PHY3702 Assignment 1 Solutions Year Module 2026 |Quantum Physics|

UNIVERSITY OF SOUTH AFRICA
College of Science, Engineering and Technology


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PHY3702

Assignment:1

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PHY3702
Module:
Quantum Physics
Module Name
1
Assignment:
2026
Due Date:




Submitted in partial fulfilment of the requirements — UNISA

,UNISA | PHY3702 Assignment: 1



Question 1: Blackbody Radiation — Stefan-Boltzmann and Wien’s Laws


Question


Assuming that a given star radiates like a blackbody, estimate:

(a) the temperature at its surface,
(b) the wavelength of its strongest radiation,

when it emits a total intensity of I = 575 MW m−2 .


Solution


Given:
I = 575 MW m−2 = 575 × 106 W m−2


The Stefan-Boltzmann constant:


σ = 5.67 × 10−8 W m−2 K−4



The Stefan-Boltzmann law states:
I = σT 4


(a) Temperature at the Surface


Rearranging for T 4 :
I
T4 =
σ

Substituting values:
575 × 106
T4 =
5.67 × 10−8



T 4 = 1.0141 × 1016 K4


Taking the fourth root:

1/4
T = 1.0141 × 1016


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, UNISA | PHY3702 Assignment: 1




T ≈ 1.00 × 104 K


(b) Wavelength of Strongest Radiation


Wien’s displacement law states:


λmax T = 2.898 × 10−3 m K



Therefore:
2.898 × 10−3
λmax =
T

Substituting T = 1.00 × 104 K:
2.898 × 10−3
λmax =
1.00 × 104



λmax = 2.898 × 10−7 m




λmax ≈ 289 nm


This wavelength falls in the ultraviolet region of the electromagnetic spectrum.

Implementation Insight
Physical Meaning: A surface temperature of approximately 10,000 K is characteristic
of a hot blue-white star such as Vega or Sirius A. The peak wavelength of 289 nm
confirms emission primarily in the ultraviolet, consistent with stars of spectral class A.




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