Consider the following data for fluorine: 19.00 mol atomic mass electronegativity 3.98 kJ 328. mol electron affinity kJ 1681.0 mol ionization energy kJ 0.26 mol heat of fusion You may find additional useful data in the ALEKS Data tab. Does the following reaction absorb or release energy? release absorb + (1) F (g) + e F (g) Can't be decided with the data given. yes Is it possible to calculate the amount of energy absorbed or released by reaction (1) using only the data above? no If you answered yes to the previous question, enter the amount of energy absorbed or released by reaction (1): |kJ/mol Does the following reaction absorb or release energy? release absorb (2) F (g) F (g) + e Can't be decided with the data given. Is it possible to calculate the amount of energy absorbed or released by reaction (2) using only the data above? yes O no If you answered yes to the previous question, enter the amount of energy absorbed or released by reaction (2): O kJ/mol

Consider the following data for fluorine: 19.00 mol atomic mass electronegativity 3.98 kJ 328. mol electron affinity kJ 1681.0 mol ionization energy kJ 0.26 mol heat of fusion You may find additional useful data in the ALEKS Data tab. Does the following reaction absorb or release energy? release absorb + (1) F (g) + e F (g) Can't be decided with the data given. yes Is it possible to calculate the amount of energy absorbed or released by reaction (1) using only the data above? no If you answered yes to the previous question, enter the amount of energy absorbed or released by reaction (1): |kJ/mol Does the following reaction absorb or release energy? release absorb (2) F (g) F (g) + e Can't be decided with the data given. Is it possible to calculate the amount of energy absorbed or released by reaction (2) using only the data above? yes O no If you answered yes to the previous question, enter the amount of energy absorbed or released by reaction (2): O kJ/mol

Principles of Modern Chemistry

8th Edition

ISBN:9781305079113

Author:David W. Oxtoby, H. Pat Gillis, Laurie J. Butler

Publisher:David W. Oxtoby, H. Pat Gillis, Laurie J. Butler

Chapter3: Atomic Shells And Classical Models Of Chemical Bonding

Section: Chapter Questions

Problem 17P

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H2 has equilibrium bond length of 0.751 Å and bond dissociation energy of 432 kJ mol21, whereas F2 has equilibrium bond length of 1.417 Å and bond dissociation energyof 155 kJ mol21. On the same graph show qualitativesketches of the effective potential energy curve Veff for anH2 and an F2 molecule. In your solution, show the conversion from kJ mol21to the energy of a single molecule.1
Findthemass%ofH2O2 inasolutionmadefrom36gofH2O2 and84gofH2O: A) 84% B) 36% C) 43% D) 30.% E) 70.%
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H2 has equilibrium bond length of 0.751 Å and bond dissociation energy of 432 kJ mol21 , whereas F2 has equilibrium bond length of 1.417 Å and bond dissociation energy of 155 kJ mol21. On the same graph show qualitativesketches of the effective potential energy curve Veff for an H2 and an F2 molecule. In your solution, show the conversion from kJ mol21 to the energy of a single molecule.
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Match the term to the description Example: 7.__j__
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