The distance "d" you bike varies directly with the amount of time "t" you bike. Suppose you bike 13.2 miles in 1.25 hours. What is an equation that relates "d" and "t"? What is the graph of the equation? ...?

Answer:

0.8087 C J/g oC

Explanation:

4786 J = 89.0 g x C x (89.5 C- 23.0 C)  

4786 J = 6185.5 gC

0.8087 C J/g oC

0.809 C J/g C (sig figs)

Final answer:

The specific heat of the unknown material, given the provided values, is calculated to be approximately 0.80 J/g°C.

Explanation:

To calculate the specific heat of the unknown material, we use the formula q = mcΔT, where q is the heat absorbed or released (in joules), m is the mass of the substance (in grams), c is the specific heat capacity (in Joules per gram per degree Celsius), and ΔT is the change in temperature (in degrees Celsius).

In this question, q = 4786 joules, m = 89.0 grams, and ΔT (change in temperature) = 89.5°C - 23.0°C = 66.5°C. Plugging in these values, we get 4786 = 89.0 * c * 66.5. Solving for c, we find that c = 4786 / (89.0 * 66.5).

After calculating, the specific heat of the material is found to be approximately 0.80 J/g°C.

Answer: electronegativity

Explanation: a covalent bond is a chemical bond. Electronegativity: an atom’s ability to attract shared electrons in a chemical bond (covalent bond is a chem bond).

The advantage of using a lever is that it reduces the input force required to lift a heavy object and can alter the direction of the force to be more convenient for the user. Option B is correct.

The advantage of using a lever in lifting heavy objects over lifting them directly is that it reduces the input force required to lift the object. A lever does this by changing the point where the force is applied and by increasing the distance over which this force is applied, making the work of lifting an object easier than lifting it directly. This principle of mechanics falls under the category of simple machines, which are devices that change the direction or magnitude of a force.

In the context of the multiple-choice question provided, the correct answer is : reduces the input force as well as alters the force in a convenient direction. This option accurately reflects the action of a lever—reducing the effort needed to lift a weight (input force) and changing the direction in which the force is applied to be more convenient for the user.

Answer:

Option (C)

Explanation:

The obstruction offered by the conductor in the path of flow of electrons is called the resistance of the conductor.

The reistance of the conductor is directly proportional to the length of the conductor and inversely proportional to the area of crossection of the conductor.

To minimize the resistance we need a wire of short length and more crossection area.

So, wire should be short and thick.

Took a wild guess and got it correct. The answer is B Kinetic Energy increases and potential energy decreases.

The changes in kinetic and potential energy in a roller coaster from point A to point B on a frictionless track represent a conversion of potential energy into kinetic energy, with the total mechanical energy remaining constant.

As a roller coaster begins its journey from point A (at rest and at maximum height) to point B, it experiences a transformation of energy. Initially, at point A, the coaster has a maximum amount of gravitational potential energy (PE) because it is at its highest point. As the coaster moves to point B on the frictionless track, this potential energy is converted into kinetic energy (KE).

The law of conservation of energy states that the total mechanical energy in the system remains constant if we ignore losses due to friction. In this frictionless scenario, as the potential energy decreases while the coaster descends, the kinetic energy increases proportionally. By the time the coaster reaches point B, which is at a lower height, much of its original potential energy has been transformed into kinetic energy, giving it its highest speed.

Thus, the changes in kinetic and potential energy as the roller coaster travels from point A to point B can be described as a transfer where potential energy is converted into kinetic energy, and the total mechanical energy of the coaster remains constant.

Answer:

false

Explanation:

Final answer:

All simple machines are variations of the inclined plane or the lever, with examples like the wedge and the wheel and axle. They provide a mechanical advantage by multiplying the force applied. Complex machines, like bicycles, integrate multiple simple machines to increase efficiency.

Explanation:

All simple machines are variations of either the inclined plane or the lever. Two specific examples are the wedge, which is a simple machine consisting of two back-to-back inclined planes, and the wheel and axle, which is a simple machine consisting of a rod fixed to the center of a wheel. These machines help to multiply or augment a force, thereby providing a mechanical advantage to the user.

A complex machine, such as a bicycle or a car, combines several simple machines to perform a task more efficiently. The wire cutters, for instance, combine two levers and two wedges, while bicycles include components like wheel and axles and pulleys. The concept of mechanical advantage (MA) is crucial as it represents the ratio of output to input forces, allowing for a smaller force to perform a given task thanks to the simple machine.

Answer:

The magnitude of its displacement of the car is 28 km.                

Explanation:

It is given that,

Distance covered by the car due west, [tex]d_1=20\ km[/tex]

Distance covered by the car due south, [tex]d_2=20\ km[/tex]

We need to find the magnitude of its displacement. Let it is given by d. We know that displacement of an object is equivalent to the shortest path traveled. It can be calculated as :

[tex]d=\sqrt{d_1^2+d_2^2}[/tex]

[tex]d=\sqrt{(20)^2+(20)^2}[/tex]

d = 28.28 km

or

d = 28 km

So, the magnitude of its displacement is 20 km. Hence, the correct option is  (c).

The final velocity of the snowmobile after accelerating for 5.6 seconds is approximately 8.788 m/s. If it decelerates at a rate of -0.51 m/s^2, it will take roughly 9.22 seconds to reach a complete stop.

To find the final velocity of the snowmobile that has an initial velocity of 4.7 m/s and accelerates at the rate of 0.73 m/s2 for 5.6s, we can use the formula:

v = u + at

Where:

Plugging in the values gives us:

v = 4.7 m/s + (0.73 m/s2)(5.6 s)

v = 4.7 m/s + 4.088 m/s

v ≈ 8.788 m/s

To calculate the time it takes to reach a complete stop when the snowmobile decelerates at a rate of -0.51 m/s2, we rearrange the formula to solve for time:

t = (v - u) / a

Since the final velocity v at a complete stop is 0 m/s, the initial velocity u is 4.7 m/s (the velocity before deceleration), and a is -0.51 m/s2, the time t is:

t = (0 m/s - 4.7 m/s) / -0.51 m/s2

t ≈ 9.22 s

The average speed of the ocean current that carried the rubber ducks was approximately 0.309 miles per hour (mi/h) or 0.138 meters per second (m/s), calculated by dividing the total distance by the time taken and converting the units accordingly.

The question revolves around calculating the average speed of ocean currents based on the distance rubber ducks traveled after being spilled into the ocean. To find the average speed, we divide the total distance by the total time taken. In this case, the ducks traveled approximately 1800 miles over eight months. Since one month averages about 30.44 days, and there are 24 hours in a day, we first convert 8 months into hours:

8 months * 30.44 days/month * 24 hours/day = 5825.92 hours

Now we calculate the average speed in miles per hour (mi/h):

Average Speed = Total Distance / Total Time = 1800 miles / 5825.92 hours = 0.309 mi/h

Next, we'll convert this speed into meters per second (m/s), using the conversion factor where 1 mile = 1609.34 meters.

0.309 mi/h * (1609.34 meters/mile) / (3600 seconds/hour) = 0.138 m/s

Therefore, the approximate average speed of the ocean current was 0.309 mi/h or 0.138 m/s.

Final answer:

Information in the human brain is first stored in the hippocampus, which is crucial for converting short-term memory into long-term memory and for spatial navigation. The hippocampus works with other brain parts, like the cortex, for the long-term storage of information. Understanding hippocampus function helps underscore the importance of mental engagement and continuous learning.

Explanation:

Information in the human brain is first stored in the hippocampus, an essential part of the brain's limbic system. The hippocampus plays a critical role in the consolidation of information from short-term memory to long-term memory and spatial navigation. When we encounter new information, it is temporarily held in the sensory and short-term memory; if deemed important, this information is then transferred to the hippocampus for more durable storage. Over time, the process of memory consolidation involves the transfer of memories from the hippocampus to other parts of the brain for long-term storage, particularly to the cortex.

The formation and retrieval of memories involve a complex process that is not fully understood but is known to depend on various factors, including attention, emotional significance, and repetition. Neuroplasticity, or the brain's ability to reorganize itself by forming new neural connections, plays a vital role in learning and memory. This fascinating aspect of brain functionality underscores the importance of continuous learning and mental engagement for cognitive health.

The state of matter that has the greatest distance between the individual particles is steam. Thus, the correct option for this question is C.

The state of matter may be characterized as one of the distinct forms in which matter can exist in nature. It is a way to describe the behavior of atoms and molecules in a substance. There are three main states of matter that are commonly found in nature. They are as follows:

The distance between the individual particles depends on the type of the state of matter. For example, a solid has the least distance between the individual particles because the particles of a solid are closely compact.

On contrary, the molecules in the gaseous states are loosely bound to each other and the intramolecular force of attraction between the particles is very low. Steam represents the example of a gaseous state of matter.

Therefore, the state of matter that has the greatest distance between the individual particles is steam. Thus, the correct option for this question is C.

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Answer:

t = 41.56 min

Explanation:

As we know that the distance moved on the trade mill is given as

[tex]d = 7500 ft[/tex]

here we know that

[tex]1 ft = 12 inch[/tex]

[tex]1 inch = 2.54 cm[/tex]

so we have

[tex]1 ft = 12 \times 2.54 cm[/tex]

[tex]1 ft = 0.3048 m[/tex]

now we know that

[tex]d = 7500 \times 0.3048 m[/tex]

[tex]d = 2286 m[/tex]

now we know that the speed on the trade mill is given as

[tex]v = 55 m/min[/tex]

so time taken to move the given distance is

[tex]t = \frac{d}{v}[/tex]

[tex]t = \frac{2286}{55}[/tex]

[tex]t = 41.56 min[/tex]

Answer: c. There is more air pressure pushing up on the object than there is pushing down

Explanation:

air pressure increases with air column above it. Thus, with increasing depth, the air pressure increases. Air pressure acts in all the directions. The bottom surface experiences greater air pressure than the top surface. Thus, there is more air pressure pushing up on the object than there is pushing down. correct option is c.

Answer:

option (a)

Explanation:

The electrical power is defined as the energy per unit time.

The formula foe the power is given by

P = V I = I^2 R = V^2 / R

So, to find the power we must know the values of current and voltage.

Answer:

The answer is <<< A. current and voltage

Explanation:

The question involves adding and subtracting the vector components of three displacements and calculating the angle between the resultant vector and the z-axis. Further, it asks for the components of one displacement vector along and perpendicular to the direction of another displacement vector. These operations involve vector dot product and cross-product calculations.

To solve this problem, you first need to subtract and add the respective i, j, and k components of the three displacements: d1, d2, and d3. Calculations will give you r which is represented by three values (a), (b), and (c) for i, j, and k components respectively.

To find the angle (d) between r and the positive z-axis, you will have to use the dot product formula and the arccos function. The component of d1 along the direction of d2 can be calculated using the dot product of d1 and the unit vector in the direction of d2 (part (e) of your question). The component of d1 perpendicular to the direction of d2 and in the plane of d1 and d2, asked in part (f), can be found using vector cross-product operations and the magnitude of the resulting vector.

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The displacement vector r is (4.5i + 2.8j - 0.9k). The angle between r and the positive z-axis is approximately 16.35°. The component of d1 along the direction of d2 is -1.5 and the component of d1 perpendicular to the direction of d2 and in the plane of d1 and d2 is (3.0i + 1.8j - 5.0k).

The displacement vector r can be calculated by subtracting d2 from d1 and adding d3. In component form, r = (d1 - d2 + d3) = (1.5 - (-1.0) + 4.0)i + (1.8 - 2.0 + 3.0)j + (-5.0 + 3.0 + 2.0)k = 4.5i + 2.8j - 0.9k.

(d) To find the angle between r and the positive z-axis, we can calculate the dot product of r and the unit vector along the positive z-axis. The dot product is given by cos(θ) = (r dot k) / (|r||k|), where r dot k is the dot product of r and k. Since |k| = 1, we have cos(θ) = (r dot k) / |r|. Evaluating the dot product, we get the angle θ ≈ 16.35°.

(e) The component of d1 along the direction of d2 can be found using the dot product formula. The component is given by |d1| cos(θ), where θ is the angle between d1 and d2. Since θ = 180°, the component is 1.5 cos(180°) = -1.5.

(f) The component of d1 that is perpendicular to the direction of d2 and in the plane of d1 and d2 can be found by subtracting the component in the direction of d2 from d1. The component is given by d1 - (|d1| cos(θ)) = 1.5i + 1.8j - 5.0k - (-1.5i) = 3.0i + 1.8j - 5.0k.

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The molar mass of the newly discovered gas is approximately 58.8 g/mol. This was calculated using the Ideal Gas Law and the gas's given density, temperature, and pressure.

To determine the molar mass of a gas, you can use the Ideal Gas Law rearranged to solve for molar mass (M): = RT / , where 'm' is mass, 'R' is the gas constant, 'T' is temperature in Kelvin, 'P' is pressure, and 'V' is volume.

However, you can also use the given gas density (ρ = mass/volume = 2.39 g/L) and the Ideal Gas Law in a combined form: = / . So, the molar mass would be = (2.39 g/L * 0.0821 L atm/ K mol * (273.15 + 23.0)K ) / 0.941 atm = 58.8 g/mol.

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