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Wavelength and Frequency | 18 mins | 0 completed | Learn |

Diffraction vs Refraction | 5 mins | 0 completed | Learn |

The Particle Nature of Light | 10 mins | 0 completed | Learn |

Photoelectric Effect | 4 mins | 0 completed | Learn Summary |

De Broglie Wavelength | 8 mins | 0 completed | Learn |

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Electromagnetic Spectrum |

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Wave Function |

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**Heisenberg's Uncertainty Principle **tries to explain the potential duality of an electron behaving as either a particle or wave.

Heisenberg's Uncertainty Principle illustrates that an electron can behave as a particle or as a wave, but never both simultaneously.

Concept #2: To illustrate this dual nature of an electron Heisenberg created his Uncertainty or Indeterminacy Principle

Example #1: An electron has an uncertainty in its position of 630 pm. What is the uncertainty in its velocity?

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Concept #1: Heisenberg Uncertainty Principle

Concept #2: Heisenberg Uncertainty Principle

Example #1: Heisenberg Uncertainty Principle

An electron has an uncertainty in its position of 552 pm. What is the uncertainty in its velocity?

An electron traveling at 3.7 x 10 5 m/s has an uncertainty in its velocity of 1.88 x 10 5 m/s. What is the uncertainty in its position.

According to the Heisenberg uncertainity principle , if the uncertainity in the speed of an electron is 3.5 x 103 m/s, the uncertainity in its position (in m) is at least:
A) 66 m
B) 1.7 x 10-8 m
C) 17 m
D) 2.1 x 10-10 m
E) 6.6 x 10-8 m

According to the Heisenberg uncertainty principle, if the uncertainty in the speed of an electron is 3.5 x 103 m/s, the uncertainty in its position (in m) is at least (mass electron = 9.11 x 10-31 kg) __.
A) 1.7 x 10-8 m
B) 6.6 x 10-8 m
C) 17 m
D) 66 m
E) None of these choices is correct

An alpha particle with mass = 6.6 x 10 −24 g moves at a speed of 1.52 x 10 7 ± 0.03 m/s. What is the minimum uncertainty of its position?
a) 2.66 x 10 −10 m
b) 2.66 x 10 −7 m
c) 6.54 x 10 −3 m
d) 8.54 x 10 −3 m
e) 1.75 x 12 −5 m

Why does the uncertainty principle make it impossible to predict a trajectory for the electron?a. Because you cannot know both the position and velocity of the electron simultaneously.b. Because you cannot know both the position and force acting on the electron simultaneously.c. Because you cannot know the velocity of the electron.d. Because you cannot know the force acting on the electron.e. Because you cannot know both the velocity and force acting on the electron simultaneously.f. Because you cannot know the position of the electron.

Using Heisenberg’s uncertainty principle, calculate the uncertainty in the position of (a) a 1.50-mg mosquito moving at a speed of 1.40 m/s if the speed is known to within ∓0.01 m/s

Using Heisenberg’s uncertainty principle, calculate the uncertainty in the position of (b) a proton moving at a speed of (5.00 ± 0.01) x 104 m/s.

Calculate the uncertainty in the position of (a) an electron moving at a speed of (3.00 ∓ 0.01) x 105 m/s

Calculate the uncertainty in the position of (b) a neutron moving at this same speed. (The masses of an electron and a neutron are given in the table of fundamental constants)

Calculate the uncertainty in the position of (a) an electron moving at a speed of (3.00 ∓ 0.01) x 105 m/s, (b) a neutron moving at this same speed. (The masses of an electron and a neutron are given in the table of fundamental constants in the inside cover of the text.) (c)What are the implications of these calculations to our model of the atom?

To what uncertainty (in m) can the position of a baseball traveling at 45.0 m/s be measured if the uncertainty of its speed is 0.10%? The mass of a baseball is about 0.145 kg.
a. 8.1 x 10-33 m
b. 5.6 x 10-15 m
c. 6.7 x 10-45 m
d. 5.9 x 10-14 m
e. 4.4 x 10-65 m

In the television series Star Trek, the transporter beam is a device used to "beam down" people from the Starship Enterprise to another location, such as the surface of a planet. The writers of the show put a "Heisenberg compensator" into the transporter beam mechanism.Explain why such a compensator would be necessary to get around Heisenberg's uncertainty principle.

What is the uncertainty of the position of the bacterium?A student is examining a bacterium under the microscope. The E. coli bacterial cell has a mass of m = 1.70 fg (where a femtogram, fg, is 10−15 g) and is swimming at a velocity of v = 8.00 μm/s, with an uncertainty in the velocity of 8.00%. E. coli bacterial cells are around 1 μm (10−6 m) in length. The student is supposed to observe the bacterium and make a drawing. However, the student, having just learned about the Heisenberg uncertainty principle in physics class, complains that she cannot make the drawing. She claims that the uncertainty of the bacterium's position is greater than the microscope's viewing field, and the bacterium is thus impossible to locate.

By looking at the uncertainty of the bacterium's position, did the student have a valid point?A) The student has a point. The uncertainty of the bacterium's position is much larger than the bacterium itself.B) The bacterium's size and the uncertainty of its position are about the same magnitude. The student should have little trouble finding the bacterium in the microscopeC) The student is wrong. The uncertainty of the bacterium's position is tiny compared to the size of the bacterium itself.A student is examining a bacterium under the microscope. The E. coli bacterial cell has a mass of m = 1.70 fg (where a femtogram, fg, is 10−15 g) and is swimming at a velocity of v = 8.00 μm/s, with an uncertainty in the velocity of 8.00%. E. coli bacterial cells are around 1 μm (10−6 m) in length. The student is supposed to observe the bacterium and make a drawing. However, the student, having just learned about the Heisenberg uncertainty principle in physics class, complains that she cannot make the drawing. She claims that the uncertainty of the bacterium's position is greater than the microscope's viewing field, and the bacterium is thus impossible to locate.

By looking at the uncertainty of the bacterium's position, did the student have a valid point? A student is examining a bacterium under the microscope. The E. coli bacterial cell has a mass of m = 1.20 fg (where a femtogram, fg, is 10-15g) and is swimming at a velocity of v = 7.00 μm/s , with an uncertainty in the velocity of 6.00 % . E. coli bacterial cells are around 1 μm ( 10-6 m) in length. The student is supposed to observe the bacterium and make a drawing. However, the student, having just learned about the Heisenberg uncertainty principle in physics class, complains that she cannot make the drawing. She claims that the uncertainty of the bacterium's position is greater than the microscope's viewing field, and the bacterium is thus impossible to locate.What is the uncertainty of the position of the bacterium? Express your answer with the appropriate units.

An electron has an uncertainty in its position of 552 pm. What is minimum possible value for the uncertainty in its velocity?a. 1.05 x 105 m/sb. 1.46 x 106 m/sc. 3.40 x 106 m/sd. 8.87 x 106 m/se. 2.21 x 107 m/s

According to the Heisenberg uncertainty principle, if the uncertainty in the speed of an electron is 3.5 x 103 m/s, the uncertainty in its position (in m) is at least.66 m 17 m 6.6 x 10-8 m 1.7 x 10-8 m 2.1 x 10-10 m

An electron has an uncertainty in its position of 190 pm. What is its uncertainty in its velocity?272 x 103 m/s 1.12 x 105 m/s 521 x 105 m/s 4.21 x 102 m/s 305 x 103 m/s

A student is examining a bacterium under the microscope. The E. coli bacterial cell has a mass of = 0.500 (where a femtogram,fg , is 10-15 g) and is swimming at a velocity of v = 9.00 um/s, with an uncertainty in the velocity of 8.00 %. E. coli bacterial cells are around 1 um (10-6m ) in length. The student is supposed to observe the bacterium and make a drawing. However, the student, having just learned about the Heisenberg uncertainty principle in physics class, complains that she cannot make the drawing. She claims that the uncertainty of the bacterium's position is greater than the microscope's viewing field, and the bacterium is thus impossible to locate.What is the uncertainty of the position of the bacterium? Express your answer numerically in meters.

The 2005 Nobel Prize in Physics was given, in part, to scientists who had made ultrashort pulses of light. These pulses are important in making measurements involving very short time periods. One challenge in making such pulses is the uncertainty principle, which can be stated with respect to energy and time as ΔE • Δt ≥ h/4πlarge{Delta EcdotDelta t ge frac{
m h}{4pi}}. What is the energy uncertainty (ΔE) associated with a short pulse of laser light that lasts for only 5.1 femtoseconds (fs)? Suppose the low-energy end of the pulse had a wavelength of 713 nm.

Which of the following statements is FALSE? A) Part of the Bohr model proposed that electrons in the hydrogen atom are located in "stationary states" or particular orbits around the nucleus. B) An orbital is the volume in which we are most likely to find an electron. C) The Heisenberg uncertainty principle implies that we can never know both the exact location and speed of an electron. D) The emission spectrum of a particular element is always the same and can be used to identify that element. E) Light has properties of both waves and particles, but electrons never behave like waves.

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