Water molecules are dipolar because the more electronegative oxygen atom attracts electrons away from the hydrogen atoms, creating a charge imbalance within the molecule. The bent shape of water molecules prevents the cancellation of these local dipoles, resulting in a net dipolarity that enables water to engage in hydrogen bonding and dissolve ionic compounds.
Water molecules are dipolar due to the unique arrangement and electrical properties of their constituent atoms. The molecule of water consists of one oxygen atom and two hydrogen atoms. Oxygen, being more electronegative, draws the shared electrons from the hydrogen atoms towards itself more strongly.
This electron shift results in a partial negative charge on the oxygen atom and a partial positive charge on the hydrogen atoms, creating a polarity in the molecule. Additionally, due to water's bent shape, with an H-O-H angle of approximately 104.45°, these individual bond polarities do not cancel out as they might in a symmetrical molecule. Instead, they reinforce each other, leading to a significant molecular dipole where the molecule has an uneven distribution of charge—oxygen being anionic and hydrogen being cationic.
This dipolarity allows water to form hydrogen bonds with other water molecules or interact with ions, facilitating the dissolution of ionic compounds in water. In essence, the conditions that make water dipolar are its asymmetry and the varying electronegativity of oxygen and hydrogen atoms.
What mass of HCl is contained in 45.0 mL of an aqueous HCl solution that has a density of 1.19 g cm–3 and contains 37.21% HCl by mass?
Final answer:
To find the mass of HCl in a 45.0 mL aqueous solution with a specific density and concentration, the volume is converted to mass using the given density, and then the mass of HCl is calculated based on its percentage concentration, resulting in 19.93 g of HCl.
Explanation:
The question asks to find the mass of HCl contained in 45.0 mL of an aqueous HCl solution with a density of 1.19 g cm–3 and a concentration of 37.21% HCl by mass. First, we convert the volume of the solution to mass using the given density. Calculating the mass of the solution: 45.0 mL × 1.19 g/mL = 53.55 g. Next, to find the mass of HCl, we use the percentage concentration of HCl in the solution. Calculating the mass of HCl: 53.55 g × 0.3721 = 19.93 g. Therefore, the mass of HCl in the 45.0 mL solution is 19.93 g.
What is the name of an isotope with 23 protons and 25 neutrons?
What happens if you cool the crystallization solution in a container of ice that is too big?
G.com what is the mass of a gold bar that is 7.379 × 10–4 m3 in volume
Na→Na++− Express your answer as a particle or a chemical formula.
The process of Na→Na++ represents a sodium atom (Na) losing an electron to become a positively charged sodium cation (Na+). This can be a part of a reaction such as 2NaCl(aq) + 2H2O(l) -> 2NaOH(aq) + H2(g) + Cl2(g). The net ionic equation for this reaction is 2H2O(l) -> H2(g) + Cl2(g).
Explanation:The chemical formula Na→Na++ indicates a sodium atom losing an electron to become a sodium cation with a positive charge. This is a part of a redox reaction that might occur in a chemical formula such as when sodium chloride (NaCl) reacts with water (H2O) to produce sodium hydroxide (NaOH), hydrogen gas (H2), and chlorine gas (Cl2).
The balanced molecular equation would be: 2NaCl(aq) + 2H2O(l) -> 2NaOH(aq) + H2(g) + Cl2(g)
The complete ionic equation would be: 2Na+(aq) + 2Cl−(aq) + 2H2O(l) -> 2Na+(aq) + 2OH−(aq) + H2(g) + Cl2(g)
The net ionic equation, which only focuses on the species that actually change and react, would thus be: 2H2O(l) -> H2(g) + Cl2(g)
Learn more about Chemistry Equations here:https://brainly.com/question/14945213
#SPJ12
Calculate the mass (in g) of 2.1 x 1024 atoms of W.
The mass of [tex]\( 2.1 \times 10^{24} \)[/tex] atoms of tungsten (W) is [tex]641.03 \text{ g}} \)[/tex].
To calculate the mass of [tex]\( 2.1 \times 10^{24} \)[/tex] atoms of tungsten (W), we'll follow these steps:
1. Find the molar mass of tungsten (W):
The molar mass of tungsten (W) is approximately [tex]\( 183.84 \)[/tex] g/mol.
2. Convert atoms to moles:
Use Avogadro's number to convert the number of atoms to moles:
[tex]\[ \text{Number of moles} = \frac{\text{Number of atoms}}{\text{Avogadro's number}} \][/tex]
Avogadro's number is [tex]\( 6.022 \times 10^{23} \)[/tex] atoms/mol.
[tex]\[ \text{Number of moles} = \frac{2.1 \times 10^{24}}{6.022 \times 10^{23}} \]\[ \text{Number of moles} = 3.487 \text{ moles} \][/tex]
3. Calculate the mass:
Now, multiply the number of moles by the molar mass to find the mass in grams:
[tex]\[ \text{Mass} = \text{Number of moles} \times \text{Molar mass} \]\[ \text{Mass} = 3.487 \text{ moles} \times 183.84 \text{ g/mol} \]\[ \text{Mass} = 641.03 \text{ g} \][/tex]
Therefore, the mass of [tex]\( 2.1 \times 10^{24} \)[/tex] atoms of tungsten (W) is [tex]641.03 \text{ g}} \)[/tex].
which statement describes a homogeneous mixture
What is the ratio of [a–]/[ha] at ph 3.75? the pka of formic acid (methanoic acid, h–cooh) is 3.75?
At pH 3.75, the ratio of [tex]\frac{[A^-]}{[HA]}\right)[/tex] for formic acid ([tex]pK_a[/tex] = 3.75) is 1.
To find the ratio of the concentrations of the conjugate base [A⁻] to the acid [HA] for formic acid (HCOOH) at pH 3.75, we can use the Henderson-Hasselbalch equation:
[tex]\text{pH} = \text{p}K_a + \log\left(\frac{[A^-]}{[HA]}\right)[/tex]Given that the pH is 3.75 and the [tex]pK_a[/tex] of formic acid is also 3.75, we can set up the equation as follows:
[tex]3.75 = 3.75 + \log\left(\frac{[A^-]}{[HA]}\right)[/tex]Subtract 3.75 from both sides:
[tex]0 = \log\left(\frac{[A^-]}{[HA]}\right)[/tex]To solve for the ratio [tex]\frac{[A^-]}{[HA]}\right)[/tex], we need to exponentiate both sides with base 10:
[tex]10^0 = \frac{[A^-]}{[HA]}[/tex]Therefore:
[tex]\frac{[A^-]}{[HA]}\right) = 1[/tex]This result makes sense because when the pH of the solution is equal to the [tex]pK_a[/tex] of the acid, the concentrations of the acid and its conjugate base are equal. Consequently, the ratio is exactly 1.
what is the molarity of sucrose if 150.0 g is dissolved in 250.0 mL of solution
The iupac name for ch3–ch2–c ≡ c–ch3 is ________
Final answer:
The IUPAC name for CH3–CH2–C ≡ C–CH3 is 3-hexyne.
Explanation:
The IUPAC name for CH3–CH2–C ≡ C–CH3 is 3-hexyne.
In this compound, the longest carbon chain contains six carbons, so it is called a hexyne. The triple bond is between the third and fourth carbon, so the name includes the prefix 3-
0.036549 round to three sig figs
Answer:
0.0365
Explanation:
Given number,
0.036549,
In the above number there are 5 significant figures (i.e. 3, 6, 5, 4 and 9)
When we round a decimal number to 3 significant figure we check the fourth significant number after decimal,
if it is 5 or more than 5 then the number is rounded next significant figure it rounded to previous significant figure,
Here, the fourth significant number after decimal = 4
Thus, 0.036549 ≈ 0.0365 ( rounded to 3 significant figure )
Which of the solutions have greatest osmotic pressure 30% sucrose 60% sucrose or 30% magnesium sulfate?
Final answer:
The solution with the greatest osmotic pressure depends on the total concentration of solute particles. While a 60% sucrose solution has a high concentration, the dissociation of magnesium sulfate in a 30% solution increases its total solute particle concentration, potentially giving it a higher osmotic pressure when considering its van 't Hoff factor.
Explanation:
The question asks which of the solutions has the greatest osmotic pressure: 30% sucrose, 60% sucrose, or 30% magnesium sulfate. Osmotic pressure is directly proportional to the concentration of solute particles in a solution. While a higher percentage indicates a more concentrated solution, the key factor in determining osmotic pressure is the number of solute particles in solution, not just the concentration of the solution itself.
Sucrose is a non-electrolyte and does not dissociate in water, meaning a 30% or 60% sucrose solution will provide a straightforward concentration of molecules. Magnesium sulfate, on the other hand, is an electrolyte and will dissociate into magnesium and sulfate ions, effectively increasing the number of solute particles in the solution.
Therefore, even though the sucrose solution at 60% is more concentrated than the 30% magnesium sulfate solution, the dissociation of magnesium sulfate into ions means that the 30% magnesium sulfate solution may actually have a greater total concentration of solute particles, leading to a higher osmotic pressure. However, to accurately determine which solution has the highest osmotic pressure, one must consider the molar concentration of particles (ions for magnesium sulfate and molecules for sucrose) and the van 't Hoff factor (i), which accounts for the dissociation of ions in solution.
48.5 moles of P4O10 contains how many moles of P
There are 194 moles of phosphorus in 48.5 moles of P4O10 because each molecule of P4O10 contains 4 phosphorus atoms.
Explanation:To calculate the number of moles of phosphorus (P) in 48.5 moles of P4O10, we must understand the molar relationship between P4O10 and P. The molecule P4O10 has a composition of 4 phosphorus atoms to 10 oxygen atoms. This means that in every mole of P4O10, there are 4 moles of phosphorus atoms because the subscript '4' in P4 indicates that there are 4 phosphorus atoms in each molecule.
Using this stoichiometric ratio, the calculation is straightforward:
Number of moles of P = 4 imes Number of moles of P4O10
Number of moles of P = 4 imes 48.5 moles
Number of moles of P = 194 moles
Therefore, 48.5 moles of P4O10 contains 194 moles of phosphorus (P).
If your lawn is 21.0 ft wide and 20.0 ft long, and each square foot of lawn accumulates 1350 new snow flakes every minute. How much snow (in kilograms) accumulates on your lawn per hour? Assume an average snow flake has a mass of 1.60 mg.
In a certain grocery store, strawberries cost $4.16 per pound ( 4.16 dollars/lb ). What is the cost per ounce?
Why does calcium chloride weigh more when exposed to air?
A certain ore is 37.3% nickel by mass how many kilograms of this ore would you need to dig up to have 10.0g of nickel
What is the charge on a hypothetical ion with 85 protons and 82 electrons?
On an activity series chlorine is more active than bromine. what is a balanced chemical equation for the reaction between chlorine gas and aqueous sodium bromide?
please help me dont just comment for points please i actually need help
Order the relative rate of diffusion of the following gases from slowest to fastest.
1. 1 Ar
2. 2 Ne
3. 3 N
4. 4 Kr
Answer:
Kr < Ar < Ne < N (N is fastest and Kr is slowest)
Explanation:
According to graham law of diffusion, rate of diffusion of a gas is inversely proportional to the square root of molar mass of the gas.
[tex]R\propto \frac{1}{\sqrt{M}}[/tex]
Where R is rate of diffusion and M is molar mass
Molar masses of given gases are - Ar(40 g/mol), Ne(20 g/mol), N(14 g/mol) and Kr(84 g/mol)
So molar mass order : Kr > Ar > Ne > N
Hence rate of diffusion order: Kr < Ar < Ne < N (N is fastest and Kr is slowest)
A substance with a density of 2.70 g/ml occupies a volume of 21.3 ml. what is the mass of the sample
a scientist has developed a new type of material that is suppose to float on water. this material has a mass of 2.0g for every 3.0cm3 of volume. will this material float on water (density= 1.0g/cm3) explain
Final answer:
The material, with a density of 0.67g/cm³, will float on water since its density is less than water's density of 1.0g/cm³. This is determined by dividing its mass by its volume and comparing it to water's density.
Explanation:
The question asks whether a new material with a mass of 2.0g and volume of 3.0cm3 will float on water, which has a density of 1.0g/cm3. To determine whether this material will float, we calculate its density using the formula density = mass / volume. Plugging in the given values, we find the density of the material to be 2.0g / 3.0cm3 = 0.67g/cm3.
Since the density of the material (0.67g/cm3) is less than the density of water (1.0g/cm3), the material will float on water. This is explained by the principle of buoyancy, which states that an object will float in a fluid if its density is less than the density of the fluid.
Lithium carbonate, li2co3, contains 18.8 % lithium and is used in the treatment of mental illnesses such as bipolar disorder. what mass of lithium is present in a 1.70−g dose of lithium carbonate?
In a 1.70-g dose of lithium carbonate, which contains 18.8% lithium, there is approximately 0.3196 g of lithium.
Explanation:The question is asking for the amount of lithium in a 1.70-g dose of lithium carbonate (Li2CO3) which is known to contain 18.8% lithium. The calculation is fairly straightforward once we understand that the percentage given is by mass. Hence, to find out the lithium content, we simply multiply the total mass of the dose by the percentage of lithium.
Step 1. Convert the lithium percentage to a decimal by dividing 18.8 by 100, giving us 0.188.
Step 2. Multiply the mass of the lithium carbonate dose (1.70 g) by the decimal from Step 1. The calculation is: 1.70 g × 0.188 = 0.3196 g.
The result indicates that in a 1.70-g dose of lithium carbonate, there is approximately 0.3196 g of lithium.
Learn more about Lithium in Lithium Carbonate here:https://brainly.com/question/5596184
#SPJ12
To find the mass of lithium in a 1.70-g dose of lithium carbonate, multiply the mass by the percentage of lithium content (18.8%). This calculation results in 0.3196 grams of lithium.
Step-by-Step Solution
First, identify the percentage of lithium in lithium carbonate: 18.8%.Next, calculate the mass of lithium in the given dose using the percentage formula:Mass of lithium = (percentage of lithium / 100) * mass of lithium carbonate
Substitute the given values:Mass of lithium = (18.8 / 100) * 1.70 g
Mass of lithium = 0.3196 g
Therefore, there are 0.3196 grams of lithium present in a 1.70-g dose of lithium carbonate.
Which of these best describes the term phospholipid? a a polar lipid molecule that fully interacts with water. b a nonpolar lipid molecule that is made amphipathic by the addition of a phosphate. c a nonpolar lipid molecule that is made polar by the addition of a phosphate. d a polar lipid molecule that fully repels water?
Chromatography Portfolio
5. What evidence is there that marker ink is a mixture?
6. Each compound in the marker ink is represented by a color. Did one compound travel farther than others? Explain why you think that this is the case.
7. Did the compounds travel farther in water or isopropyl alcohol (rubbing alcohol)? Explain why you think that this is the case.
8. How could you improve upon the accuracy of your R[f] measurements?
Answer:
i honestly dont know but ill try
Explanation:
hope this helps its yes
Convert 35 m3 to liters
The Atomic Mass of Al is 26.98154 g/mol. Is it possible to have 5.0 × 10^-25 g of Al? Explain.
It is theoretically possible to have 5.0 × 10⁻²⁵ g of Al, but this is realistically impossible because it is smaller than the mass of a single aluminum atom.
The question asks if it's possible to have 5.0 × 10⁻²⁵ g of aluminum (Al), given that the atomic mass of Al is 26.98154 g/mol. One mole of Al has a mass in grams that is numerically equivalent to its atomic mass. Since the mass of 1 mol of Al is 26.98 g, having a sample of 5.0 × 10⁻²⁵ g is theoretically possible but practically not feasible since this mass represents far less than a single atom of Al. The smallest practical amount of Al one can have is the mass of one atom, which is much more than 5.0 × 10⁻²⁵ g. Hence, 5.0×10⁻²⁵ g of Al is not a meaningful physical quantity because it is significantly less than the mass of one atom, and one cannot have a fraction of an atom.
Which statement best compares the properties of compounds and elements that the compounds contain?
What would likely happen if a hot saturated solution were filtered by vacuum filtration using a büchner funnel? (hint: the mixture will cool as it comes in contact with the büchner funnel.)?
A hot saturated solution, when filtered using a Büchner funnel, may result in the precipitation of the solute as the solution cools down. This is due to the decreased solubility at cooler temperatures.
Explanation:If a hot saturated solution was filtered using vacuum filtration with a Büchner funnel, some of the solutes could precipitate out of the solution as it cools down. This is because the solubility of most solutes decreases as the temperature decreases. Thus, as the hot solution comes in contact with the cooler Büchner funnel and cools down, the solute's ability to remain dissolved lessens, leading to the precipitation of the solute. The precipitate could end up on the filter in the Büchner funnel, potentially clogging it and affecting the filtration process.
Learn more about Solubility here:https://brainly.com/question/31493083
#SPJ3
Vacuum filtration with a Büchner funnel for a hot saturated solution will cause rapid cooling, leading to crystal formation on the filter paper or in the stem, thus clogging the setup.
A crystal formation occurs on the filter paper or in the stem and as a result the setup is clogged.
A hot filtration is essential for filtering solutions that crystallize upon cooling. Vacuum filtration using a Büchner funnel would cause the mixture to cool rapidly. Consequently, crystals would form on the filter paper or in the stem, clogging the setup and reducing yield.To avoid this, ensure the funnel is pre-warmed and maintain a hot temperature during the filtration process.
For each bond, choose δ+ and δ- from the dropdown menu to show the direction of polarity. indicate which bond is expected to be the most polar.
Final answer:
Determining bond polarity involves identifying the direction of the polarity based on electronegativity differences. The atom with higher electronegativity gains a partial negative charge, defining the bond's polarity. The H-F bond is typically the most polar due to a large difference in electronegativity.
Explanation:
The question involves identifying the direction of polarity in chemical bonds and determining which bond is the most polar. Polarity arises when there is a difference in electronegativity between the atoms forming a bond. The atom with higher electronegativity will have a partial negative charge (δ-) and the other a partial positive charge (δ+). To predict the most polar bond, compare the electronegativity values of the atoms involved; the greater the difference, the more polar the bond.
Examples:
H-Cl: Chlorine has higher electronegativity than hydrogen, so it gets δ-, making the bond polar.C-H: Carbon and hydrogen have similar electronegativity values, making this bond less polar compared to others with a greater difference.Generally, bonds involving atoms like fluorine, oxygen, and nitrogen with other less electronegative atoms tend to be highly polar due to the significant electronegativity differences. Thus, among common bonds, the bond between hydrogen and fluorine (H-F) would be expected to be the most polar because of the large electronegativity difference between the two atoms.