**Photodissociation of Hydrogen Molecules**Light of wavelengths shorter than 275 nm can be used to photodissociate hydrogen molecules into hydrogen atoms in the gas phase. In this scenario, a 70.0 mL glass cylinder contains \( \text{H}_2 (g) \) at 65.0 mtorr and 25 °C. **Problem:**What is the minimum amount of light energy that must be absorbed by the hydrogen in the tube to dissociate 26.0% of the molecules?**Solution Attempt:**An energy value of 0.277 J was entered, but it is labeled as "Incorrect."**Instructions:**Use the principles of photochemistry and gaseous equilibrium to calculate the correct amount of energy needed for the dissociation process. Remember to convert pressure and volume units, and consider the dissociation energy per molecule to find the total energy required.

Answered: Image /qna-images/answer/627c6cb0-56e9-484c-9b3b-51c79021a2c2.jpg

Light of wavelengths shorter than 275 nm can be used to photodissociate the hydrogen molecule into hydrogen atoms in the gas phase. A 70.0 mL glass cylinder contains H, (g) at 65.0 mtorr and 25 °C. What minimum amount of light energy must be absorbed by the hydrogen in the tube to dissociate 26.0% of the molecules? 0.277 energy absorbed: Incorrect

Light of wavelengths shorter than 275 nm can be used to photodissociate the hydrogen molecule into hydrogen atoms in the gas phase. A 70.0 mL glass cylinder contains H, (g) at 65.0 mtorr and 25 °C. What minimum amount of light energy must be absorbed by the hydrogen in the tube to dissociate 26.0% of the molecules? 0.277 energy absorbed: Incorrect

Chemistry

10th Edition

ISBN:9781305957404

Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Publisher:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Chapter1: Chemical Foundations

Section: Chapter Questions

Problem 1RQ: Define and explain the differences between the following terms. a. law and theory b. theory and...

See similar textbooks

Similar questions

Bromine is used in the manufacture of disinfectant products, it has a very strong oxidizing character, due to the great electronic affinity it presents. Based on therefore, what will be the electron affinity in kJ/mol of bromine from the following equations?. Explain the development.
If Li(s) is exposed to F2(g), how would the electrons rearrange? Write a balanced chemical equation and explain why it occurs by comparing the Zeff of Li vs. F.
Assuming the wavelength for fluorescence is observed at 475 nm and the wavelength of the phosphorescence process occurs at 523 nm, find the energy released from 12.35 g of Calcium atoms. (Assume that there is 1 excited electron per calcium atom and every one of them relaxes via the processes above.) (Fluorescence occurs 2.45 times more frequently than phosphorescence)
Compare the energy (in joules) carried by an X-ray pho- ton (wavelength A = 0.20 nm) with that carried by an AM radio wave photon (A = 200 m). Calculate the 1.00 mol of each type of photon. What effect do you expect each type of radiation to have for inducing chemi- cal reactions in the substances through which it passes? energy of
Question:In the field of quantum chemistry, explain the concept of electron correlation and its impact on molecular properties.