(b)
Interpretation:
The significant resonant structures indicated by curved arrows have to be drawn.
Concept Introduction:
Resonance is a method to relating to describe about delocalized electrons inside certain molecules or polyatomic ions where the Lewis structure can’t be expressed. A molecule or ion containing delocalized electrons can be represented by using several similar structures such structures are called as resonance structures or canonical structures.
The delocalization of electron lowers the potential energy of the substance and making it more stable than any of the contributing structures. The variation in the potential energy of the actual structure and that of resemblance structure with lowest potential energy is known as resonance energy or delocalization energy.
Curved arrows:
The necessary tools to draw perfect resonance structure are curved arrows. Curved arrows don’t represent the flow of electrons. A tail and a head can be seen in curved arrow.
A head and tail of every arrow are to be drawn in the exact location. The tail represents where the electrons are originated, and the head represents the place where the electrons are going.
(c)
Interpretation:
The significant resonant structures indicated by curved arrows have to be drawn.
Concept Introduction:
Resonance is a method to relating to describe about delocalized electrons inside certain molecules or polyatomic ions where the Lewis structure can’t be expressed. A molecule or ion containing delocalized electrons can be represented by using several similar structures such structures are called as resonance structures or canonical structures.
The delocalization of electron lowers the potential energy of the substance and making it more stable than any of the contributing structures. The variation in the potential energy of the actual structure and that of resemblance structure with lowest potential energy is known as resonance energy or delocalization energy.
Curved arrows:
The necessary tools to draw perfect resonance structure are curved arrows. Curved arrows don’t represent the flow of electrons. A tail and a head can be seen in curved arrow.
A head and tail of every arrow are to be drawn in the exact location. The tail represents where the electrons are originated, and the head represents the place where the electrons are going.
(d)
Interpretation:
The significant resonant structures indicated by curved arrows have to be drawn.
Concept Introduction:
Resonance is a method to relating to describe about delocalized electrons inside certain molecules or polyatomic ions where the Lewis structure can’t be expressed. A molecule or ion containing delocalized electrons can be represented by using several similar structures such structures are called as resonance structures or canonical structures.
The delocalization of electron lowers the potential energy of the substance and making it more stable than any of the contributing structures. The variation in the potential energy of the actual structure and that of resemblance structure with lowest potential energy is known as resonance energy or delocalization energy.
Curved arrows:
The necessary tools to draw perfect resonance structure are curved arrows. Curved arrows don’t represent the flow of electrons. A tail and a head can be seen in curved arrow.
A head and tail of every arrow are to be drawn in the exact location. The tail represents where the electrons are originated, and the head represents the place where the electrons are going.
(e)
Interpretation:
The significant resonant structures indicated by curved arrows have to be drawn.
Concept Introduction:
Resonance is a method to relating to describe about delocalized electrons inside certain molecules or polyatomic ions where the Lewis structure can’t be expressed. A molecule or ion containing delocalized electrons can be represented by using several similar structures such structures are called as resonance structures or canonical structures.
The delocalization of electron lowers the potential energy of the substance and making it more stable than any of the contributing structures. The variation in the potential energy of the actual structure and that of resemblance structure with lowest potential energy is known as resonance energy or delocalization energy.
Curved arrows:
The necessary tools to draw perfect resonance structure are curved arrows. Curved arrows don’t represent the flow of electrons. A tail and a head can be seen in curved arrow.
A head and tail of every arrow are to be drawn in the exact location. The tail represents where the electrons are originated, and the head represents the place where the electrons are going.
(f)
Interpretation:
The significant resonant structures indicated by curved arrows have to be drawn.
Concept Introduction:
Resonance is a method to relating to describe about delocalized electrons inside certain molecules or polyatomic ions where the Lewis structure can’t be expressed. A molecule or ion containing delocalized electrons can be represented by using several similar structures such structures are called as resonance structures or canonical structures.
The delocalization of electron lowers the potential energy of the substance and making it more stable than any of the contributing structures. The variation in the potential energy of the actual structure and that of resemblance structure with lowest potential energy is known as resonance energy or delocalization energy.
Curved arrows:
The necessary tools to draw perfect resonance structure are curved arrows. Curved arrows don’t represent the flow of electrons. A tail and a head can be seen in curved arrow.
A head and tail of every arrow are to be drawn in the exact location. The tail represents where the electrons are originated, and the head represents the place where the electrons are going.
(g)
Interpretation:
The significant resonant structures indicated by curved arrows have to be drawn.
Concept Introduction:
Resonance is a method to relating to describe about delocalized electrons inside certain molecules or polyatomic ions where the Lewis structure can’t be expressed. A molecule or ion containing delocalized electrons can be represented by using several similar structures such structures are called as resonance structures or canonical structures.
The delocalization of electron lowers the potential energy of the substance and making it more stable than any of the contributing structures. The variation in the potential energy of the actual structure and that of resemblance structure with lowest potential energy is known as resonance energy or delocalization energy.
Curved arrows:
The necessary tools to draw perfect resonance structure are curved arrows. Curved arrows don’t represent the flow of electrons. A tail and a head can be seen in curved arrow.
A head and tail of every arrow are to be drawn in the exact location. The tail represents where the electrons are originated, and the head represents the place where the electrons are going.
(h)
Interpretation:
The significant resonant structures indicated by curved arrows have to be drawn.
Concept Introduction:
Resonance is a method to relating to describe about delocalized electrons inside certain molecules or polyatomic ions where the Lewis structure can’t be expressed. A molecule or ion containing delocalized electrons can be represented by using several similar structures such structures are called as resonance structures or canonical structures.
The delocalization of electron lowers the potential energy of the substance and making it more stable than any of the contributing structures. The variation in the potential energy of the actual structure and that of resemblance structure with lowest potential energy is known as resonance energy or delocalization energy.
Curved arrows:
The necessary tools to draw perfect resonance structure are curved arrows. Curved arrows don’t represent the flow of electrons. A tail and a head can be seen in curved arrow.
A head and tail of every arrow are to be drawn in the exact location. The tail represents where the electrons are originated, and the head represents the place where the electrons are going.
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Chapter 2 Solutions
Organic Chemistry
- 3. A thermometer is placed in a test tube of chipped ice at -5.0 °C. The temperature is recorded at the time intervals shown below until room temperature is reached. Plot the data given below on graph paper and explain all flat, horizontal portions of the curve. Plot time on the X-axis! Time (min) Temperature (°C) 0 -5.0 2 -2.5 4 -1.0 6 0.0 10 0.0 15 0.0 20 0.0 25 0.0 30 1.5 35 4.0 40 8.0 45 11.5 50 15.0 55 17.5 60 19.0 65 20.0 70 20.0 75 20.0 80 20.0arrow_forwardNaming the Alkanes a) Write the IUPAC nomenclature of the compound below b) Draw 4-isopropyl-2,4,5-trimethylheptane, identify the primary, secondary, tertiary, and quaternary carbons. c) Rank pentane, neopentane and isopentane for boiling point. pentane: H3C-CH2-CH2-CH2-CH3 neopentane: CH3 H3C-Ċ-CH3 I CH3 isopentane: CH3 H3C-CH2-CH-CH3arrow_forwardWhich will evaporate faster, 1-Butanol or Pentane? Explain your choice.arrow_forward
- Using the equation below, what is the rate of this reaction if the rate of disappearance of H2 is 0.44 M/sec? H2 + Br2 → 2HBrarrow_forward2Fe3+(aq) + Sn2+(aq) □ 2Fe²+(aq) + Sn 4+ (aq) If the change in Sn²+ concentration is 0.0010M in 38.5 seconds, what is the rate of disappearance of Sn²+?arrow_forwardFor a neutral hydrogen atom with an electron in the n = 4 state, how many different energies are possible when a photon is emitted? 4 3 2 1 There are infinite possibilitiesarrow_forward
- 2 NO(g) + H2(g) → N2(g) +2 H2O(g) If NO has rate of disappearance of 0.025 M/min, what is the rate of this reaction?arrow_forward2Fe3+(aq) + Sn2+(aq) □ 2Fe²+(aq) + Sn 4+ (aq) If the change in Sn2+ concentration is 0.0010M in 38.5 seconds, what is the rate of appearance of Fe²+?arrow_forwardUsing the equation below, if the rate of disappearance of Cl2 is 0.26 M/min, what is the rate of this reaction? 2NO(g) + Cl2(g) → 2NOCI(g)arrow_forward
- A 45.0 mL solution containing a mixture of 0.0634 M KCN and 0.0634 M KCI is titrated with 0.107 M AgNO. From this mixture, which silver salt will precipitate first? A list of Ksp values can be found in the table of solubility constants. • AgCI • not enough information to determine AgCN What is the concentration of Ag* at the first equivalence point? [Ag*] = Will the second silver salt begin to precipitate at the first equivalence point before the first silver salt has completely precipitated? • not enough information to determine • yes • noarrow_forward[Review Topics] [References] Indicate whether the pair of structures shown represent stereoisomers, constitutional isomers, different conformations of the same compound, or the same conformation of a compound viewed from a different perspective. Note that cis, trans isomers are an example of stereoisomers. H₂N ✓ CI H₂N NH2 NH₂ CI Submit Answer Retry Entire Group 2 more group attempts remaining Previous Next>arrow_forwardDon't used Ai solutionarrow_forward
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