The question is incomplete. Here is the complete question.
Consider the selenium atom, Se, and the bromine atom, Br.
Write out the full electron configuration fro each atom.
Se:
Br:
Calculate the Effective Nuclear Charge for each atom. Show all of your work for full credit.
Se:
Br:
Which atom is larger?
Answer and Explanation: Electron Configuration of an atom demonstrates the shape and energy of its electrons. One of the rules used for it is given by using Madelung's Rule, in which the order of increased energy of the electrons is:
1s < 2s < 2p < 3s < 3p < 4s < 4p < 5s < 6s < 4f < 5d < 6p < 7s < 5f < 6d < 7p
Atom of Selenium (Se) has 34 electrons. Its electron configuration is
Se: [tex]1s^{2}2s^{2}2p^{6}3s^{2}3p^{6}4s^{2}3d^{10}4p^{4}[/tex]
Atom of Bromine has 35 electrons. Its electron configuration is
Br: [tex]1s^{2}2s^{2}2p^{6}3s^{2}3p^{6}4s^{2}3d^{10}4p^{5}[/tex]
Effective Nuclear Charge ([tex]Z_{eff}[/tex])is the net positive charge experienced by an electron in a multi-electron atom. In other words, it is the net force that helds nucleus and electrons together.
It is calculated by: [tex]Z_{eff}=Z-S[/tex]
where
Z is the atomic number, i.e., number of protons of the atom
S is the nonvalence electrons, i.e., the number of electrons between the nucleus and the electron in question.
For Selenium (Se):
From the electron configuration, the valence shell is 4 with 6 valence electrons. Nonvalence electrons is the difference between valence and total electrons:
S = 34 - 6 = 28
[tex]Z_{eff}=34-28[/tex] = 6
The Effective Nuclear Charge of Se is 6
For Bromine (Br):
The valence shell, according to the configuration, is 4 and valence electrons are 7.
S = 35 - 7 = 28
[tex]Z_{eff}=35-28[/tex] = 7
The Effective Nuclear Charge fo Br is 7.
Bromine is larger than Selenium because it has bigger Effective Nuclear Charge, which means it held its electrons more loosely and, consequently, has a larger atomic radius.
If 28.0% of a sample of gallium-66 decays in 4.46 hours, what is the half-life of this isotope (in hours)?
Answer:
I hope it will work dear,
Explanation:
by simple mathematical rule,
if 28%=4.46 hrthen we know at half life 50% decay occur hence we get
2. 50% = T 1/2
solving the 2 equations by cross multiplication we will get,
T 1/2= 7.96 hr
THANKS FOR ASKING QUESTION:
If you spill a chemical on a balance and continue to weigh, do you think it will affect your reading
Answer:
It shouldn't, but it might there is a chance. Liquid doesn't really weigh that much but it still can add slight weight.
Explanation:
The chemical could maybe make the balancer move a bit. But not a lot.
Determine if the following compounds will be soluble or insoluble in water?
a) CrPO4
b) Na2S
c) PbBr2
d) Ag2SO4
e) Ca(ClO3)2
f) K3PO4
Answer:
a) Insoluble
b) Soluble
c) Insoluble
d) Insoluble
e) Soluble
f) Soluble
Explanation:
Fill in the [?]:
82 ul = [?]x10^[?] L
Answer:
8.2×10¯⁵ L
Explanation:
82 μL.
We can convert 82 μL to L by doing the following:
To convert from microlitre (μL) to litre(L), we need to know how many microlitre (μL) that makes up a litre (L)
Recall:
1 μL = 1×10¯⁶ L
Therefore,
82 μL = 82 μL × 1×10¯⁶ L/1 μL
82 μL = 8.2×10¯⁵ L
Therefore, 82 μL is equivalent to 8.2×10¯⁵ L
Which compound is more soluble in an acidic solution than in a neutral solution? a) PbBr2 b) CuCl c) AgI d) BaF2
Answer:
d) BaF2
Explanation:
The compound which is more soluble in an acidic solution than in a neutral solution is shown below:-
First we will compare acidic with Neutral
[tex]acidic \rightarrow H+ ions[/tex]
So,
[tex]PbBr2 \rightarrow Pb+2 + 2Br-[/tex]
[tex]BaF2 \rightarrow Ba+2 + 2F-[/tex]
[tex]AgI \rightarrow Ag+ + I-[/tex]
[tex]CuCl \rightarrow Cu+ + Cl-[/tex]
Now, when we add H+ ions, so it will be
[tex]BaF2 \rightarrow Ba+2 + 2F-[/tex]
[tex]F- + H2O <-> HF + OH-[/tex]
Then it will reduces F-, as BaF2 begin to form more aqueous ions, so, it will rises the solubility
For a voltaic cell consisting of Al(s) in Al(NO3)3(aq) and Cu(s) in Cu(NO3)2(aq), what is Ecell, given [Al3 ]
Answer:
2.0 V
Explanation:
For the oxidation half cell;
Al(s) -------> Al^3+(aq) + 3e.
For reduction half cell;
Cu^2+(aq) +2e ------> Cu(s).
E°cell = E°cathode - E°anode
But;
E°cathode= 0.34 V
E°anode = -1.66 V
E°cell= 0.34 -(-1.66)
E°cell= 2.0 V
How does a scientist use observations to help create the
hypothesis in a scientific investigation?
Answer:
They use hypotheses to guess a result based on what they already know. Observations are used to record the results of an experiment. Predictions are used to have an expected outcome of a test, thinking the hypothesis is correct. Experiments are used to test the hypothesis.
are any substance made up of matter and can be natural or man-made.
Answer:
Yes.
Explanation:
Substances are made up of matter or matter are made up of tiny molecules or atoms that occur naturally or some are synthetic or man made.
All matter are made up of substances called elements and each elements have its own physical and chemical properties and cannot be broken easily by ordinary chemical reactions.
Of all the 118 elements only 92 occur naturally and 26 are man made or synthetic which are made in the laboratories.
limitations of bohr
Answer:
Bohr's Atomic model
Explanation:
The limitations of Bohr’s model are Bohr’s model of an atom that could not explain the line spectra of atoms containing more than one electron called multi-electron atoms.
The 488 nm laser is shine on a lithium metal whose work function is 2.9 eV will you be able to see any photoelectrons? if yes what is the kinetic energy of the electrons if no what wavelength of light should be used to see the photoelectrons
Answer:
There will not be any ejection of photoelectrons
Explanation:
Energy of the photon= hc/λ
Where;
h= Plank's constant
c= speed of light
λ= wavelength of the incident photon
E= 6.6×10^-34 × 3 ×10^8/488 × 10^-9
E= 4.1 ×10^-19 J
Work function of the metal (Wo)= 2.9 eV × 1.6 × 10^-19 = 4.64 × 10^-19 J
There can only be ejected photoelectrons when E>Wo but in this case, E<Wo hence there will not be any ejection of photoelectrons.
The number of bonds an atom can form without violating the octet rule is reflected in the number of holes the "ball" for that atom has in the ball-and-stick model set. Based on that information, how many holes would you expect to see in models of atoms for each of the following elements: (4 points total; 1 point per element) a. Carbon (C)
Answer:
four holes
Explanation:
A ball and stick model is a representation of a molecule that can show the number of bonds and sometimes, the stereochemistry of the molecule under study.
The number of holes on present in the ball and stick model for any atom corresponds to the number of bonds that particular atom can form without violating the octet rule.
Carbon is usually tetravalent, it forms four bonds to other atoms. Hence we expect carbon to have four holes.
Answer:
Explanation:
Carbon - Four-hole
Nitrogen - Three-hole
Oxygen - Two-hole
Hydrogyn - Two-hole
Which species functions as the oxidizing agent in the following reduction-oxidation reaction?
Which one the reducing agent?
Which one is oxidized?
Which one is reduced?
Which one loses electrons?
Which one gains electrons?
Zn(s) + Cu2+(aq) ? Cu(s) + Zn2+(aq).
Answer:
See explanation
Explanation:
In this case, we can start with the half-reactions. If the total reaction is:
[tex]Zn_(_s_)~+~Cu^2^+~_(_a_q_)~->~Cu_(_s_)~+~Zn^2^+_(_a_q_)[/tex]
If we split the reaction we will have:
Half-reaction 1:
[tex]Zn_(_s_)~->~Zn^2^+_(_a_q_)[/tex]
Half-reaction 2:
[tex]Cu^2^+~_(_a_q_)~->~Cu_(_s_)[/tex]
Now we can add the electrons, keeping in mind that we have to obtain zero charge in both sides of each half-reaction:
Half-reaction 1:
[tex]Zn_(_s_)~->~Zn^2^+_(_a_q_)~+~2e^-[/tex]
Half-reaction 2:
[tex]Cu^2^+~_(_a_q_)~+~2e^-~->~Cu_(_s_)[/tex]
With this in mind, we can solve the questions:
Which one loses electrons?
In half-reaction number 1 we have the electrons in the products side, therefore this half-reaction is the one that loses electrons.
Which one gains electrons
In half-reaction number 2 we have the electrons in the reagent side, therefore this half-reaction is the one that gains electrons.
Which one is oxidized?
If half-reaction number 1 loses electrons will be the oxidation reaction.
Which one is reduced?
If half-reaction number 2 gains electrons will be the reduction reaction.
Which species functions as the oxidizing agent in the following reduction-oxidation reaction?
If half-reaction number 2 is the reduction will be a oxidizing agent.
Which one the reducing agent?
If half-reaction number 1 is the oxidation will be a reducing agent.
I hope it helps!
Which of the following is a characteristic of a good roasting pan?
Answer:
i can't understand the question
On the basis of intermolecular forces of attraction, rank the following three compounds in terms of increasing boiling point.
CH3CH2OH
CH3OCH3
CH3CH2CH3
a. (lowest bp) CH3CH2CH3 < CH3OCH3 < CH3CH2OH (highest bp)
b. (lowest bp) CH3CH2OH < CH3OCH3 < CH3CH2CH3 (highest bp)
c. (lowest bp) CH3OCH3 < CH3CH2OH < CH3CH2CH3 (highest bp)
d. (lowest bp) CH3CH2OH < CH3CH2CH3 < CH3OCH3 (highest bp)
e. (lowest bp) CH3CH2CH3 < CH3CH2OH < CH3OCH3 (highest bp)
Answer:
a. (lowest bp) CH3CH2CH3 < CH3OCH3 < CH3CH2OH (highest bp
Explanation:
CH3CH2OH is an alkanol. The intermolecular forces present within the molecules include dispersion forces, dipole-dipole attraction as well as hydrogen bonding which is the major intermolecular force of attraction present.
CH3OCH3 is an ether. The intermolecular forces present within the molecules are dispersion forces and dipole-dipole attraction.
CH3CH2CH3 is an alkane. The only intermolecular forces present is dispersion forces.
The order of increasing strength of these intermolecular forces is dispersion forces ,dipole-dipole forces<hydrogen bonding, the alkanol has the highest bioling point, followed by the ether and then the alkane with the lowest boiling point.
The ranking of the compounds in terms of increasing the boiling point is option a.
What is ethanol?Ethanol i.e. (CH3-CH2-O-H) has three types of intermolecular interactions i.e. weak van der Waals interaction, dipole-dipole interaction, and strong intermolecular H-bonding interaction.
While on the other hand, in dimethyl ether (CH3-O-CH3) have two types of interactions - weak van der Waals interaction, and dipole-dipole interaction.
In propane (CH3-CH2-CH3) has only weak van der Waals interaction.
So ethanol needed more energy to overcome this these interactions for the conversion to a liquid state to the gaseous state.
Learn more about compounds here: https://brainly.com/question/18136864
FeCl2(aq) + Na2CO3(aq) FeCO3(s) + 2NaCl(aq) What are the spectator ions in this equation?
Answer:
Chloride (Cl⁻) and sodium (Na⁺) ions.
Explanation:
Hello,
In this case, since the aqueous species are actually dissociated when reacting and the solid species (ferric carbonate) remains undissolved, we can modify the given reaction as follows:
[tex]FeCl_2(aq) + Na_2CO_3(aq) \rightarrow FeCO_3(s) + 2NaCl(aq)[/tex]
In such a way, dissociating the aqueous species we obtain:
[tex]Fe^{2+}(aq)+2Cl^-(aq) + 2Na^+(aq)+CO_3^{2-}(aq) \rightarrow FeCO_3(s) + 2Na^+(aq)+2Cl^-(aq)[/tex]
It means that the net ionic equation is:
[tex]Fe^{2+}(aq)+CO_3^{2-}(aq) \rightarrow FeCO_3(s)[/tex]
Therefore, the spectator ions are those were cancelled out, chloride (Cl⁻) and sodium (Na⁺).
Best regards.
Which of the following solutions will have the lowest freezing point?
a. 0.010 m Li2SO4
b. 0.015 m MgCl2
c. 0.035 m CH3CH2CH2OH
d. 0.010 m NaCl
Answer:
0.035 m CH3CH2CH2OH
Explanation:
We know that freezing point is a coligative property hence it depends on the number of solute particles present.
Covalent substances do not break up into ions, hence they do not produce many particles in solution unlike ionic substances. Hence, ionic substances have a far higher freezing point than covalent molecules.
For this reason, 0.035 m CH3CH2CH2OH has the lowest freezing point.
What are scientific models used for? Give an example of each of the follwoing types of models: idea, physical, computer
Answer:
Scientific models are used to explain phenomena that can not be experience directly and it is also used for prediction.
Explanation:
An example of idea model is the Eistein equation. An idea model shows how things interact together to produce a particular result.
An example of physical model is the solar system.
Computer model is used to predict long term events and an example of this is computer simulations.
The following molecular equation represents the reaction that occurs when aqueous solutions of silver(I) nitrate and calcium chloride are combined.
2AgNO3 (aq) + CaCl2 (aq)-------- 2AgCl (s) + Ca(NO3)2 (aq)
Write the balanced net ionic equation for the reaction.
Answer:
Ag+(aq) + Cl-(aq) —> AgCl(s)
Explanation:
2AgNO3(aq) + CaCl2(aq) —>2AgCl(s) + Ca(NO3)2(aq)
The balanced net ionic equation for the reaction above can be obtained as follow:
AgNO3(aq) and CaCl2(aq) will dissociate in solution as follow:
AgNO3(aq) —> Ag+(aq) + NO3-(aq)
CaCl2(aq) —> Ca2+(aq) + 2Cl-(aq)
AgNO3(aq) + CaCl2(aq) –>
2Ag+(aq) + 2NO3-(aq) + Ca2+(aq) + 2Cl-(aq) —> 2AgCl(s) + Ca2+(aq) + 2NO3-(aq)
Cancel out the spectator ions i.e Ca2+(aq) and 2NO3- to obtain the net ionic equation.
2Ag+(aq) + 2Cl-(aq) —> 2AgCl(s)
Divide through by 2
Ag+(aq) + Cl-(aq) —> AgCl(s)
The, the net ionic equation is
Ag+(aq) + Cl-(aq) —> AgCl(s)
Determine the pH of a buffer which is a 0.20 M solution of trimethylamine (N(CH3)3) and a 0.40 M solution of trimethylammonium chloride (NH(CH3)3Cl). The Kb of trimethylamine at 25°C is 6.3x10-5.
Answer:
pH of the buffer is 10.10
Explanation:
trimethylamine is a weak base that, in presence with its conjugate base, trimethylammonium ion, produce a buffer.
To determine the pH of the buffer we use H-H equation for weak bases:
pOH = pKb + log [Conjugate acid] / [Weak base]
pKb is -log Kb = 4.20
pOH = 4.20 + log [N(CH₃)₃] / [NH(CH₃)₃]
Replacing the concentrations of the problem:
pOH = 4.20 + log [0.20M] / [0.40M]
pOH = 3.90
As pH = 14 -pOH
pH of the buffer is 10.10
At 700 K, the reaction 2SO 2(g) + O 2(g) 2SO 3(g) has the equilibrium constant K c = 4.3 × 10 6, and the following concentrations are present: [SO 2] = 0.010 M; [SO 3] = 10. M; [O 2] = 0.010 M. Which of the following is true based on the above?
A. Qc < Kc, the reaction proceeds from right to left to reach equilibrium
B. Qc < Kc, the reaction proceeds from left to right to reach equilibrium
C. Qc > Kc, the reaction proceeds from right to left to reach equilibrium
D. Qc > Kc, the reaction proceeds from left to right to reach equilibrium
E. Qc = Kc, the reaction is currently at equilibriums
Answer:
The correct answer is "C. Qc > Kc, the reaction proceeds from right to left to reach equilibrium"
Explanation:
The reaction quotient Qc is a measure of the relative amount of products and reactants present in a reaction at a given time.
Being:
aA + bB ⇔ cC + dD
where a, b, c and d are the stoichiometric coefficients of the balanced equation, the coefficient Q is calculated as:
[tex]Qc=\frac{[C]^{c}*[D]^{d} }{[A]^{a} *[B]^{b} }[/tex]
If Qc <Kc there is less concentration of products than in equilibrium, with which the reaction will evolve to the right to increase the concentration of products.
If Qc> Kc, it is possible to affirm that the reaction will evolve to the left since in this case the direct reaction predominates and there will be more product present than what is obtained in equilibrium. Therefore, this product is used to promote the reverse reaction and achieve equilibrium. Then the system will evolve to the left to increase the concentration of reagents.
If Qc = Kc, it means that the reaction is in equilibrium.
In the case of the reaction:
2 SO₂ (g) + O₂ (g) ⇔ 2 SO₃(g)
the value of the constant Qc is calculated as:
[tex]Qc=\frac{[SO_{3} ]^{2} }{[SO_{2} ]^{2} *[O_{2} ]}[/tex]
Being:
[SO₂] = 0.010 M [SO₃] = 10 M [O₂] = 0.010 Mand replacing:
[tex]Qc=\frac{10^{2} }{0.010^{2} *0.010}[/tex]
you get:
Qc=100,000,000=1*10⁸
Being Kc=4.3*10⁶, then Qc>Kc and the reaction proceeds from right to left to reach equilibrium.
So the correct answer is "C. Qc > Kc, the reaction proceeds from right to left to reach equilibrium"
How does the solubility of atmospheric carbon dioxide change with variations in pH and salinity?
Answer:
Decreasing pH decreases the solubility; increasing salinity increases the salinity.
Explanation:
Atmospheric carbon dioxide in seawater is involved in the following equilibria:
(i) CO₂(g) ⇌ CO₂(aq)
(ii) CO₂(aq) + H₂O ⇌ H₂CO₃(aq)
(iii) H₂CO₃(aq) + H₂O(l) ⇌ H₃O⁺(aq) + HCO₃⁻(aq)
(iv) HCO₃⁻(aq)+ H₂O(l) ⇌ H₃O⁺(aq) + CO₃²⁻(aq)
1. Effect of pH
Decreasing pH increases [H₃O⁺].
According to Le Châtelier's Principle, the position of equilibrium of (iv) will be pushed to the left.
This, in turn, pushes the positions of equilibrium of (iii), (ii), and (i) to the left.
The net effect is that CO₂ is pushed out of the solution and back into the atmosphere.
Thus, decreasing the pH decreases the solubility of atmospheric CO₂.
2. Effect of salinity
Salinity includes the measurement of all ions in seawater, not just Na⁺ and Cl⁻.
An important ion that contributes to salinity is Ca²⁺.
Ca²⁺ ions are involved in the equilibrium
Ca²⁺(aq) + CO₃²⁻(aq) ⇌ CaCO₃(s).
Thus, increasing the salinity ([Ca²⁺]) removes CO₃²⁻ from the solution and pulls the position of equilibrium of (iv) to the right.
The effect goes back through the chain of equilibria.
The net result is that more atmospheric CO₂(g) dissolves in the seawater to replace the CO₃²⁻ that has been removed.
Increasing the salinity increases the solubility of atmospheric CO₂.
For a concentration cell, the standard cell potential is always:________.
a. positive
b. negative
c. zero
d. need more information
Answer:
C. Zero
Explanation:
A concentration cell is defined as a type of galvanic cell which has two equivalent half-cells of the same constituent in the electrodes but different concentration in the electrolytes.
For a concentration cell, the standard cell potential is always Zero and the cell potential is usually measured with the use of the Nernst equation.
Select the salts that will undergo hydrolysis.
a. KF
b. NaNO3
c. NH4NO2
d. MgSO4
e. KCN
f. C6H5COONa
g. RbI
h. Na2CO3
i. CaCl2
j. HCOOK
Answer:
- In general, the salt that can make hydrolysis (both ions) is option c (ammonium nitrite).
- Salts that can make hydrolysis (one of the ions) are option a (potassium fluoride), option e (potassium cyanide), option f (sodium benzoate), option h (sodium carbonate) and option k (potassium formiate).
- Surely the neutrals salt are (salts that don't make hydrolysis) option b (sodium nitrate), option d (magnessium sulfate), option g (rubidium iodide) and option i (calcium chloride).
Explanation:
To determine the hydrolysis we have to dissociate the salts, and then we define the conjugate strong bases or acids, that can react to water.
a. KF → K⁺ + F⁻
F⁻ comes from the HF, a weak acid so the anion is the conjugate strong base. F⁻ can make hydrolysis, but the K⁺, can not.
b. NaNO₃ → Na⁺ + NO₃⁻
Boths are conjugate weak acid and base, this salt is neutral. So they cannot do hydrolysis.
c. NH₄NO₂ → NH₄⁺ + NO₂⁻
Both ions can make hydrolysis to water, because the are conjugate strong base and acid.
The ammonium gives ammonium again:
NH₄⁺ + H₂O ⇄ NH₃ + H₃O⁺ Ka
The nitrite gives nitrose acid, again
NO₂⁻ + H₂O ⇄ HNO₂ + OH⁻ Kb
d. MgSO₄ → Mg²⁺ + SO₄⁻²
This is a neutral salt. Boths are conjugate weak acid and base, that's why they can not make hydrolysis.
e. KCN → K⁺ + CN⁻
As K⁺ comes from a strong base, it can not do hydrolysis.
Then, the cyanide can make hydrolysis because it comes from the HCN (a weak acid), so the ion is the conjugate strong base.
CN⁻ + H₂O ⇄ HCN + OH⁻
f. C₆H₅COONa → C₆H₅COO⁻ + Na⁺
This salt is called sodium benzoate. As Na⁺ comes from a strong base, it can not do hydrolysis. Then, the C₆H₅COO⁻ can make hydrolysis because it comes from the benzoic acid, so the ion is the conjugate strong base.
C₆H₅COO⁻ + H₂O ⇄ C₆H₅COOH + OH⁻ Kb
g. RbI → Rb⁺ + I⁻
This is a neutral salt. Similar case as NaCl. Both are conjugate weak acid and base, that's why they can not make hydrolysis.
h. Na₂CO₃ → 2Na⁺ + CO₃⁻²
The one that can make hydrolysis in this case, is the carbonate anion.
CO₃⁻² + H₂O ⇄ HCO₃⁻ + OH⁻
Carbonate comes from the carbonic acid, a dyprotic weak one.
i. CaCl₂ → Ca²⁺ + 2Cl⁻
This is a neutral salt. Similar case as NaCl. Both are conjugate weak acid and base, that's why they can not make hydrolysis.
j. HCOOK → HCOO⁻ + K⁺
This is the potassium formiate. K⁺ comes from KOH, a strong base. It don't make hydrolysis, while the HCOO⁻ can do the hydrolysis in water.
When the formiate react, we can produce formic acid. Formiate is the conjugate strong base, of a weak acid.
HCOO⁻ + H₂O ⇄ HCOOH + OH⁻
calculate the specific heat of copper if it takes 23 cal to heat a 5.0 g sample from 25 C to 75 C
Answer:
0.384928 J/g°C
Explanation:
The formula for Specific Heat (C)
= q/m × ∆t
Where q = Heat energy required to heat the compound (in joules)
m = mass of the compound (sample)
∆t = Change in temperature
In the question, we are given the following values.
m = 5.0g
∆t = Change in temperature = 75°C - 25°C
= 50°C
q = Heat energy = 23 cal
We have to convert to joules
One calorie is equal to 4.184 joules.
1 Cal = 4.184 joules
23 Cal =
23 × 4.184 joules
= 96.232 joules
Specific Heat (C) of copper
= 96.232 J /(5g × 50°C)
= 96.232J / 250
= 0.384928 J/g°C
Therefore, the Specific Heat of Copper is 0.384928 J/g°C
Light energy from the sun is converted by plants into
A electricity
B mechanical energy
C leaves
D chemical energy
A solution is made by dissolving
3.60g of sodium chloride to a final
volume of 115mL solution.
What is the weight/volume % of the
solute?
Answer:
3.13%
Explanation:
Step 1: Given data
Mass of sodium chloride (solute): 3.60 g
Volume of solution: 115 mL
Step 2: Calculate the weight/volume % of the solute
We will use the following expression.
%w/v = mass of solute / milliliters of solution × 100%
%w/v = 3.60 g / 115 mL × 100%
%w/v = 3.13%
The weight/volume % of the solute is 3.13%
Answer:
3.13
Explanation:
correct
A) For the following reaction, K > 1. Classify each of the reactants and products based on their strength as Bronsted-Lowry acids or bases.
C9H7N + HNO2Doublearrow.GIFC9H7NH+ + NO2-
a) HNO2 1) stronger acid
b) NO2- 2) weaker acid
c) C9H7NH+ 3) stronger base
d) C9H7N 4) weaker base
B)
For the following reaction, K < 1. Classify each of the reactants and products based on their strength as Bronsted-Lowry acids or bases.
C5H11NH+ + C6H5COO-Doublearrow.GIFC5H11N + C6H5COOH
a) C5H11NH+ 1) strongest acid
b) C6H5COO- 2) stongest base
c) C5H11N 3) weakest acid
d) C6H5COOH 4) weakest base
Answer:
Explanation:
According to Bronsted-Lowry acids or base theory , the reagent capable of giving hydrogen ion or proton will be acid and that which accepts hydrogen ion or proton will be base .
C₉H₇N + HNO₂ ⇄ C₉H₇NH⁺ + NO₂⁻
If K > 1 , reaction is proceeding from left to right .
Hence HNO₂ is giving H⁺ or proton and C₉H₇N is accepting proton to form
C₉H₇NH⁺ .
Hence HNO₂ is bronsted acid and C₉H₇N is bronsted base .
B )
when K < 1 , reaction above proceeds from right to left . That means
C₉H₇NH⁺ is giving H⁺ so it is a bronsted acid and NO₂⁻ is accepting H⁺ so it is a bronsted base .
Hence , NO₂⁻ is a bronsted base and C₉H₇NH⁺ is a bronsted acid .
In the following net ionic equation, identify each reactant as either a Bronsted-Lowry acid or a Bronsted-Lowry base. HCN(aq) H2O(l) CN-(aq) H3O (aq) B-L _____ B-L _____
The formula of the reactant that acts as a proton donor is_______
The formula of the reactant that acts as a proton acceptor is________
Answer:
Explanation:
The definition of acids and bases by Arrhenius Theory was modified and extended by Bronsted-Lowry.
Bronsted-Lowry defined acid as a molecule or ion which donates a proton while a base is a molecule or ions that accepts the proton. This definition can be extended to include acid -base titrations in non-aqueous solutions.
In this theory, the reaction of an acid with a base constitutes a transfer of a proton from the acid to the base.
From the given information:
[tex]\mathsf{HCN _{(aq)} + H_2O_{(l)} \to CN^{-}_{(aq)} + H_3O_{(aq)}}[/tex]
From above:
We will see that HCN releases an H⁺ ion, thus it is a Bronsted-Lowry acid
[tex]H_2O[/tex] accepts the H⁺ ion ,thus it is a Bronsted-Lowry base.
The formula of the reactant that acts as a proton donor is HCN
The formula of the reactant that acts as a proton acceptor is H2O
1.An aqueous solution of 0.975 M hydrochloric acid, HCl, has a density of 1.02 g/mL. The percent by mass of HCl in the solution is ___ %.
2.An aqueous solution of 1.29 M ethanol, CH3CH2OH, has a density of 0.988 g/mL. The percent by mass of CH3CH2OH in the solution is ___%.
3.An aqueous solution is 40.0% by mass silver nitrate, AgNO3, and has a density of 1.47 g/mL. The molarity of silver nitrate in the solution is ___M.
Answer:
The percent mass of HCl in the solution is 3.48 %
The percent mass of ethanol in the solution is 6.01 %
The molarity of silver nitrate in the solution is 3.46 M
Explanation:
Percent by mass = mass of solute/100 g of solutionDensity always referrs to solution data.
1.02 g/mL = 100 g / volume of solution
Volume of solution = 98.04 mL
Molarity = moles of solute in 1L of solution (or mmoles of solute in 1mL)
M . 98.04 mL = mmoles of solute → 0.975 M . 98.04 mL = 95.59 mmoles
mmoles . PM (mg / mmol) = mg → 95.59 mmol . 36.45 mg/mmol = 3484 mg.
We convert data to g → 3484 mg . 1g/ 1000 mg = 3.48 g
The percent mass of HCl in the solution is 3.48 %
Percent by mass = mass of solute/100 g of solutionDensity always referrs to solution data.
0.988 g/mL = 100 g / volume of solution
Volume of solution = 101.21 mL
Molarity = moles of solute in 1L of solution (or mmoles of solute in 1mL)
M . 101.21 mL = mmoles of solute → 1.29 M . 101.21 mL = 130.6 mmoles
mmoles . PM (mg / mmol) = mg → 130.6 mmol . 46.07 mg/mmol = 6015 mg.
We convert data to g → 6015 mg . 1g/ 1000 mg = 6.01 g
The percent mass of ethanol in the solution is 6.01 %
Percent by mass = mass of solute/100 g of solutionDensity always referrs to solution data.
1.47 g/mL = 100 g / volume of solution
Volume of solution = 68.03 mL
Molarity = moles of solute in 1L of solution (or mmoles of solute in 1mL)
40 g = 40000 mg
mg / PM (mg / mmol) = mmol → 40000 mg / 169.87 mg/mmol
= 235.4 mmoles
mmoles / mL = Molarity → 235.4 mmol / 68.03 mL = 3.46 M
The term electron capture best fits which of the following descriptions?
A. Electron capture is a phenomenon exhibited by an unstable nucleon that spontaneously converts into a more stable nuclei.
B. Electron capture is the combination of a core electron with a proton to yield a neutron within the nucleus.
C. Electron capture is the addition of an electron to a neutral atom to form an anion.
D. None of the above.
Answer:
Option B:
Electron capture is the combination of a core electron with a proton to yield a neutron within the nucleus.
Explanation:
The electron capture is a nuclear process whereby a neutral atom absorbs an electron from its closest shell (which is usually the K shell of the atom).
This capture phenomenon, causes one of the protons within the nucleus of the atom to convert into a neutron because of the merging of the positive and negative charges. Once they merge, a light particle called the electron neutrino is emitted from the nucleus of the atom.
This phenomenon occurs mostly in atoms that have a proton-rich nucleus. This provides the positive charge that pulls the electron from its shell into the nucleus of the atom.