When you sneeze, the air in your lungs accelerates from rest to approximately 160 km/hr in about 0.55 seconds . what is the acceleration of the air in m/s2?

Final velocity = Vf=0 
Initial velocity = Vi = 9.5m/s 
Acceleration = a = -4.6m/s²
Time = t =? 

Now use the formula;

Vf=Vi+at 

0=9.5 - 4.6m/s²t

-9.5 = -4.6m/s²(t) 

9.5/4.6 = t
T= 2.01s

Using Ohm's Law, the resistance required in a circuit with a voltage of 120 volts to achieve a current of 5 amps is calculated to be 24 ohms.

To determine the resistance that must be in the circuit when the voltage is 120 volts, and the current is 5 amps, you can use Ohm's Law.

Ohm's Law states that V = IR, where V is the voltage, I is the current, and R is the resistance. You can rearrange the equation to solve for resistance: R = V/I.

Plugging the given values into this formula:

Voltage (V) = 120 volts

Current (I) = 5 amps

Resistance (R) = V/I = 120V / 5A = 24 ohms.

Therefore, the circuit must have a resistance of 24 ohms to achieve a current of 5 amps with a voltage of 120 volts.

The number of atoms required to span the given distance is [tex]9.1\times 10^8[/tex].

The SI unit of length is the meter. The unit conversion of the picometer and millimeter to the meter is:

[tex]1\ pm= 10^{-12}\ m\\1\ mm= 10^{-3}\ m[/tex]

Given:

The radius of the niobium atom, [tex]r=131\ pm[/tex]

The length to be covered is [tex](l) =2.40\ mm[/tex]

Convert both magnitudes into meters.

[tex]r=131\times10^{-12}\ m\\l=2.40\times10^{-3}\ m[/tex]

The number of atoms required to cover the length is calculated as:[tex]n=\frac{l}{2\times r}\\=\frac{2.40\times 10^{-3}}{2\times1.31\times10^{-12}}\\=9.6\times10^8[/tex]

Therefore, the number of atoms required to span the given distance is [tex]9.1\times 10^8[/tex].

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Final answer:

Approximately 9160 niobium atoms, each with a diameter of 262 pm, would need to be laid side by side to span a distance of 2.40 mm.

Explanation:

To determine how many niobium atoms would span a distance of 2.40 mm, we need to convert the length into picometers (pm) since the atomic radius of niobium is given in picometers. First, convert millimeters to picometers:

1 mm = 106 pm

Therefore, 2.40 mm equals 2.40 × 10⁶ pm:

2.40 mm = 2.40 × 10⁶ pm

Next, since the atomic radius of niobium is the distance from the center to the edge of one atom, the diameter of one niobium atom is twice the radius. Therefore, the diameter is 2 × 131 pm = 262 pm.

To find out how many niobium atoms fit into 2.40 mm, divide the total distance in picometers by the diameter of one niobium atom:

Number of Niobium atoms = Total distance (pm) / Diameter of one atom (pm)

Number of Niobium atoms = 2.40 × 10⁶ pm / 262 pm

Finally, calculate the number of niobium atoms:

Number of Niobium atoms = 9160.3

Since we cannot have a fraction of an atom, we round to the nearest whole number, which makes it roughly 9160 niobium atoms that would span 2.40 mm.

Those stitches are what "chews" into the wind when you like to throw a breaking ball. Additionally, a knuckleball that barely spins eats at the wind using the stitches on the ball and this enables it to drop, sail or rise.

In short, the stitches makes the ball air resistant or cut into air making it faster.

The most ‘striking’ feature of the baseball is the stitches that interact with the air when the ball moves. Along with a slight effect on the air drag, there is a strong effect on the Magnus force. According to the stitch pattern, the Magnus force on a moving ball depends accordingly because the air interacts strongly with the raised stitches on the ball. Apart from this, the stitches provide a better grip for the pitcher and help in forcing the ball to move in different ways.

Answer:

Ff = 5.5 N

Explanation:

Given:

M: 15kg

A: 16.3 m/s2

We use:

[tex]f=ma[/tex]

force=mass*acceleration

[tex](15kg)(16.3m/s^{2} )=244.5N[/tex]

This means that 244.5 N is the net force on the object, and the right vector is showing 250 N, so to find the left vector - which would be a negative number (left direction) - we do

[tex](-Ff)+250N= 244.5N (net force)[/tex]

Hope This Helps!

Final answer:

The question delves into historical instances of execution by hanging, touching on both real individuals like John Brown and Nat Turner, and fictional characters such as Peyton Farquhar. These figures were tied to pivotal societal and political issues, such as slavery and civil war, facing harsh penalties for their actions.

Explanation:

The question refers to various historical figures who were executed by hanging for their actions which often had considerable political or social impact. Peyton Farquhar, a fictional character from Ambrose Bierce’s short story, "An Occurrence at Owl Creek Bridge", symbolizes the concept of civilian interference in military matters and the grim consequences that follow during times of war. He is described as a genteel man, suggesting that civil status did not exempt one from capital punishment. A reference is made to John Brown, a historical figure who was hanged in 1859 after attempting to initiate a slave revolt at Harpers Ferry, effectively marking a critical moment that stirred greater national tension leading to the American Civil War.

Similarly, it mentions Nat Turner, leader of a slave rebellion in Virginia, which led to a swift and brutal response from the state authorities and white vigilantes, resulting in his death along with many other Black individuals, free and enslaved. Lastly, it hints at the Fugitive Slave Law and the repercussions for those who attempted to help enslaved individuals escape, as in the case of the unidentified 'young white man from Ohio.' This aligns with historical accounts of abolitionists and their often fatal attempts to combat slavery.

Final answer:

SI base units are the seven fundamental units in the SI system, such as kilograms for mass; derived units, such as grams per milliliter for density, are constructed by combining base units. Derived units are essential for expressing a wide range of physical quantities, demonstrating the SI system's adaptability.

Explanation:

The difference between SI base units and derived units lies in their definitions and applications. SI base units are the seven fundamental units of measurement in the International System of Units (SI) that are defined by specific physical phenomena and are independent of each other. These include the kilogram (kg) for mass and the meter (m) for length, among others. On the other hand, derived units are units that are constructed by combining the base units according to algebraic relationships. Examples of derived units include grams per milliliter (g/mL) for density and joules (J) for energy, which are obtained by combining base units in multiplicative ways.

Derived units can express a wide variety of physical quantities such as area, volume, density, and energy, showcasing the versatility of the SI system. Combining prefixes with base units can also create new units of larger or smaller sizes, enhancing the adaptability of the system to cover a broad range of measurements from the microscopic to the astronomical scale.

The philosophy is simple that no one can start the journey towards being a Muslim unless he professes the basic principles mentioned in the  "Declaration of Faith", which is "“There is none worthy of worship but Allah and Muhammad is His Messenger”.
The declaration consists of the two most fundamental elements of Islamic ideology:
1) Unity of Allah: Declaring that there is only One God and none else is mandatory to be a Muslim.
2) Faith in the prophet hood of Muhammad, the messenger of Islam.

We must take note that the 28 meters high is simply a diversion. What we only need is the 4 hours and 12 kilometers distance. The formula for calculating the speed or velocity is :

velocity = distance / time

Therefore:

velocity = 12 km / 4 h

velocity = 3 km / h = 0.83 m / s 

Answer: So the campers must travel 12km two times (because they must go back after reached the lighthouse), and 28m two times.

If they keep the velocity constant (it means that they climb up and down the stairs at the same speed that they walk )

then you could add the whole distance as 12km*2 + 28m*2

a km is 1000m, so the distance will be 12000*2m+28*2m = 24046m

and they have 4 hours to do this, so the velocity is distance over time, they should do 24046m/4hours = 6011.5m/h or 6.0115km/h

Answer:

5 km

Explanation:

Hello

speed is the relationship between a travel length and the time taken for it,and  the equation is given by

[tex]V=\frac{displacement(d)}{time\ used\ for\ do\ that\ displacement(t)}\\\\ V=\frac{d}{t}[/tex]

Step 1

the speed and the time are known data, so we have to isolate the displacement

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

Step 2

same units of time must be used, hence

using a rule of three let's convert 30 min into hours

[tex]1\ hour = 60\ minutes\\x? hours= 30\ min\\\frac{1\ hour}{60\ minutes}=\frac{x}{30\ minutes } \\ x=\frac{1\ hour*30\ minutes}{60\ minutes}\\x=0.5\ hours\\[/tex]

Step 3

Put the values into the equation

[tex]d=v*t\\d=10\frac{km}{h}* 0.5\ h\\\\ d=5 km[/tex]

he traveled 5 kilometers

Have a good day

Final answer:

Using the density of pure silver (10.5 g/cm³), we calculate that 5.25 g of silver will have a volume of 0.5 cm³, raising the water level in the graduated cylinder from 11.2 mL to 11.7 mL.

Explanation:

The question asks to determine the volume level rise in a graduated cylinder when 5.25 g of pure silver is added to it. To find the rise in the volume of water within the cylinder, we utilize the concept of density, which relationship between mass and volume of a substance. The density of pure silver is given as 10.5 g/cm3. We can calculate the volume of the silver using the formula: Density = Mass / Volume, hence Volume = Mass / Density. Substituting the given values, we get Volume = 5.25 g / 10.5 g/cm3 = 0.5 cm3. Therefore, the volume level in the graduated cylinder will rise from 11.2 mL to 11.7 mL (since 1 cm3 = 1 mL).

Final answer:

To determine the initial speed of the second arrow when both arrows reach their maximum height at the same time, kinematic equations are utilized, taking into account the initial velocity of the first arrow, delay time before the second arrow is fired, and gravity's acceleration.

Explanation:

The problem given is a classic example of two-body motion in which two arrows are launched vertically with different initial velocities, and the challenge is to find the initial speed of the second arrow when both arrows reach their peak heights simultaneously. To solve this problem, we need to use the equations of kinematics for each arrow.

First, we find the time it takes for the first arrow to reach its maximum height using the initial speed and the acceleration due to gravity. The equation for this is derived from the kinematic equation v = u + at, where v is the final velocity (0 m/s at maximum height), u is the initial velocity (31.8 m/s), a is the acceleration (-9.8 m/s² directed downwards), and t is the time. Thus, the time, t, for the first arrow to reach its maximum height can be calculated as follows:

t = (v - u) / a

Knowing the time it takes for the first arrow to reach the maximum height, we can then calculate the initial speed of the second arrow, which is fired 1.82 s later. This involves adding the delay time to the time it took the first arrow to reach the maximum height and then using that total time to determine the initial speed of the second arrow using the kinematic equation u = v - at, with v again being 0 m/s at maximum height.

By carefully evaluating these kinematic equations, we find the initial speed of the second arrow, ensuring that both arrows reach their peak heights at the same moment.

Trigonometry allows finding the result for the angle for which the components of the velocity are equal is:  

Trigonometry allows you to find the component of the vectors with the relationships.

              [tex]cos \theta = \frac{v_x}{v} \\sin \theta = \frac{v_y}{v}[/tex]  

             vₓ = v cos θ

             [tex]v_y[/tex]  = v sin sin θ

Indicates that the values ​​of the two components are equal therefore.

           [tex]v_y = v_x[/tex]

          sin θ = cos θ

The only angle where the sine and cosine values ​​are equal is 45º

In conclusion using trigonometry we can find the result for the angle for which the components of the velocity are equal is:

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both a and b

ur answer is d