, such as Earth's temperature trends. CO₂ concentrations measured from ice traps and deuterium analysis also reveal historical climate data, informing about past atmospheric stability. Furthermore, the Gravity Recovery and Climate Experiment (GRACE) by NASA enables scientists to measure mass changes in Earth's water resources which is critical for understanding climatic and atmospheric variations.

I think the answer is 5cm

the answer is positive mindset : )

The correct choice is

D. 22 Hz and 42 Hz.

In fact, the beat frequency is given by the difference between the frequencies of the two waves:

[tex] f_B = |f_1 -f_2| [/tex]

In this problem, the beat frequency is [tex] f_B=20 Hz [/tex], therefore the only pair of frequencies that gives a difference equal to 20 Hz is

D. 22 Hz and 42 Hz.