The energy level to which an electron in a hydrogen atom moves to from n = 5 upon emission of a photon of wavelength 1281 nm is to be determined. Concept introduction: An atom of hydrogen contains one electron. But the spectrum of hydrogen consists of a large number of lines. This is so because a sample of hydrogen contains a very large number of atoms. When energy is supplied to a sample of gaseous atoms of hydrogen, different atoms absorb different amounts of energy. Therefore, the electrons in different atoms jump to different energy levels. Upon losing the energies gained initially, the electrons jump back to lower energy levels and release radiations of different wavelengths. The equation used to predict the position and wavelength of any line in a given series is called the Rydberg’s equation. Rydberg’s equation is as follows: 1 λ = R ( 1 n 1 2 − 1 n 2 2 ) (1) Here, λ is the wavelength of the line. n 1 and n 2 are positive integers, with n 2 > n 1 . R is the Rydberg’s constant. The conversion factor to convert wavelength from nm to m is, 1 nm = 1 × 10 − 9 m

Question

Want to see the full answer?

Answer 1

Question

Chapter 7, Problem 7.32P

Interpretation Introduction

Interpretation:

The energy level to which an electron in a hydrogen atom moves to from n=5 upon emission of a photon of wavelength 1281 nm is to be determined.

Concept introduction:

An atom of hydrogen contains one electron. But the spectrum of hydrogen consists of a large number of lines. This is so because a sample of hydrogen contains a very large number of atoms. When energy is supplied to a sample of gaseous atoms of hydrogen, different atoms absorb different amounts of energy. Therefore, the electrons in different atoms jump to different energy levels. Upon losing the energies gained initially, the electrons jump back to lower energy levels and release radiations of different wavelengths.

The equation used to predict the position and wavelength of any line in a given series is called the Rydberg’s equation.

Rydberg’s equation is as follows:

1λ=R(1n12−1n22) (1)

Here,

λ is the wavelength of the line.

n1 and n2 are positive integers, with n2>n1.

R is the Rydberg’s constant.

The conversion factor to convert wavelength from nm to m is,

1nm=1×10−9 m

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Students have asked these similar questions

please solve. If the answer is "no error" and it asks me to type something, and i typed a-helix, its always wrong.

Can you please solve and explain this for me in a simple way? I cant seem to comprehend this problem.

Part I. Problem solving. Include all necessary calculations 13 provide plots and graphs. Complexation wl diphenyl carbazide (OPC) in acidic media is another type of sensitive photometric method used for the analysis of aqueous. hexavalent chromium. At 540nm the cherry-red complex as a result of DPC reaction w/ chromium can be photometrically measured. at this wavelength. - a 25mL The UV-vis analysis for the determination of nexavalent chromium in ground water sample is given below. The experiment was based on external calibration method w/ each measurement sample prepared are as follows lab sample analysis contained the standard 100 ppb croy cor groundwater sample, volumes used as indicated below), 12.50 mL of 0.02 M H2Soy and 5.50 ml of 100 ppm DPC (wi water to adjust final volume to 25-ml). The main stripping method was square wave voltammetry, following the conditions set in the main ASV experiment. Standard 100 Volumetric Groundwater H2SO4 0.20 M, flask Sample, mL ppb CrO4*, 100…