**Understanding Wave Properties in Quantum Mechanics****Why must we consider the wave properties of an electron, but not the wave properties of macroscopic objects (such as humans)?*** The wavelength of the electron is similar in size to the atom and affects its properties, whereas the wavelength of the macroscopic object is much smaller than the object and does not affect its properties.* We cannot tell if electrons are waves or particles because they are too small to see. Since we can see macroscopic objects, we can confirm that they are not waves.* We can calculate the wavelength of an electron but cannot calculate the wavelength for a macroscopic object using the de Broglie equation.* Only very small pieces of matter (such as electrons) are waves, whereas macroscopic objects are not.

The correct answer is 1) The wavelength of the electron is size-intrinsic to the atom and affects…

Why must we consider the wave properties of an electron, but not the wave properties of macroscopic objects (such as humans)? O The wavelength of the electron is similar in size to the atom and affects its properties, whereas the wavelength of the macroscopic object is much smaller than the object and does not affect its properties. O We cannot tell if electrons are waves or particles because they are too small to see. Since we can see macroscopic objects, we can confirm that they are not waves. O We can calculate the wavelength of an electron but cannot calculate the wavelength for a macroscopic object using the de Broglie equation. O Only very small pieces of matter (such as electrons) are waves, whereas macroscopic objects are not.

Why must we consider the wave properties of an electron, but not the wave properties of macroscopic objects (such as humans)? O The wavelength of the electron is similar in size to the atom and affects its properties, whereas the wavelength of the macroscopic object is much smaller than the object and does not affect its properties. O We cannot tell if electrons are waves or particles because they are too small to see. Since we can see macroscopic objects, we can confirm that they are not waves. O We can calculate the wavelength of an electron but cannot calculate the wavelength for a macroscopic object using the de Broglie equation. O Only very small pieces of matter (such as electrons) are waves, whereas macroscopic objects are not.

Chemistry

10th Edition

ISBN:9781305957404

Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Publisher:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Chapter1: Chemical Foundations

Section: Chapter Questions

Problem 1RQ: Define and explain the differences between the following terms. a. law and theory b. theory and...

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