Textbook Question
INT A beam of electrons is incident upon a gas of hydrogen atoms. Through what potential difference must the electrons be accelerated to have this speed?
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Ch 38: Quantization
Knight Calc5th EditionPhysics for Scientists and EngineersISBN: 9780137344796
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Table of contents
- Ch 01: Concepts of Motion35
- Ch 02: Kinematics in One Dimension75
- Ch 03: Vectors and Coordinate Systems58
- Ch 04: Kinematics in Two Dimensions60
- Ch 05: Force and Motion23
- Ch 06: Dynamics I: Motion Along a Line53
- Ch 07: Newton's Third Law27
- Ch 08: Dynamics II: Motion in a Plane52
- Ch 09: Work and Kinetic Energy56
- Ch 10: Interactions and Potential Energy50
- Ch 11: Impulse and Momentum56
- Ch 12: Rotation of a Rigid Body71
- Ch 13: Newton's Theory of Gravity52
- Ch 14: Fluids and Elasticity44
- Ch 15: Oscillations55
- Ch 16: Traveling Waves37
- Ch 17: Superposition39
- Ch 18: A Macroscopic Description of Matter53
- Ch 19: Work, Heat, and the First Law of Thermodynamics60
- Ch 20: The Micro/Macro Connection53
- Ch 21: Heat Engines and Refrigerators34
- Ch 22: Electric Charges and Forces40
- Ch 23: The Electric Field39
- Ch 24: Gauss' Law32
- Ch 25: The Electric Potential63
- Ch 26: Potential and Field57
- Ch 27: Current and Resistance42
- Ch 28: Fundamentals of Circuits39
- Ch 29: The Magnetic Field47
- Ch 30: Electromagnetic Induction60
- Ch 31: Electromagnetic Fields and Waves32
- Ch 32: AC Circuits63
- Ch 33: Wave Optics32
- Ch 34: Ray Optics57
- Ch 35: Optical Instruments30
- Ch 36: Special Relativity38
- Ch 37: The Foundations of Modern Physics25
- Ch 38: Quantization49
- Ch 39: Wave Functions and Uncertainty31
- Ch 40: One-Dimensional Quantum Mechanics35
- Ch 41: Atomic Physics18
- Ch 42: Nuclear Physics27
Knight Calc5th EditionPhysics for Scientists and EngineersISBN: 9780137344796Not the one you use?Change textbook
Chapter 38, Problem 64
Very large, hot stars—much hotter than our sun—can be identified by the way in which He+ ions in their atmosphere absorb light. What are the three longest wavelengths, in nm, in the Balmer series of He+?
Verified step by step guidance1
Step 1: Understand the Balmer series. The Balmer series corresponds to electronic transitions in hydrogen-like atoms where the electron moves from a higher energy level (n > 2) to the n = 2 energy level. For He+, the nucleus has a charge of +2, so the energy levels are scaled by a factor of Z², where Z is the atomic number (Z = 2 for helium).
Step 2: Use the Rydberg formula to calculate the wavelengths of the transitions. The formula is: , where λ is the wavelength, R is the Rydberg constant (approximately 1.097 × 10⁷ m⁻¹), Z is the atomic number, n₁ is the lower energy level (n₁ = 2 for the Balmer series), and n₂ is the higher energy level (n₂ > n₁).
Step 3: Identify the three longest wavelengths. The longest wavelengths correspond to the smallest energy transitions, which occur when n₂ = 3, n₂ = 4, and n₂ = 5. Substitute these values into the Rydberg formula one at a time to calculate the wavelengths.
Step 4: Convert the calculated wavelengths from meters to nanometers. Since 1 nm = 10⁻⁹ m, multiply the result of each calculation by 10⁹ to express the wavelengths in nanometers.
Step 5: Summarize the results. The three longest wavelengths in the Balmer series of He+ correspond to the transitions from n₂ = 3, n₂ = 4, and n₂ = 5 to n₁ = 2. These wavelengths are expressed in nanometers after conversion.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Balmer Series
The Balmer series refers to the set of spectral lines corresponding to transitions of electrons in hydrogen atoms from higher energy levels to the second energy level. Although the question pertains to He+, the concept is similar, as it involves electron transitions that emit or absorb light at specific wavelengths. The Balmer series is crucial for understanding how light interacts with ions and can be used to identify the presence of elements in stellar atmospheres.
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Ionization and Electron Transitions
Ionization occurs when an atom or molecule gains enough energy to remove an electron, resulting in a positively charged ion. In the case of He+, the ion has lost one electron, and its electron transitions between energy levels lead to the absorption or emission of light at specific wavelengths. Understanding these transitions is essential for determining the wavelengths in the Balmer series and analyzing the light spectrum from stars.
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Wavelength and Spectroscopy
Wavelength is the distance between successive peaks of a wave, typically measured in nanometers (nm) for light. Spectroscopy is the study of how light interacts with matter, allowing scientists to analyze the composition and properties of celestial objects. By examining the wavelengths of light absorbed or emitted by ions like He+, astronomers can infer the physical conditions and elemental makeup of stars, including their temperature and size.
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Related Practice
Textbook Question
Draw an energy-level diagram, similar to Figure 38.21, for the He+ ion. On your diagram: Show the ionization limit.
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Textbook Question
Draw an energy-level diagram, similar to Figure 38.21, for the He+ ion. On your diagram: Show the first five energy levels. Label each with the values of n and En.
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Textbook Question
Draw an energy-level diagram, similar to Figure 38.21, for the He+ ion. On your diagram: Show all possible emission transitions from the n = 4 energy level.
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Textbook Question
INT A beam of electrons is incident upon a gas of hydrogen atoms. What minimum speed must the electrons have to cause the emission of 656 nm light from the 3→2 transition of hydrogen?
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Textbook Question
INT Two hydrogen atoms collide head-on. The collision brings both atoms to a halt. Immediately after the collision, both atoms emit a 121.6 nm photon. What was the speed of each atom just before the collision?
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