PLEASE ANSWER

These two containers have a pink liquid in them. Which of these containers has more thermal energy and why?

A. Container B has more thermal energy because the temperature is higher.
B. Container A has more thermal energy since there is more room for the liquid to move around.
C. Even thought the temperature is the same,, container A has more thermal energy since it has less liquid than container B
D. Even thought the temperature is the same, container B has more thermal energy since it has more liquid than container A

Answer:

Sweat gland release moisture on the skin, cooling and relaxing the skin

Explanation:

Sweat gets sunken into your skin so it won't evaporate much.

Sweat is mainly water with a little bit of salts.

Whenever sweat evaporates, it tends to cool down the skin.  

Answer:

They all vibrate, but they all move differently.

Explanation:

Similarities: They all consist of particles and vibrate, just at different frequencies.

Differences: The particles in solids move slowly and vibrate. In liquids, they move a bit quicker and slide past one another. They will also take the shape of the container they're in. In gases, they move freely at high speeds and also taking the shape of the container.

Hope this helped! :)

Answer:

Gravitational energy and thermal energy

Explanation:

A water cycle is a product of gravitational energy from the earth and thermal energy from the sun.

A water cycle is driven around with the help of hydroelectric energy. Now  hydroelectric energy is a product of potential energy that is converted into kinetic energy, with the help of gravitational energy, which again is also acquired from thermal energy from the sun.

Therefore, the correct answer is gravitational energy and thermal energy.

No. of atoms included in 1245 mg is 0.127 *[tex]10^{23}[/tex] atoms.

Answer:

Explanation:

We know that we can determine the number of atoms in any given amount of sample by dividing the given weight to the atomic mass of the particular sample and then multiplying it with avagadro's number.

So, here the atomic mass of cobalt is 58.9 amu.

Thus,

No.of atoms  = [tex]\frac{1245 mg}{58.9g} * 6.023 * 10^{23}[/tex]

No. of atoms included in 1245 mg is 0.127 *[tex]10^{23}[/tex] atoms.

As we know that atomic mass of any element contains avagadro's number of atoms. So in order to find the number of atoms in a given weight of sample, we have to follow the above procedure.

No. of atoms included in 1245 mg is 0.127 *[tex]10^{23}[/tex] atoms.

Answer:

                   T₁  =  194 K

Solution:

Data Given:

                 Initial Temperature  =  T₁  =  ??

                 Final Temperature  =  T₂  =  465 K

                 Initial Pressure  =  P₁  =  18.7 psi

                 Final Pressure  =  P₂  =  20.2 psi

                 Initial Volume  =  V₁  =  0.475 L

                 Final Volume  =  V₂  =  1.054 L

Formula Used:

Let's assume that the hydrogen gas in balloon is acting as an Ideal gas, the according to Ideal Gas Equation,

                 P V  =  n R T

where;  R  =  Universal Gas Constant  =  0.082057 atm.L.mol⁻¹.K⁻¹,

Taking number of moles and R constant we can have following formula for initial and final states,

                P₁ V₁ / T₁  =  P₂ V₂ / T₂

Solving for T₁,

                T₁  =  P₁ V₁ T₂ / P₂ V₂

Putting values,

                T₁  =  (18.7 psi × 0.475 L × 465 K) / (20.2 psi × 1.054 L)

               T₁  =  194 K

Answer:

194 K

Explanation:

Mass of boron trifluoride is 35.768 g.

Firstly we need to write the balanced chemical equation involved in this question:

[tex]2B(s)+ 3F_2(g)[/tex] → [tex]2BF_3(g)[/tex]

It is given that:

Mass of fluorine= 30.0 g

So, we need to calculate moles of Fluorine

∵ Molar mass of fluorine= 38 g/mol

[tex]n= \frac{m}{M} = \frac{30.0g}{38 gmol^{-1}} = 0.789 mol[/tex]

Now, for 3 moles of F₂ ; 2 moles of BF₃ are produced.

So, for 0.789 moles of F₂, number of moles of  BF₃ will be:

[tex]\frac{2}{3} *0.789=0.526 \text{mol}[/tex]

Moles of  BF₃ =0.526 mol

∵ Molar mass of boron trifluoride =67.8 g/mol

Thus, mass of boron trifluoride can be calculated as:

[tex]m=n*M= 0.526*67.8=35.662 g[/tex]

⇒Mass of boron trifluoride is 35.768 g.

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Not among the offered possibilities as the closest option is 53.0 grams. Using the stoichiometry of the balanced chemical equation for the reaction between boron (B) and fluorine to make boron trifluoride, we can calculate the mass of boron trifluoride (BF₃) that can be produced from 30.0 grams of fluorine (F₂).

The chemical formula is B + 3 F₂ BF₃, which is balanced.

One mole of boron combines with three moles of fluorine to form one mole of boron trifluoride, as shown by the equation.

First, we must change the amount of fluorine from grams to moles: (30.0 grams F₂) / (38.00 grams/mole F₂) = 0.789 moles F₂.

According to the stoichiometry, 3 moles of fluorine are converted into 1 mole of boron trifluoride. As a result, the amount of BF₃ that was created is similarly 0.789 moles.

Finally, by utilizing its molar mass, we can determine the mass of BF₃:

53.49 grams BF₃ are equal to (0.789 moles BF₃) times (67.81 grams/mole BF₃).

As a result, 30.0 grams of fluorine may be used to produce around 53.49 grams of boron trifluoride.

The estimated number is not exactly matched by any of the available response options. The response would be: Not among the offered possibilities as the closest option is 53.0 grams.

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Answer:

5878.6 j

1.405 cal

Explanation:

Given data:

Specific heat of fat = 0.45 cal/g.°C or 1.9 j/g.°C

Density of fat = 30.94 g/cm³

Initial temperature = 25°C

Final temperature = 35°C

Energy needed = ?

Volume of fat = 10 cm³

Solution:

First of all we will calculate the mass of fat from given density and volume.

d = m/v

30.94 g/cm³ = m/ 10 cm³

m = 30.94 g/cm³ ×  10 cm³

m = 309.4 g

Now we will calculate the energy needed for fat.

Q = m.c. ΔT

Q = amount of heat absorbed or released

m = mass of given substance

c = specific heat capacity of substance

ΔT = change in temperature

ΔT = T2 - T1

ΔT =  35°C -  25°C

ΔT =  10°C

Q = m.c. ΔT

Q = 309.4 g . 1.9 j/g.°C . 10°C

q = 5878.6 j

In calories,

5878.6 / 4184 = 1.405 cal

The energy required to heat 10cm3 of fat from 25°C to 35°C is calculated using the specific heat formula. The calculations in calories and joules are 42.3 cal and 178.6 Joules respectively.

To calculate the amount of energy needed to heat 10 cm3 of fat from 25 °C to 35 °C, we have to understand the concept of specific heat, which is the energy required to raise the temperature of 1 gram of a substance by 1 °C. Here, we are dealing with the substance fat, which has a specific heat of 0.45 cal/(g ⋅ °C) or 1.9 J/g °C and a density of 0.94 g/cm3.

First, determine the mass of the fat using the formula mass = volume × density. Here, volume is 10 cm3 and density is 0.94 g/cm3, which gives us a mass of 9.4 g. The change in temperature (ΔT) we need is from 25°C to 35°C, hence ΔT = 35 - 25 = 10 °C.

The energy required can then be calculated using the formula energy = mass × specific heat × ∆T. For calories, the calculation is energy = 9.4g × 0.45 cal/(g °C) × 10 °C = 42.3 cal. For Joules, the calculation is energy = 9.4 g × 1.9 J/(g °C) × 10°C = 178.6 Joules.

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Fungi play a crucial role in the food web shown as they are decomposers. They break down dead organic matter, such as dead plants and animals, and recycle the nutrients back into the ecosystem.

Microbes, or microorganisms, play important roles in food webs and ecosystem functioning. They can be found at all trophic levels of the food web, from primary producers to top predators, and their activities have significant impacts on the cycling of energy and nutrients.

In this food web, the fungus likely feeds on dead organic matter produced by the other organisms in the ecosystem, such as the sloth and the fruit bat.

This recycling of nutrients helps to maintain the balance of the ecosystem and supports the growth of other organisms in the food web, such as the strangler fig which may benefit from the nutrients provided by the decomposing organic matter.

Without decomposers like fungi, dead organic matter would accumulate in the ecosystem, leading to nutrient depletion and the eventual collapse of the food web.

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1. Yes, the data supported my hypothesis.

2. Water refracted the light rays the most.

3. Air refracted the light rays the least.

4. Density affects refraction because the denser the material, the slower the speed of light in that material.

5. The light ray would be refracted very strongly.

6. Reflection, refraction, and absorption of light can be observed in mirrors, aquariums, and sunglasses.

Summary of lab results:

Reflection, refraction, and absorption of light can be observed in many everyday activities. For example, when you look in a mirror, you are seeing a reflection of yourself. When you look at a fish in an aquarium, you are seeing the refraction of light as it passes from the water into the air. And when you wear sunglasses, you are absorbing some of the sunlight, which helps to protect your eyes.

Interpretation of the results:

The results of the lab supported my hypothesis that the denser the material, the more it would refract light. The light rays were refracted the most when they passed from air into water, which is the denser of the two materials. The light rays were refracted the least when they passed from air into glass, which is the least dense of the three materials.

The density of a material affects how much it refracts light because the denser the material, the slower the speed of light in that material. When light travels from a less dense material to a denser material, it slows down and bends towards the normal. When light travels from a denser material to a less dense material, it speeds up and bends away from the normal.

The results of this lab can be used to explain many everyday phenomena, such as why diamonds sparkle so much. Diamonds are very dense materials, so they refract light very strongly. This is why when you look at a diamond, you see a rainbow of colors.

Reflection, refraction, and absorption of light in everyday activities:

Reflection, refraction, and absorption of light are all around us in our everyday activities. Here are a few examples:

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Final answer:

In the lab investigation, glass refracted light the most, air the least, and density was found to significantly affect the degree of light refraction. A light ray passing through a diamond would exhibit a substantial amount of refraction due to the diamond's high density.

Explanation:

Conclusion: Interpretation of Lab Results

To conclude the investigation on refraction phenomena, it is essential to analyze the data collected and compare it to our initial hypothesis. When examining whether the data supported the hypothesis, it is crucial to reference specific evidence from the experiment. The hypothesis, in this case, may have been concerning the relationship between density and refraction of light through different materials.

Regarding which material refracted light rays the most, glass typically has a higher index of refraction compared to air and water, indicating that light rays bend more when passing through glass. Conversely, air refracted the light rays the least among the three because it has the lowest density and index of refraction.

Density is directly related to refraction; denser materials have higher indexes of refraction and therefore bend light to a greater degree. Given that diamonds are highly dense, a light ray projected from air through a diamond would undergo significant refraction, resulting in a high degree of bending.

In daily life, reflection can be observed in mirrors, refraction when looking at objects submerged in water, and absorption when objects do not reflect or transmit light visibly. Recalling these phenomena can aid in understanding their application and significance.

Answer:

[tex]\large \boxed{\text{4650 nm}}[/tex]

Explanation:

The second line in the Pfund series corresponds to a transition from n = 7 to n = 5.

To calculate the wavelength of the transition, we can use the Rydberg equation:

[tex]\dfrac{1}{\lambda} = R_{H}\left ( \dfrac{1 }{n_{1}^{2}} - \dfrac{1 }{n_{2}^{2}} \right )[/tex]

where

[tex]R_{H} = 1.097 \times 10^{7} \text{ m}^{-1}[/tex]

If n₁ = 5 and n₂ = 7

[tex]\begin{array}{rcl}\dfrac{1}{\lambda} & = & 1.097 \times 10^{7} \text{ m}^{-1}\left ( \dfrac{1 }{5^{2}} - \dfrac{1 }{7^{2}} \right )\\\\ & = & 1.097 \times 10^{7} \text{ m}^{-1}\left ( \dfrac{1 }{25} - \dfrac{1 }{49} \right )\\\\ & = & 1.097 \times 10^{7} \text{ m}^{-1}\left ( \dfrac{49 - 25 }{49 \times25}\right )\\\\& = & 1.097 \times 10^{7} \text{ m}^{-1}\left ( \dfrac{24 }{1225}\right )\\\\ & = & 2.149 \times 10^{7}\text{ m}^{-1}\\\end{array}\\[/tex]

[tex]\begin{array}{rcl}\lambda & = & \dfrac{1}{2.149 \times 10^{7}\text{ m}^{-1}}\\\\ & = & 4.65 \times 10^{-6} \text{ m}\\ & = & \mathbf{4650} \textbf{ nm}\\\end{array}\\\text{The wavelength of the line is $\large \boxed{\textbf{4650 nm}}$, which is in the $\textbf{infrared region}$}.[/tex]

The calculated wavelength for the second line in the Pfund series is 4.65 x 10^-6 m (4650 nm), positioning it within the infrared spectrum.

Rydberg Equation:

The Rydberg equation is employed to calculate the wavelength (λ) of light emitted or absorbed during electronic transitions in hydrogen-like atoms.

"1/λ = RH (1/n₁² - 1/n₂²)"

Given Values:

We are given the Rydberg constant (RH) as "1.097 x 10^7 m^-1" and the principal quantum numbers (n₁ = 5 and n₂ = 7).

Substitute Values:

Substituting the known values into the Rydberg equation:

"1/λ = 1.097 x 10^7 (1/5² - 1/7²)"

Evaluate Exponents:

Calculating the squares in the denominators:

"1/λ = 1.097 x 10^7 (1/25 - 1/49)"

Find Common Denominator:

Combining the fractions over a common denominator (1225):

"1/λ = 1.097 x 10^7 (49 - 25)/1225"

Combine Terms:

Simplifying the expression:

"1/λ = 1.097 x 10^7 (24/1225)"

Calculate:

Performing the multiplication:

"1/λ = 2.149 x 10^7 m^-1"

Reciprocal to Find Wavelength:

Taking the reciprocal to find the wavelength:

"λ = 1/(2.149 x 10^7)"

Final Result:

Converting the numerical result to scientific notation:

"λ = 4.65 x 10^-6 m"

= 4650nm

This detailed calculation ensures a comprehensive understanding of each step involved in determining the wavelength.

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6.72 L of Carbon Monoxide (CO) is needed.

Explanation:

First from the mass of the oxygen in grams is converted into moles and then it is proportionate to the moles of CO and then it is converted into its Volume in litres ( L).

4.8 g of O₂ × 1 mol of O₂× 2 mol CO ×22.4 L CO / (32 g of O₂ × 1 mol of O₂ × 1 mol of CO) = 6.72 L CO

The volume of CO reacted with oxygen at STP has been 6.72 L.

The moles of reactant and product in a balanced chemical equation has been given by the stoichiometric coefficient.

The balanced chemical equation for the formation of carbon dioxide has been:

[tex]\rm 2\;CO\;+\;O_2\;\rightarrow\;2\;CO_2[/tex]

The balanced chemical equation has been giving the information of 2 moles of CO reacted with a mole of oxygen.

The available moles of oxygen in 4.80 g has been:

[tex]\rm Moles\;=\;\dfrac{Mass}{Molar\;mass}\\\\ Moles\;O_2=\dfrac{4.80}{32}\\\\ Moles\;O_2=0.15\;mol[/tex]

The available moles of oxygen has been 0.15 mol.

The moles of CO reacted has been given by the stoichiometric coefficient of the balanced equation as:

[tex]\rm 1\;mol\;O_2=2\;mol\;CO\\0.15\;mol\;O_2=0.30\;mol\;CO[/tex]

The moles of CO reacted has been 0.30 mol.

The volume of a mole of gas at STP has been 22.4 L. The volume of 0.30 mol CO has been:

[tex]\rm 1\;mol=22.4\;L\\\\0.30\;mol=\dfrac{22.4}{1}\;\times\;0.30\;L\\\\ 0.30\;mol=6.72\;L[/tex]

The volume of CO reacted with oxygen has been 6.72 L.

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Answer:

             The complete chemical equation is as;

                                          C + O₂   →   CO₂

Explanation:

                    According to law of mass conservation the mass in isolated system can neither be created nor be destroyed. Applying this law to given synthesis reaction means that,

               (i) If there is one carbon atom on left hand side of the equation (reactant side) then there must be on e carbon on right hand side (product side) of the equation.

                (ii) If there are two oxygen atoms on left hand side of the equation (reactant side) then there must be two oxygen atoms on right hand side (product side) of the equation.

Hence, from equation it is proved that it obeys the said law and the number of atoms on both side are equal i.e.

                           Reactant Side                     Product Side

Carbon                          1                                          1

Oxygen                          2                                         2

368.92 g of HCOOH could be formed.

Explanation:

First we have to write the balanced equation as,

CH₃OH + O₂ → HCOOH + H₂O

Here the question said that 8.02 mol of CH₃OH and 15.49 mol of O₂.

In the above reaction methanol and oxygen is used in 1:1 ratio, but the moles are lesser in case of methanol, so CH₃OH  is the limiting reagent.

Now by making use of 8.02 moles of methanol, we can produce 8.02 mol of HCOOH.

Molar mass of HCOOH is 46 g/mol.

So mass of HCOOH formed is moles ×molar mass of HCOOH.

8.02 moles × 46 g/mol = 368.92 g of HCOOH could be formed.

Answer: 498.51mmHg

Explanation:

First let us analyse what was given from the question:

T1 = 425K

T2 = 275.15K

P1 = 770 mmHg

P2 =?

Using the general gas equation

P1V1/T1 = P2V2/T2

But we were told from the question that the volume is constant. So, our equation becomes:

P1/T1 = P2/T2

770/425 = P2 /275.15

Cross multiply to express in linear form:

P2 x 425 = 770 x 275.15

Divide both side by 425, we have:

P2 = (770 x 275.15) /425

P2 = 498.51mmHg

Answer: 85.8 g AlCl3

Explanation:

Convert molecules of AlCl3 to moles using the Avogadro's number

Convert moles of AlCl3 to mass using its molar mass.

3.913x10²³ molecules AlCl3 x 1mole AlCl3 / (6.022x10²³ molecules AlCl3) X 132g AlCl3/ 1 mole AlCl3

= 85.8 g AlCl3

Answer:

[tex]\large \boxed{\text{8.00 mol}}[/tex]

Explanation:

We will need a balanced chemical equation with masses, moles, and molar masses.

1. Gather all the information in one place:

Mᵣ:                  18.02

            2Na + H₂O ⟶ 2NaOH + H₂

m/g:                72.0  

2. Moles of H₂O

[tex]\text{Moles of H$_{2}$O} = \text{72.0 g H$_{2}$O} \times \dfrac{\text{1 mol H$_{2}$O}}{\text{18.02 g H$_{2}$O}} = \text{3.996 mol H$_{2}$O}[/tex]

3. Moles of Na

The molar ratio is 2 mol Na/1 mol H₂O.

[tex]\text{Moles of Na} = \text{3.996 mol H$_{2}$O} \times \dfrac{\text{2 mol Na}}{\text{1 mol H$_{2}$O}} = \textbf{8.00 mol Na}\\\\\text{The water will react with $\large \boxed{\textbf{ 8.00 mol}}$ of Na}[/tex]

Final answer:

To find out how many moles of sodium would react with 72.0 grams of water, we calculate moles of water using its molar mass and then apply the stoichiometry of the reaction between sodium and water. We conclude that 4 moles of sodium would react with 72.0 grams of water.

Explanation:

The question appears to contain a typo and seems to ask how many moles of sodium would react with 72.0 grams of water.

Molar mass of water (H₂O) is approximately 18.02 g/mol. Therefore, to find out how many moles of water we have in 72.0 grams, we use the formula:

moles of H₂O = mass of H2O / molar mass of H₂O

moles of H₂O = 72.0 g / 18.02 g/mol = 4 moles of H₂O

The reaction between sodium (Na) and water (H₂O) typically forms sodium hydroxide (NaOH) and hydrogen gas (H2). The balanced chemical equation for this reaction is:

2Na + 2H₂O → 2NaOH + H2

From the balanced reaction, we can see that 2 moles of Na are required to react with 2 moles of H₂O. This means, to react with 4 moles of H₂O, we would need 4 moles of Na.

Answer:

                       1.42 g/mL

Explanation:

                    The mass per unit volume is called as density. It is an intensive property and its value doesn't depend upon the amount of a substance.

It is given as,

                                   Density  =  Mass / Volume

Data Given:

Mass of Liquid + Flask  =  163.4 g

Volume of Liquid = 5.98 mL

Mass of empty Flask = 154.9 g

Mass of Liquid  = 163.4 g - 154.9 g =  8.5 g

Formula Used:

                     Density  =  Mass / Volume

                     Density  =  8.5 g / 5.98 mL

                     Density  =  1.42 g/mL

Answer:

The standard boiling point of an ideal solution is 100 degree celsius for a given composition. Mostly all given  solution of a given composition is a constant (boiling point 100 degrees) but not all composition is constant.

Explanation:

Answer:

the standard boiling point of an ideal solution of a given composition is constant. The normal boiling point of an ideal solution such as water is 99.97 °C (211.9 °F) at a pressure of 1 atm (i.e., 101.325 kPa).

Explanation:

The motion of Earth's plates are like slow and constant. The correct option is D.

Tectonic plates are massive chunks of the Earth's crust and upper mantle. They are composed of oceanic and continental crust.

Earthquakes occur near mid-ocean ridges and large faults that mark the plate boundaries.

The hot magma flows in convection currents due to tremendous heat and pressure within the earth. These currents usually result the tectonic plates that make up the earth's crust to move.

The Earth's tectonic plates are constantly shifting. Heat within the Earth drives their movement.

Hot material within the Earth rises as a result, until it reaches the surface, where it moves sideways, cools, and sinks. Convection is the name given to this circular motion.

Thus, the correct option is D.

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Answer: V= 44. 6 L

Explanation: use Boyle's Law

P1V1 = P2V2

Derive to find V2:

V2 = P1V1 / P2

= 937.57 Pa( 12.5 L ) / 262.52 Pa

= 44.6 L

Answer:

Explanation:

5.6 mol

Answer: 96g

Explanation:

To find the mass of 2.40mol of NaOH, we must first obtain the molar mass of NaOH. This is illustrated below:

Molar Mass of NaOH = 23 + 16 + 1 = 40g/mol

From the question, we were asked to find the mass of 2.4moles of NaOH. This is done by the formula:

Mass = number of mole x molar Mass

Mass of NaOH = 2.4 x 40

Mass of NaOH = 96g

Answer:

only compounds with the (aq) state symbol

Only compounds with the an aqueous (aq) state symbol break up into ions in solution.

The solution in which water is present as solvent. The solute dissolved in water and form an ions which is surrounded by water molecules.

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Answer:

u gotta have the volume of it

Explanation:

The car would need approximately 7.73 gallons of gasoline for a 3.0-hour trip at a speed of 70 mi/h, and fuel efficiency of 11km/L.

To calculate how many gallons of gas are needed for a 3.0-hour trip, we must first figure out the total distance the car travels. With a speed of 70 miles per hour (mi/hr), the car would cover 70 mi/hr x 3 hours = 210 miles.

Next, we will have to convert miles to kilometers since the fuel consumption rate is given in kilometers per liter (km/L). So, 210 miles ≈ 321.87 kilometers (using conversion factor 1 mile ≈ 1.60934 kilometers).

The car uses gasoline at a rate of 11 kilometers per liter. Therefore, it would consume 321.87 kilometers ÷ 11 km/L ≈ 29.26 liters of gas.

Finally, since gas is usually measured in the U.S. in gallons, we need to convert liters to gallons. 29.26 liters ≈ 7.73 gallons (using conversion factor 1 liter ≈ 0.264172 gallons).

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Answer:

protists are part of the domain eukarya

protists make up the kingdom protista

hope this helps x

Final answer:

In a balanced chemical equation, if a coefficient is "1", it is typically left blank. Coefficients are used to ensure the same number of each atom on both sides of the equation and represent relative amounts of reactants and products in the simplest whole-number ratio.

Explanation:

The student's question is about understanding how coefficients are represented in a balanced chemical equation. When balancing chemical equations, it's important to adjust coefficients to ensure the same number of atoms of each element are on both sides of the equation. If a coefficient is "1", it is typically not written explicitly. For example, the balanced chemical equation for photosynthesis is 6CO2 + 6H2O → C6H12O6 + 6O2, where the coefficient of 1 for glucose is understood and therefore left blank. It's also critical to understand that coefficients should be in the simplest whole-number ratio, and they represent the relative amounts of substances involved in the reaction. For instance, when methane reacts with oxygen to yield carbon dioxide and water, the coefficients indicate a ratio of 1:2:1:2 for methane, oxygen, carbon dioxide, and water respectively.

Direction

Explanation:

In describing the displacement of a body, the directional attribute must be included or added to it.

Displacement is a vector quantity.

It is a length of path taken from start to finish of the motion of a body.

Coupled with this, the direction of the travel must also be included.

For example, Sam traveled in from Alaska to Florida with a displacement of 1000km south-east.

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Air bags help lessen injuries in an automobile crash.  --> Boyle's law

A helium balloon decreases in size when you put it into a freezer.  --> Charle's law

A can of spray paint will explode if tossed into a fire --> Gay Lussac's Law

Explanation:

- Boyle's law states that for a fixed mass of an ideal gas kept at constant temperature, the pressure of the gas (p) is inversely proportional to its volume (V):

[tex]p \propto V[/tex]

- Charle's law states that for a fixed mass of an ideal gas kept at constant pressure, the volume of the gas (V) is proportional to its absolute temperature (T):

[tex]V\propto T[/tex]

- Gay-Lussac's Law states that for a fixed mass of an ideal gas kept at constant volume, the pressure of the gas (p) is proportional to the absolute temperature (T):

[tex]p\propto T[/tex]

We can now use these three laws to explain the mentioned phenomena:

Air bags help lessen injuries in an automobile crash.  --> Boyle's law. In fact, as the volume of the gas inside the air bag increases, the pressure exerted by the gas inside decreases, and since the temperature is constant, the pressure exerted by the airbag on the passenger will be lower.

A helium balloon decreases in size when you put it into a freezer.  --> Charle's law. When the balloon is put into the freezer, its temperature decreases, and since the pressure inside the freezer is approx. constant, the volume of the balloon decreases as well.

A can of spray paint will explode if tossed into a fire --> Gay Lussac Law. Due to the fire, the temperature of the gas inside the can increases; since the volume is constant, the pressure will increase, and at some point it will be large enouth to cause the can to explode.

Learn more about ideal gases:

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The scenarios involving air bags, helium balloons in a freezer, and an exploding can of spray paint are explained by Gay-Lussac's Law and Charles's Law, relating to the pressure, temperature, and volume of gases.

The gas laws that explain each scenario provided are based on the relationships between pressure, volume, and temperature for a gas.

Answer:

positive

Explanation:

lost of negative electron leaves one more positive charges than negative charges.

Answer:

h2*

Explanation: