REGENTS CHEMISTRY LAB

SPECTROSCOPIC STUDY OF ELEMENTS

Introduction:

When electrical energy is directed through gas tubes containing elements, we see that each element creates a different colored light. This is the principle behind “neon” lights used for advertising. When the light from a glowing gas is passed through a diffraction grating or spectroscope,you will see that a particular color seen with your eyes is really a series of colored “bright lines” all blended together.

In this lab you will observe the emitted light emitted from several gas discharge tubes using a spectroscope. When you view the light from the glowing gas,it will be broken up into several brightly colored lines called “spectral lines”. Each spectral line indicates excited electrons that are falling back down to the ground state and emitting photons of energy of specific wavelengths. You will be able to read the wavelengths (in angstroms) of each brightly colored line.

From the observed wavelengths, you will calculate the frequency and energy of each bright line (for hydrogen only). You will then compare your data to a chart to determine which electron jump is responsible for each colored line for hydrogen These calculations will be done for hydrogen gas only.

٭Precautions: Turn off the spectrum tubes as soon as you are done using them. Letting

them constantly burn reduces their useful life span.

DO NOT touch black power supplies.

Procedure:

1.Using the gas discharge tubes note the colored lines thatyou see through a spectroscope and record the color and wavelengths (in Å) for each bright line.

Record wavelengths for the following tubes on the attach data sheet

Hydrogen

Mercury

Helium

Neon

Air

Sodium

Oxygen

Water

Fluorescent light bulb (look for the bright lines within the “rainbow”)

Calculations and Questions:

1.)For the hydrogen tube only, calculate the energy of each bright line that you observed.

Red Line:

Wavelength converted to meters (1 Angstrom = 1x10-10 meters)Wavelength (λ): ______

Determine the frequency of the colored line using this formula: c = λ x γ

c = speed of light = 3 x 108 meters/sec

λ = wavelength (in meters) of the colored line

γ = frequency (in cycles/sec) of the colored lineFrequency (γ):______

Determine the energy of the colored line using this formula: E = h x γ

γ = frequency (in cycles/sec) of the colored line

E = energy in Joules

h = Planck’s constant = 6.63 x 10-23 J/secEnergy (E): ______

Blue Line:

Wavelength converted to meters (1 Angstrom = 1x10-10 meters) Wavelength (λ): ______

Determine the frequency of the colored line using this formula: c = λ x γ

c = speed of light = 3 x 108 meters/sec

λ = wavelength (in meters) of the colored line

γ = frequency (in cycles/sec) of the colored lineFrequency (γ):______

Determine the energy of the colored line using this formula: E = h x γ

γ = frequency (in cycles/sec) of the colored line

E = energy in Joules

h = Planck’s constant = 6.63 x 10-23 J/secEnergy (E): ______

Purple Line:

Wavelength converted to meters (1 Angstrom = 1x10-10 meters) Wavelength (λ): ______

Determine the frequency of the colored line using this formula: c = λ x γ

c = speed of light = 3 x 108 meters/sec

λ = wavelength (in meters) of the colored line

γ = frequency (in cycles/sec) of the colored lineFrequency (γ):______

Determine the energy of the colored line using this formula: E = h x γ

γ = frequency (in cycles/sec) of the colored line

E = energy in Joules

h = Planck’s constant = 6.63 x 10-23 J/secEnergy (E): ______

Compare your answers with this chart, which represents the energy released when an electron in hydrogen

falls between different energy levels and emits energy.

From level 2 to level 11.63 x 10-18 J

From level 3 to level 11.94 x 10-18 J

From level 4 to level 12.04 x 10-18 J

From level 5 to level 12.09 x 10-18 J

From level 3 to level 23.03 x 10-19 J

From level 4 to level 24.09 x 10-19 J

From level 5 to level 24.58 x 10-19 J

From level 4 to level 31.06 x 10-19 J

From level 5 to level 31.55 x 10-19 J

From level 5 to level 44.09 x 10-20 J

2.Using your answers, predict which electron jump is responsible for eachcolored line in the hydrogen spectrum. (Example: The red line is caused by anelectron jumping from level 5 to level 2, etc.)

3.Did any similarities exist between the hydrogen, oxygen and water spectrum tubes? Should you expect any similarities between these three tubes? Why or why not?

  1. The fluorescent tube contains one element whose spectrum you observed in this experiment. By comparing bright lines and wavelengths of the fluorescent tube withthe other spectrum tubes, what element exists inside a fluorescent light bulb?
  1. Based on the things you have seen in this spectral tube lab, would you expect to see any similarities between the bright lines in a nitrogen spectrum tube and the bright lines in an air spectrum tube? Why or why not?
  1. Using the terms excited state, ground state, absorption and emission of energy describe how electrons cause specific spectral lines according to the Bohr model.
  1. Explain in terms of subatomic particles, why an excited atom is electrically neutral
  1. Describe why emission spectroscopy is a helpful tool in determining the identity of materials in fields like forensic science.

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