Why do you need to make an ice water slush mixture (instead of only ice) in order to calibrate your thermometer at 0°c?

Answer:

Sequence will be:

NaCl

Na₂SO₄

Na₂S

Explanation:

The silver ions get precipitated on addition of chloride ion as silver chloride.

So we will add NaCl in the first step.

The following reaction will occur.

[tex]Ag^{+}+Cl^{-}--->AgCl(s)[/tex]

Lead and nickel are soluble in sodium chloride (lead chloride and nickel chloride).

[tex]Pb^{+2}[/tex] will get precipitated as lead sulfate and nickel will remain soluble as nickel sulphate is soluble in water.

The reaction will be:

[tex]Pb^{+2}+2SO_{4}^{-2}--->PbSO_{4}(s)[/tex]

Then nickel will be precipitated as sulfide.

The reaction will be:

[tex]Ni^{+2}+2Cl^{-} ---->NiCl_{2}(s)[/tex]

Answer:

The charge will be +2.

Explanation:

The atomic number of Mg is 12, so it has 12 protons.

The neutral atom of Mg has 12 electrons.

When an atom loses electrons it acquire positive charge.

The charge developed is equal to the number of electrons removed.

So the charge developed will be +2.

The equation will be:

[tex]Mg--->Mg^{+2}+2e[/tex]

A negative charge is developed when atom accepts electrons.

After one half-life (10 seconds), 8 grams of krypton-91 will remain. After 50 seconds (or 5 half-lives), only 0.5 grams will be left.

The question pertains to the concept of half-life in radioactive decay. Half-life is the time taken for half of the radioactive element to decay. With a half-life of 10 seconds, krypton-91 follows an exponential decay pattern. For example, if you start with 16 grams of krypton-91, after one half-life (10 seconds), half of it will decay, leaving you with 8 grams of krypton-91.

After 50 seconds or five half-lives, the remaining krypton-91 would be 16g * (1/2)^5 = 0.5 grams. It is important to note that the radioactive atoms don't disappear but are replaced by their decay products or daughter elements.

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The correct way to write the title of a poem is by enclosing it in quotation marks, making option (a) "Afternoon on a Hill" the correct formatting for a handwritten poem title.

When formatting the title of a poem in writing, it should either be enclosed in quotation marks or italicized if typed, depending on the style guide being used. The three options given for the poem title 'Afternoon on a Hill' vary in formatting. Based on standard English conventions for titling creative works such as poems, the handwritten version of the poem title would be formatted using either quotation marks or italicization.

Therefore, the correct answer is option (a) "Afternoon on a Hill" as it follows the guideline of using quotation marks for the title of shorter works such as poems. Option (b) and option (c) are missing the necessary punctuation or formatting emphases that set apart the titles of creative works from the rest of the text.

The reason why distilled water is being added to the crucible after having It to be ignited with the magnesium ribbon is mainly because it is needed to decompose the magnesium nitride to produce a more better result in the experiment and prevent it from reacting more vulgar such as having it to explode.

Answer:

To decompose the Mg3N and release ammonium gas

Explanation:

Distilled water is the pure state of water, without mixing with other substances and microorganisms. It is obtained through the distillation process. Even though it is clean water, it is not suitable for consumption, however it can have several other applications, such as being added to the crucible after ignition of the magnesium metal, because it allows the decomposition of Mg3N and release of ammonium gas, avoiding the emergence of explosions.

The answers are ; tension, compression, and shear respectively

Normal faults are formed when the two crust are moving away from each other and the hanging wall block moves downwards due to gravity.

In reverse faults, the two crusts move towards each other hence producing compressional force. This causes the hanging wall block to move up with respect to the footwall block

In strike-slip faulting, the two crusts move across each other resulting in shear stress and causing a dip feature.

Normal faults are caused by tensional stress, reverse faults are formed by compressional stress, and strike-slip faults are formed by shear stress usually at divergent, convergent and transform boundaries respectively.

Normal faults form due to tensional stress, which is when the crust is being pulled apart. This generally happens in divergent plate boundaries. On the other hand, reverse faults form due to compressional stress, where the crust is being pushed together, which generally occurs at convergent plate boundaries. The third category, strike-slip faults are formed because of shear stress, when different parts of the crust slide past each other in opposite directions, which usually occurs at transform boundaries.

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Final answer:

The polarity of a lipid molecule is influenced by its structure with a hydrophilic polar head and hydrophobic nonpolar tails, making it amphipathic, which explains its behavior in aqueous environments.

Explanation:

The polarity of lipid molecules is determined by their structure, which includes both polar and nonpolar parts. A typical phospholipid molecule has a polar phosphate head that is hydrophilic, meaning it is attracted to water, and nonpolar fatty acid tails that are hydrophobic, meaning they repel water and prefer to not be in contact with it. Phospholipids are amphipathic because they have these dual characteristics. Unsaturated fatty acids in the tails can create kinks that contribute to the fluidity and function. In water, phospholipids tend to arrange themselves into various structures like micelles, liposomes, or bilayers, with hydrophilic heads facing water and hydrophobic tails hidden away.

The minimum volume of 0.200 M potassium iodide required to completely react with 155.0 mL of 0.112 M lead nitrate is 173.6 mL. The larger volume is needed due to the 2:1 stoichiometry in their reaction equation, resulting in a yellow precipitate of lead iodide.

This question is about a precipitation reaction between potassium iodide and lead (II) nitrate. The reactant in a solution will react until it is entirely consumed, forming a solid precipitate called lead iodide. As given by the balanced chemical equation, 2KI(aq) + Pb(NO3)2(aq) → PbI2(s) + 2KNO3(aq), one molecule of lead nitrate reacts with two molecules of potassium iodide. Because all the reagents are in solution, we calculate amounts in moles using their molarities (M) and volumes (L).

Let's denote the required volume of potassium iodide solution as 'V'. Therefore, the number of moles in the required potassium iodide solution would be (0.200 M * V). Similarly, the number of moles in the given volume of lead nitrate solution is (0.112 M * 155.0 mL = 0.01736 moles). Since the reaction ratio is 2:1, we need twice the amount of potassium iodide for each mole of lead nitrate. Consequently, 2 * 0.01736 moles of potassium iodide are required. Solving the equation 0.200 M * V = 2 * 0.01736,  gives the minimum volume 'V' required as 0.1736 L or 173.6 mL.

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Final answer:

Metals experience plastic deformation when stress is applied beyond their elastic limit. Unlike rubber-like materials, metals show a gradual decrease in stress with increasing strain, making them malleable and ductile.

Explanation:

Metals experience plastic deformation when stress is applied beyond their elastic limit. Plastic deformation is an irreversible change in the shape and size of a material, even when the load is removed. Unlike rubber-like materials that become more difficult to stretch and eventually break, metals show a gradual decrease in stress with increasing strain, making them malleable and ductile.

When stress is applied to a metal, the free-flowing electrons can slip between the stationary cations and prevent them from coming into contact. This allows the metal to deform without breaking and enables processes like hammering into shapes, rolling into thin sheets, or pulling into thin wires.

A cubic piece of metal measures 6.00 cm on each edge. If the metal is nickel, whose density is 8.90 g/cm3, then the mass of the cube would be 1922.4 grams.

It can be defined as the mass of any object or body per unit volume of the particular object or body. Generally, it is expressed as in gram per cm³ or kilogram per meter³.

By using the above formula for density

ρ = mass / volume

As given in the problem a cubic piece of metal measures 6.00 cm on each edge. If the metal is nickel, whose density is 8.90 g/cm³, then we have to find out the mass of the cube,

the edge of the cube = 6 centimeters

the volume of the cube = 6³ centimeter³

                                 = 216 centimeter³

density = mass  /volume

8.90 g/cm³=mass  /216  cm³

mass of the cube = 216×8.90

mass of the cube = 1922.4 grams

Thus, the mass of the cube comes out to be 1922.4 grams

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Final answer:

To find the mass of the nickel cube, calculate the volume (216 cm³) and then multiply by the density of nickel (8.90 g/cm³), giving a mass of 1922.4 grams.

Explanation:

The student is asking about how to calculate the mass of a metal cube given the edge length and the density of the material, which in this case is nickel. To find the mass, you need to calculate the volume of the cube and then multiply by the density of nickel.

First, calculate the volume of the cube using the formula for the volume of a cube: V = edge length3. Here, the edge length is 6.00 cm, so V = 6.00 cm x 6.00 cm x 6.00 cm = 216.00 cm3.

Next, use the density of nickel which is 8.90 g/cm3 to find the mass: mass = density x volume. Substituting the values in gives you mass = 8.90 g/cm3 x 216.00 cm3 = 1922.4 grams.

The amount of energy need to melt 25.4 grams of iodine, I₂ is 1.57×10³ Joules

How to calculate the amount of energy needed to to melt the the iodine, I₂?

The following useful information were given from the question:

The amount of energy need to melt 25.4 grams of iodine, I₂ can be calculated as shown below:

Heat energy needed (Q) = Mass (m) × Latent heat of fusion (Hf)

= 25.4 grams × 61.7 J/g

= 1.57×10³ Joules

Thus, the amount of heat energy needed to melt the iodine,I₂ is 1.57×10³ Joules

To measure and add 50 mL of a stock solution, a volumetric pipette or graduated cylinder should be used for accuracy and precision in chemical laboratory work, as volumetric flasks are not suitable for measuring out volumes other than their calibration capacity.

If you need to add 50 mL of a stock solution to a reaction vessel, the most appropriate and precise piece of glassware to use would be ab this case. When dealing with stock solutions, it's important to use glassware that ensures precision to ensure the final concentrations of your solutions are accurate.

When mixing solutions or reagents, accuracy and precision are crucial, especially in a chemical laboratory or medical environment. For instance, preparing an IV solution with a specific concentration involves accurate measurements of the stock solution and addition of the solvent up to a desired volume. Misjudgements in the volume of stock solution added could alter the final concentration of the solution, which could have significant implications, for example, in medical applications.

Answer:

2

Explanation:

Pure chemistry involves the study of the basic principles and theories of chemistry while applied chemistry uses these principles to solve real-world problems or develop new products. They are interconnected in the sense that advancements in pure chemistry can lead to new opportunities in applied chemistry and vice versa.

The relationship between pure chemistry and applied chemistry is similar to that of theory and practice. Pure chemistry, also known as basic chemistry, is the study of the basic principles and theories of chemistry for the sake of knowledge itself. It seeks to understand the fundamental principles that explain how matter behaves and interacts. Examples include studying chemical reactions, the properties of elements, and how atoms form compounds.

On the other hand, applied chemistry utilizes these principles to solve real-world problems or develop new products. For instance, an applied chemist might work on creating new material, developing new drugs, improving environmental sustainability, or advancing food science.

In essence, applied chemistry is an application of pure chemistry. Both fields are interconnected; advancements in pure chemistry can lead to new opportunities in applied chemistry and vice versa.

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Final answer:

By applying stoichiometry and molar mass conversions, it is determined that heating 87.4 grams of KClO₃(s) will produce 34.24 grams of O₂(g).

Explanation:

Calculating Grams of Oxygen Gas from Potassium Chlorate Decomposition

To determine how many grams of O₂(g) can be produced by heating 87.4 grams of KClO₃(s), we need to understand the stoichiometry of the chemical reaction involved. The balanced chemical equation for the decomposition of potassium chlorate (KClO₃) is:

2 KClO₃(s) → 2 KCl(s) + 3 O₂(g)

Using the molar masses: 1 mol KClO₃ = 122.55 g/mol and 1 mol O₂ = 32.00 g/mol, we can calculate the amount of oxygen gas produced from the given mass of potassium chlorate.

Convert the mass of KClO₃ to moles:

(87.4 g KClO₃) × (1 mol KClO₃ / 122.55 g KClO₃) = 0.713 moles of KClO₃

Use the stoichiometry of the reaction to find moles of O₂ produced:

(0.713 moles KClO₃) × (3 moles O₂ / 2 moles KClO₃) = 1.070 moles of O₂

Convert moles of O₂ to grams:

(1.070 moles O₂) × (32.00 g/mol O₂) = 34.24 grams of O₂

Hence, 34.24 grams of O₂ can be produced from heating 87.4 grams of KClO₃(s).

During chemical change and the chemical property ripen banana which involve in a different steps like  change in color of peel from green to yellow then to brown, in second step change in taste become more sweeter as they begin to ripen.

Chemical properties of the substance which can be measured when the  substance undergoes chemical change where as the Physical properties of the substance include without involvement of any chemical change.

A chemical reaction conducted to show the chemical property where as for the determination of physical property of a substance no chemical reaction occur.

In Chemical properties the compounds are formed by chemical bonds  while in Physical properties the compounds do not give any relationship.

chemical property used to detect how substances react while physical property used in identifying or describing the substance.

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There are 10,080 minutes in one week. To calculate the number of minutes in one week, multiply the number of minutes in an hour (60) by the number of hours in a day (24), and then multiply that result by the number of days in a week (7).

To calculate the number of minutes in one week using unit conversion, you first need to know how many minutes are in an hour, how many hours are in a day, and how many days are in a week. There are 60 minutes in an hour. In each day, there are 24 hours. Therefore, in one day, there are  60 x 24 = 1440 minutes. A week consists of 7 days, so to find out the number of minutes in a week, you would do 1440 x 7 = 10,080. So, there are 10,080 minutes in one week.

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We take as a basis for solving this item, 100 g of sample. If 15.77% of the sample is carbon, we solve for the amount of carbon in the sample,

    Carbon = (100 g)(0.1577)  = 15.77

Then, we solve for the amount sulphur in the sample by,

    Sulfur = (100 g)(1 – 0.1577) = 84.23 g

 Next, we solve for the number of moles of the elements by dividing the calculated masses by the molar mass.

 Carbon = (15.77g)(1 mol/12 g) = 1.3 moles

 Sulphur = (84.23 g)(1 mol/32 g) = 2.63 moles

 From the ratio of the calculated number of moles, we can say that each mol of carbon will have to be paired up with two other sulphur atoms. Thus, the shape of the molecule is LINEAR. 

Final answer:

Phosphate group in phospholipids contributes through nonpolar avoidance of water, negative charge for water interaction, and providing bonding sites for adjoining phospholipids.

Explanation:

The phosphate group contributes to the structure of a phospholipid in the following ways:

Nonpolar group that avoids water: The fatty acid tails are nonpolar and hydrophobic, which provides stability and structure to the phospholipid bilayer.

Negative charge to interact with water: The phosphate group is negatively charged, making it hydrophilic and allowing it to interact with water molecules.

Place where bonds can form between adjoining phospholipids: The phosphate groups can form bonds with adjacent phospholipids, contributing to the formation of the lipid bilayer.

Answer:

[tex]Kg/cm^3[/tex]

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

[tex] Kg/L[/tex]

[tex]g/m^3[/tex]

Explanation:

We know that density is defined as the mass per unit volume

[tex]Density=\frac{Mass}{volume}[/tex]

When mass in gram and volume in cubic centimeter

Then units of density is[tex]g/cm^3[/tex]

When mass is given in Kg and volume given in litre then unit of density

[tex] Kg/L[/tex]

When mass is given in gram and volume in meter then units of density is given by [tex]g/m^3[/tex]

When mass is given in kilogram and volume is given in cubic centimeter

Then, units of density is given by [tex]Kg/cm^3[/tex]