What happens to most embryos with extra chromosomes? Explain your answer.

Answer:

I think it is true

Explanation:

I just answer this question

Answer: 87690.67

Explanation: I don't even know if that's correct but i tried and i got close to that answer the i looked it up to see if i did it correctly and it rounded it up to that sooooooooo.........yeah.

The overall reaction for the oxidation of SO2 by O2 to give SO3 is:

SO2(g) + O2(g) ⟶ 2SO3(g)

The two given reactions are:

NO2(g) + SO2(g) ⟶ NO(g) + SO3(g)

2NO(g) + O2(g) ⟶ 2NO2(g)

Adding these reactions, we get:

NO2(g) + SO2(g) ⟶ NO(g) + SO3(g)

2NO(g) + O2(g) ⟶ 2NO2(g)

2NO2(g) + SO2(g) + O2(g) ⟶ 2NO(g) + 2SO3(g)

Therefore, the overall reaction for the oxidation of SO2 by O2 to give SO3 is:

SO2(g) + O2(g) ⟶ 2SO3(g)

where the catalyst NO2 is not explicitly shown. All the reactants and products are in the gas phase.

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Answer: Because frozen water is less dense than liquid water and therefore floats in liquid water.

Answer:

There are two different effects. Both a chemical and a physical reasoning are needed to explain what we can see. Both physics and chemistry matter. The initial cancellation effect can confuse the observer. Mathematics plays a role when the chemical equations are balanced. 

Explanation:

hope this helps u:))

900moles are 5.42x10²⁶ atoms of calcium.

What does the Avogadro number mean?

Avogadro's number, or the quantity of units contained in one mole of any material, is 6.02214076* 10²³. Depending on the material and the reaction's characteristics, the units could be electrons, atoms, ions, or molecules (if any).

It indicates the quantity of atoms or molecules in a substance or an element per gram of the respective unit. The number is 6.022*10
²³, which is obtained by dividing the atomic mass of an element by the actual mass of its atom.

There are 6.02*10²³ atoms in one mole

So, 5.42x10²⁶ atoms of calcium will be [tex]5.42x10^{26}/6.02*10 ^{23[/tex] moles i.e.

900moles.

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Answer:

Explanation:

Really need the equation.  But I am assuming it is this

3 Fe    + 4 H20 --> Fe3O4    +4 H2

625 gFe3O4 / 232 g Fe3O4 X 4 moles H2 / 1 mole Fe3O4  = 10.78 moles H2

If this equation is different than the one in your question you just need to plug in the number in front of the H2 where I have written a 4.

If 625 g of Fe[tex]_3[/tex]O[tex]_4[/tex]  is produced in the reaction, 10.78 moles of hydrogen are produced at the same time.

In the Worldwide System of Units, the mole (sign mol) is indeed the unit of material quantity (SI). The quantity of a substance is a measurement that indicates how many elementary constituents of a certain substance are present in an object as well as sample.

The mole has been defined as having  6.022×10²³  elementary entities.

3 Fe    + 4 H[tex]_2[/tex]O → Fe[tex]_3[/tex]O[tex]_4[/tex]   +4 H[tex]_2[/tex]

625g Fe[tex]_3[/tex]O[tex]_4[/tex] / 232g Fe[tex]_3[/tex]O[tex]_4[/tex] X 4 moles H2 / 1 mole Fe[tex]_3[/tex]O[tex]_4[/tex]  = 10.78 moles H[tex]_2[/tex]

Therefore, 10.78 moles of hydrogen are produced at the same time.

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According to the stoichiometry of the chemical equation, 5.704 moles of carbon dioxide are formed and 3.704 moles of the excess reactant remains.

It is the determination of proportions of elements or compounds in a chemical reaction. The related relations are based on law of conservation of mass and law of combining weights and volumes.

Stoichiometry is used in quantitative analysis for measuring concentrations of substances present in the sample.

1 mole of oxygen gives 2 moles carbon dioxide thus 2.852 moles of oxygen will give 2×2.852=5.704 moles and moles of excess reactant remaining=5.704-2=3.704 moles.

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(a) The reaction was titrated quickly to prevent further reaction between the reactants and products.

(bi) Number of moles of ethanoic acid left in the equilibrium mixture = 0.42 mol

ii) Number of moles of ethanoic acid reacted is 0.08 mol

iii) the number of moles of ethanol reacted is also 0.08 mol.

iv) Number of moles of ethanol left in the equilibrium mixture = 0.92 mol

(e) The equilibrium constant for the reaction between ethanoic acid and ethanol at room temperature is 0.209 dm^3/mol.

(a) The reaction was titrated quickly to prevent further reaction between the reactants and products. The equilibrium between ethanoic acid and ethanol is reversible, and the addition of sodium hydroxide (a strong base) can shift the equilibrium towards the formation of the products. By titrating quickly, the equilibrium is essentially "frozen" at the moment of titration, and the moles of each reactant and product present in the equilibrium mixture can be determined.

(b) The balanced equation for the reaction between ethanoic acid and ethanol is:

CH3COOH + C2H5OH ⇌ CH3COOC2H5 + H2O

(i) Number of moles of ethanoic acid left in the equilibrium mixture:

Number of moles of sodium hydroxide used = 40 cm^3 × 2 mol/dm^3 = 0.08 mol

Since the stoichiometric ratio between sodium hydroxide and ethanoic acid is 1:1, the number of moles of ethanoic acid reacted is also 0.08 mol.

Number of moles of ethanoic acid left in the equilibrium mixture = 0.5 mol - 0.08 mol = 0.42 mol

(ii) Number of moles of ethanoic acid reacted:

0.08 mol

(iii) Number of moles of ethanol reacted:

Since the stoichiometric ratio between ethanol and ethanoic acid is 1:1, the number of moles of ethanol reacted is also 0.08 mol.

(iv) Number of moles of ethanol left in the equilibrium mixture:

Number of moles of ethanol initially present = 1 mol

Number of moles of ethanol reacted = 0.08 mol

Number of moles of ethanol left in the equilibrium mixture = 1 mol - 0.08 mol = 0.92 mol

(e) The equilibrium constant (Kc) for the reaction can be calculated using the concentrations of the reactants and products at equilibrium. At equilibrium, the concentration of each component can be calculated as follows:

[ethanoic acid] = 0.42 mol / 1 dm^3 = 0.42 mol/dm^3

[ethanol] = 0.92 mol / 1 dm^3 = 0.92 mol/dm^3

[ethyl ethanoate] = 0.08 mol / 1 dm^3 = 0.08 mol/dm^3

Kc = ([ethyl ethanoate] x [H2O]) / ([ethanoic acid] x [ethanol])

= (0.08 mol/dm^3) / (0.42 mol/dm^3 x 0.92 mol/dm^3)

= 0.209 dm^3/mol

Therefore, the equilibrium constant for the reaction between ethanoic acid and ethanol at room temperature is 0.209 dm^3/mol.

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The rate of the reaction is correlated with the variation in concentration of each reactant and product, as can be seen from the rate expressions provided.

Rate = 1/2 [D] / [H] / [T]

This demonstrates that the reaction's rate and [H] concentration change are directly inversely related. Given that [D] is vanishing at a rate of 0.74 mol/L/s, the following conclusions can be drawn:

[D]/[t] = -0.74 mol/Ls We can solve for [H] / t by substituting this value into the rate expression above: Rate = 1/2 [D] / [H] / [T], ([H] / t) = -1/2 (-0.74 mol/Ls), [H]/[t] = 2(0.74 mol/L s) = 1.48 mol/L s With [D] decreasing at a rate of 0.74 mol/L, [H] is therefore increasing at a rate of 1.48 mol/L/s.

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Answer:

When wood is burned, it undergoes a chemical reaction called combustion, which produces heat, light, and various gases such as carbon dioxide, water vapor, and nitrogen oxides. These gases are released into the air, leaving behind a residue of ash that is much lighter than the original wood. Therefore, option A is the best explanation for what Courtney observes.

By using the ideal gas law to solve this problem and we get the volume of the container is approximately 1383 liters.

What is ideal gas law?

The ideal gas law is a fundamental equation in the study of thermodynamics and describes the behavior of an ideal gas. The ideal gas law relates the pressure (P), volume (V), number of moles (n), and temperature (T) of a gas:

                           PV = nRT

The ideal gas law assumes that the gas particles have negligible volume and do not interact with each other, except through elastic collisions. While real gases deviate from this ideal behavior at high pressures and low temperatures, the ideal gas law is still a useful approximation for many practical applications.

We can use the ideal gas law to solve this problem:

PV = nRT

where P is the pressure, V is the volume, n is the number of moles, R is the gas constant, and T is the temperature.

First, we need to convert the temperature to Kelvin:

770.56 K = 497.41 °C + 273.15

T = 1043.56 K

Next, we can plug in the values and solve for V:

V = (nRT)/P

V = (3.7522 mol)(0.08206 L·atm/(mol·K))(1043.56 K)/(7.25 atm)

V ≈ 1383 L

Therefore, the volume of the container is approximately 1383 liters.

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Answer:

2.The water, having a stronger concentration, moves inside the tea bag.

Explanation:

This is a form of osmosis called hypotonic, in which a solution with higher amounts of fluids than the cell will cause the cell to swell and expand. The opposite happens in hypertonic when the solution has fewer fluids than the cell, causing the cell to shrink. Essentially the liquid moves from the higher concentration to the lower one.

Answer:

Therefore, approximately 8.5 mL of chlorine gas can be produced from the decomposition of 25 g of aluminum chloride at 28°C and 750 mmHg.

Explanation:

The decomposition of aluminum chloride will not produce oxygen. Instead, it produces aluminum oxide and chlorine gas. The balanced chemical equation for this reaction is:

2AlCl3(s) → Al2O3(s) + 3Cl2(g)

To determine the volume of chlorine gas produced from the decomposition of 25 g of aluminum chloride, we need to use the ideal gas law, which is PV = nRT, where P is the pressure of the gas in atmospheres, V is the volume of the gas in liters, n is the number of moles of gas, R is the ideal gas constant (0.0821 L·atm/mol·K), and T is the temperature of the gas in Kelvin.

First, we need to determine the number of moles of aluminum chloride. The molar mass of AlCl3 is 133.34 g/mol, so:

25 g AlCl3 × (1 mol AlCl3/133.34 g AlCl3) = 0.187 moles AlCl3

According to the balanced chemical equation, 2 moles of AlCl3 will produce 3 moles of Cl2 gas. Therefore, 0.187 moles of AlCl3 will produce:

0.187 moles AlCl3 × (3 moles Cl2/2 moles AlCl3) = 0.2805 moles Cl2

Now we can use the ideal gas law to calculate the volume of Cl2 gas produced. We need to convert the temperature from Celsius to Kelvin by adding 273.15.

PV = nRT

V = nRT/P

V = (0.2805 mol) × (0.0821 L·atm/mol·K) × (301.15 K) / (750 mmHg × 1 atm/760 mmHg)

V = 0.0085 L or 8.5 mL (rounded to two significant figures)

Therefore, approximately 8.5 mL of chlorine gas can be produced from the decomposition of 25 g of aluminum chloride at 28°C and 750 mmHg.

Note that the point at which oxygen changes from liquid to gas is 90k. See the attached graph.

To plot the data, we can use a line graph with temperature (T) on the x-axis and density (d) on the y-axis. Here is a plot of the data:

From the plot, we can see that the density of oxygen decreases as the temperature increases. At around 90 K, there is a significant drop in density, indicating a change in state from liquid to gas. We can circle this temperature as the point at which oxygen changes from liquid to gas.

Therefore, we can circle the temperature 90 K as the point at which oxygen changes from liquid to gas.

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The number of formula units is 4.5 * 10^23 formula units. This was obtained from the number of moles given in the question.

To find the number of formula units from the moles of a compound, you need to know the Avogadro's number, which is a fundamental constant that relates the number of particles in a mole of a substance. Avogadro's number is approximately 6.02 x 10^23 particles per mole.

Once you know the Avogadro's number, you can use the following formula to find the number of formula units:

Number of formula units = number of moles x Avogadro's number

We know that;

1 mole would contain 6.02 * 10^23 formula units

0.75 moles will contain 0.75 *  6.02 * 10^23 /1

= 4.5 * 10^23 formula units

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Considering the Boyle's law, the pressure will be 5693.998 mmHg if the volume is changed to 23 L if the molar mass and temperature are held constant.

Boyle's law states that the pressure of a gas in a closed container is inversely proportional to the volume of the container, when the temperature is constant and is expressed mathematically as:

P×V= k

where

Considering an initial state 1 and a final state 2, it is fulfilled:

P₁×V₁= P₂×V₂

In this case, you know:

Replacing in Boyle's law:

25 atm× 19 L= P₂× 23 L

Solving:

(25 atm× 19 L)÷ 23 L= P₂

20.65 atm= 15693.998 mmHg= P₂ (being 1 atm= 760 mmHg)

Finally, the pressure will be 5693.998 mmHg.

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The term that describes the application of water to farmland from a source such as a lake or river is "irrigation."

What is Irrigation?

Irrigation is the process of artificially supplying water to crops or plants to promote their growth and development. It involves the application of water to agricultural land using various techniques, such as sprinklers, drip systems, or flood irrigation. The primary purpose of irrigation is to supplement the natural rainfall that is insufficient or irregular in certain regions, allowing farmers to grow crops in areas that would otherwise be unsuitable for farming. Irrigation systems can be designed to deliver the required amount of water directly to the roots of plants, which can increase crop yields and improve the quality of the produce. However, overuse or mismanagement of irrigation can lead to waterlogging, soil salinization, and other environmental problems.

Irrigation is the artificial application of water to land for the purpose of agricultural production. It is a critical practice in areas where rainfall is insufficient or unreliable, as it provides a reliable source of water for crops to grow. Irrigation systems can vary widely depending on the type of crops being grown, the availability of water, and the topography of the land.

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Approximately 13836 grams (or 13.8 kg) of liquid water is required to absorb 3.12×10^4 kJ of heat energy on boiling.

To find the mass of liquid water required to absorb 3.12×10^4 kJ of heat energy on boiling, we need to use the following formula:

q = m * ΔH

Where

The enthalpy of vaporization of water is 40.7 kJ/mol.

To convert kJ to J, we multiply by 1000:

q = 3.12×10^4 kJ = 3.12×10^7 J

Substituting the values, we get:

3.12×10^7 J = m * (40.7 kJ/mol)

To solve for the mass of water, we need to first convert the enthalpy of vaporization to J/g:

40.7 kJ/mol = 40.7×10^3 J/mol

The molar mass of water is 18.015 g/mol, so we can calculate the enthalpy of vaporization per gram:

40.7×10^3 J/mol / 18.015 g/mol = 2257 J/g

Substituting this value, we get:

3.12×10^7 J = m * (2257 J/g)

Solving for m, we get:

m = 3.12×10^7 J / (2257 J/g)

m ≈ 13836 g

Therefore, approximately 13836 grams (or 13.8 kg) of liquid water is required to absorb 3.12×10^4 kJ of heat energy on boiling.

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Answer:

The attraction of water molecules to other substances, like soil or glass, is called adhesion. As drops of water are added onto a penny, the adhesive force between the water and the penny keeps the water from falling off.

Explanation:

The formation of a fluid bubble on a penny is an example of cohesion, not adhesion.

When a penny is wetted with a small amount of water, the water molecules are attracted to each other by cohesive forces, which are intermolecular forces that bind molecules of the same substance together. As a result, the water molecules tend to stick to each other rather than to the surface of the penny, forming a rounded shape or a "bubble".

The cohesive forces between water molecules are strong enough to overcome the gravitational force acting on the small volume of water on the penny, which is why the water does not run off the penny. This phenomenon is also known as surface tension, which is the cohesive force that acts between molecules at the surface of a liquid.

In contrast, adhesion refers to the intermolecular forces that bind different substances together, such as the attraction between water molecules and a surface. If the adhesive forces between water and the penny were stronger than the cohesive forces between water molecules, the water would spread out over the surface of the penny, rather than forming a bubble. However, in the case of the penny and water, the cohesive forces between water molecules are stronger than the adhesive forces between water and the penny, resulting in a fluid bubble.

Answer:

C. Females choose mates based in the brightness of the coloration of males within the population

Explanation:

Natural selection occurs when individuals with certain genotypes are more likely than individuals with other genotypes to survive and reproduce, and thus to pass on their alleles to the next generation.

Pressure is independent variable and volume is dependent variable. During the investigation, the temperature and quantity of gas are kept constant.

Boyle's law, also known as the Boyle-Mariotte law or Mariotte's law, seems to be an observational gas law that specifies the connection between confined gas pressure and volume.

If the temperature as well as quantity of gas stay constant within a closed system, the absolute pressure applied by a constant amount of an ideal gas seems to be inversely correlated with the volume it fills. Pressure is independent variable and volume is dependent variable.

Therefore, pressure is independent variable and volume is dependent variable. During the investigation, the temperature and quantity of gas are kept constant.

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Burning 1000 grams of gasoline results in about 2.3 kilograms (5.1 pounds) of carbon dioxide.

One carbon atom and two oxygen atoms make up the odorless, naturally occurring gas known as carbon dioxide (CO2). The atmosphere of Earth contains most of it, which makes up roughly 0.04 percent of the air there.

Moreover, the respiration of animals, the burning of fossil fuels, and the fermentation of carbohydrates in beer and wine all produce carbon dioxide as byproducts.

A crucial component of the carbon cycle that occurs naturally on Earth and influences climate is carbon dioxide. Animals breathe out carbon dioxide whereas plants absorb it during photosynthesis.

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Answer:

0.67752kg

Explanation:

Mole ratio of LiOH to Li3N

=n(LiOH)/n(Li3N

=3/4

The mass of copper (ii) nitrate formed is 469 g Cu(NO₃)₂

The balanced chemical equation for the reaction between copper and silver is as follows:

From the equation, the mole ratio of Ag and  Cu(NO₃)₂ is 2 : 1

5.0 moles Ag × 1 mole Cu / 2 moles Ag = 2.5 moles Cu

2.5 moles Cu × 1 mole Cu(NO3)2 / 1 mole Cu = 2.5 moles Cu(NO₃)₂

The mass of 2.5 moles Cu(NO₃)₂ = 2.5₂ × 187.56 g/mol

Mass of copper (ii) nitrate = 469 g Cu(NO₃)₂

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I'm writing to you about an important land use conservation issue that has been gaining attention recently: preserving and protecting public lands.

Issue is a term used to describe an unresolved problem or conflict. It can apply to any area of life, from personal relationships to global politics. An issue can be caused by many different factors, and can be addressed through a variety of methods. In some cases, an issue may be resolved through compromise or negotiation. In other cases, a resolution may require more formal methods, such as a court ruling or a change in a law.

As population growth and development continue to put a strain on our limited public land resources, it is essential that we work to conserve and protect these areas for future generations.
Public lands are used for a variety of important reasons, including recreation, wildlife habitat, timber production, and extractive resource extraction. Unfortunately, these areas are often threatened by development, recreational use, and resource extraction. To alleviate this issue, we need to take steps to protect these lands from further destruction by creating and enforcing regulations that prevent development and resource extraction. Additionally, we need to ensure that these areas are properly managed and maintained so that they can continue to provide a variety of benefits to the public.
There are a variety of ways that individuals can get involved in helping to protect public lands. One way is to join or support local organizations that are actively working to protect these areas. Additionally, individuals can write letters to their representatives to let them know their opinions on land use issues. Finally, individuals can volunteer their time to help with conservation or management efforts at public lands.
I hope you will join me in taking action to protect our public lands. Together, we can ensure that these areas remain available for future generations to enjoy.

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The properties of gas are that  they are easy to compress and they will expend to fill their container as well as they occupy more space then the liquids and solids they originated from.

An imaginary gas which perfectly obeys gas laws is called as an ideal gas. It is a hypothetical gas whose molecules do not occupy any space and have no interactions among themselves.

This is the formula:

P . V = n . R. T

where P respresents the pressure of the gas, the V the volume where the gas is contained and T refers to the absolute T (T° in K)

R is the Universal Gases constant → 8.31 J/K.mol or 0.082 L.atm/mol.

Therefore, The properties of gas are that  they are easy to compress and they will expend to fill their container as well as they occupy more space then the liquids and solids they originated from.

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Element X has an electronegativity of 2. 5 and Y has an electronegativity of 9. X is a metal and Y is a non-metal.

The correct answer is option a.

Element X has a lower electronegativity than Element Y, which means that Element X is a metal and Element Y is a nonmetal.

The capacity of an atom to draw electrons towards itself when it establishes a chemical connection with another atom is measured as electronegativity. It is a fundamental feature of atoms and is commonly measured on the Pauling scale, which provides numerical values ranging from 0.7 (for the least electronegative element, cesium) to 4.0 (for the most electronegative element, uranium) (for the most electronegative element, fluorine).

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Answer:

The presence of a brightly colored, detachable tail can be advantageous for some lizards because it serves as a distraction or decoy for predators. When a predator attacks, the lizard can quickly detach its tail, which wriggles and continues to move for a short period of time. This sudden movement can divert the predator's attention away from the lizard's body, allowing the lizard to escape.

The bright coloration of the tail can also help to draw the predator's attention towards it, instead of the lizard's body. Bright colors are often used in the animal kingdom as warning signals, indicating that an animal is toxic or dangerous. While the lizard may not necessarily be toxic or dangerous, the bright colors of its tail can create a similar effect, deterring predators from attacking in the first place.

Additionally, the detachable tail can serve as a form of self-defense, allowing the lizard to escape from a predator's grasp. By detaching its tail, the lizard can leave the predator with a distraction while it makes its escape. Over time, the lizard can regrow its tail, allowing it to continue to use this defense mechanism in the future.