Match the following:
a) Lyman (r, t)p) visibleb) Balmer (p)q) Infraredc) Paschen (q, s)r) Ultravioletd) Brackett (q)s)n2=4,n1=3t)n2=5,n1=1
The Lyman series represents the UV spectrum, Balmer represents the visible light spectrum, and both the Paschen and Brackett series fall in the infrared spectrum. Top 4 posts. Page 1 of 1. The Lyman series is in the ultraviolet while the Balmer series is in the visible and the Paschen, Brackett, Pfund, and Humphreys series are in the infrared.
B.
a > r; b > q; c > p, s; d > s
D.
a > r, t; b > p; c > q, s; d > q
Please scroll down to see the correct answer and solution guide.
SOLUTION
This is a direct question that tests the basics of spectra from a hydrogen like species.
Take a look at the following theory. Using this you can match the columns right away.
Lyman: n1=1; UV
Balmer: n1=2; Visible
Paschen: n1=3; IR
Brackett. n1=4; IR
Paschen Series Equation
Paschen Balmer Lyman Series
Related Questions
Learning Objectives
- List the electron transition lines according to energy levels.
- Explain the presence of emission lines and relate them to electron transitions
Can you fix a car engine?
It’s not as common anymore, but there was a time when many people could work on their own cars if there was a problem. Today, engines are computerized and require specialized training and tools in order to be fixed.
When people did their own repairs, it was sometimes a trial and error process. Maybe the parks plugs needed to be replaced. No, that didn’t fix the problem completely, but it was a start in the right direction.
Science operates the same way. A theory that is developed may work for a while, but then there are data that the theory cannot explain. This means that it’s time for a newer and more inclusive theory.
Figure 1. Bohr model of the atom: electron is shown transitioning from the n = 3 energy level to the n = 2 energy level. The photon of light that is emitted has a frequency that corresponds to the difference in energy between the two levels.
Bohr’s model explains the spectral lines of the hydrogen atomic emission spectrum. While the electron of the atom remains in the ground state, its energy is unchanged. Os application download. When the atom absorbs one or more quanta of energy, the electron moves from the ground state orbit to an excited state orbit that is further away. Energy levels are designated with the variable n. The ground state is n = 1, the first excited state is n = 2, and so on. The energy that is gained by the atom is equal to the difference in energy between the two energy levels. When the atom relaxes back to a lower energy state, it releases energy that is again equal to the difference in energy of the two orbits (see Figure 1).
The change in energy, ΔE, then translates to light of a particular frequency being emitted according to the equation E = hv. Recall that the atomic emission spectrum of hydrogen had spectral lines consisting of four different frequencies. This is explained in the Bohr model by the realization that the electron orbits are not equally spaced. As the energy increases further and further from the nucleus, the spacing between the levels gets smaller and smaller.
Based on the wavelengths of the spectral lines, Bohr was able to calculate the energies that the hydrogen electron would have in each of its allowed energy levels. Ibackup extractor reddit app. He then mathematically showed which energy level transitions corresponded to the spectral lines in the atomic emission spectrum ( Figure 2).
Figure 2. The electron energy level diagram for the hydrogen atom.
He found that the four visible spectral lines corresponded to transitions from higher energy levels down to the second energy level (n Sellick piggyback forklift for sale. = 2). This is called the Balmer series. Transitions ending in the ground state (n = 1) are called the Lyman series, but the energies released are so large that the spectral lines are all in the ultraviolet region of the spectrum. The transitions called the Paschen series and the Brackett series both result in spectral lines in the infrared region because the energies are too small.
Bohr’s model was a tremendous success in explaining the spectrum of the hydrogen atom. Unfortunately, when the mathematics of the model was applied to atoms with more than one electron, it was not able to correctly predict the frequencies of the spectral lines. While Bohr’s model represented a great advancement in the atomic model and the concept of electron transitions between energy levels is valid, improvements were needed in order to fully understand all atoms and their chemical behavior.
Summary
- Emission lines for hydrogen correspond to energy changes related to electron transitions.
- The Bohr model works only for the hydrogen atom.
Practice
Use the link below to answer the following questions:
- How many volts can be used to generate a hydrogen line spectrum?
- Can you see the Lyman series with the naked eye?
- Which series can we at least partially see?
- What happens to the hydrogen gas in a discharge tube?
Review
- What happens when a hydrogen atoms absorbs one or more quanta of energy?
- How do we detect the change in energy?
- What electron transitions are presented by the lines of the Paschen series?
- Does the Bohr model work for atoms other than hydrogen?
Glossary
- electron transition: Movement of an electron from one energy level to another.
References
Paschen Series
- 1588877/Pixabay. https://pixabay.com/en/car-engine-tuned-engine-1044236/.
- CK-12 Foundation – Zachary Wilson.
- CK-12 Foundation – Christopher Auyeung.