Uncovering the Randomness of Thermal Noise and Nuclear Decay

In summary: Sure. In accordance with the Heisenberg Uncertainty Relations, there are plenty of things that will take on a random distribution of values when a non-commuting attribute is held constant. A common example is taking a photon of known polarization and passing it through a polarizing beam splitter aligned 45 degrees from the known value. This will yield a truly random stream of photons (as to their new polarization). As far as anyone knows, the input photons are identical and there is no known "cause" that leads any photon to go one path or the other through the beam splitter. Of course, that doesn't stop folks from speculating that there is a cause. Other than our desire to
  • #1
countrymac
2
0
1. Is thermal noise truly random?
By truly random I mean can you not predict the next value even if you knew everything permitted about the electrons producing the effect.

Does this follow from the math of quantum physics?

2. What about nuclear decay is it truly random?
 
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  • #2
I don't think there is such a thing as truly random. Maby something could be so random we could never hope to work out the pattern.
 
  • #3
countrymac said:
1. Is thermal noise truly random?
By truly random I mean can you not predict the next value even if you knew everything permitted about the electrons producing the effect.

Does this follow from the math of quantum physics?

2. What about nuclear decay is it truly random?

Yes to both 1 and 2.
Whether or not anything is "truly random" is a philosophical question. However, QM does not allow us predict e.g. when a decay even will occur even in principle .
Hence, from a formal and mathematical point of view the answer is yes to both questions.
 
  • #4
f95toli said:
Yes to both 1 and 2.
Whether or not anything is "truly random" is a philosophical question. However, QM does not allow us predict e.g. when a decay even will occur even in principle .
Hence, from a formal and mathematical point of view the answer is yes to both questions.

Thanks,
Is there anything else we know to be truly random?
 
  • #5
countrymac said:
Thanks,
Is there anything else we know to be truly random?

Sure. In accordance with the Heisenberg Uncertainty Relations, there are plenty of things that will take on a random distribution of values when a non-commuting attribute is held constant.

A common example is taking a photon of known polarization and passing it through a polarizing beam splitter aligned 45 degrees from the known value. This will yield a truly random stream of photons (as to their new polarization). As far as anyone knows, the input photons are identical and there is no known "cause" that leads any photon to go one path or the other through the beam splitter.

Of course, that doesn't stop folks from speculating that there is a cause. Other than our desire to have a cause for explanatory purposes, there is no supporting evidence for quantum causality in these cases.
 

1. What is thermal noise?

Thermal noise is random fluctuations in electronic systems caused by the thermal agitation of electrons. It is also known as Johnson-Nyquist noise and is present in all electronic components and circuits.

2. How is thermal noise measured?

Thermal noise is measured using a device called a spectrum analyzer, which measures the power of the noise at different frequencies. The measurement is usually expressed in decibels (dB) or as a root mean square (RMS) voltage.

3. What is the relationship between thermal noise and temperature?

The amplitude of thermal noise is directly proportional to the temperature of the system. This means that as the temperature increases, the thermal noise also increases. This relationship is described by the Johnson-Nyquist equation, which states that the power of thermal noise is equal to a constant multiplied by the temperature in Kelvin.

4. How does thermal noise affect electronic systems?

Thermal noise can affect electronic systems in several ways. It can reduce the signal-to-noise ratio, which can lead to errors in data transmission. It can also cause interference and distortion in analog signals, affecting the overall performance of the system.

5. What is the connection between thermal noise and nuclear decay?

Thermal noise is one of the main sources of noise in nuclear decay experiments. The random fluctuations caused by thermal noise can affect the accuracy of measurements of nuclear decay rates. This is why it is important for scientists to understand and account for thermal noise in their experiments.

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