We saw that, on Earth, the number flux of solar neutrinos from the p-p chain is 6.7E10 s-1 cm-2. Other nuclear reactions in the Sun supplement this neutrino flux with a small additional flux of higher-energy neutrinos. A neutrino detector in Japan, named Super Kamiokande, consists of a tank of 50kton of water, surrounded by photomultiplier tubes. The tubes detect the flash of Cerenkov radiation emitted by a recoiling electron when a high-energy neutrino scatters on it. Calculate the detection rate for neutrino scattering in events per day, if 10-6 of the solar neutrinos have a high enough energy to be detected by this experiment, and each electron poses a scattering cross section=10-43 cm. Hint: Consider the density of neutrino targets "seen" by an individual electron, with a relative velocity of c between the neutrinos and the electron, to obtain the rate at which one electron interacts with the incoming neutrinos, and multiply by the total number of electrons (I've already done this: 1.4E34 electrons) to obtain the rate in the entire detector.

We saw that, on Earth, the number flux of solar neutrinos from the p-p chain is 6.7E10 s-1 cm-2. Other nuclear reactions in the Sun supplement this neutrino flux with a small additional flux of higher-energy neutrinos. A neutrino detector in Japan, named Super Kamiokande, consists of a tank of 50kton of water, surrounded by photomultiplier tubes. The tubes detect the flash of Cerenkov radiation emitted by a recoiling electron when a high-energy neutrino scatters on it. Calculate the detection rate for neutrino scattering in events per day, if 10-6 of the solar neutrinos have a high enough energy to be detected by this experiment, and each electron poses a scattering cross section=10-43 cm. Hint: Consider the density of neutrino targets "seen" by an individual electron, with a relative velocity of c between the neutrinos and the electron, to obtain the rate at which one electron interacts with the incoming neutrinos, and multiply by the total number of electrons (I've already done this: 1.4E34 electrons) to obtain the rate in the entire detector.

Related questions

Q: About 2% of the energy generated in the Sun’s core by the p-p reaction is carried out of the Sun by…

A: The overall p-p reaction can be given as follows

Q: The power output of the Sun is 4 × 1026 W. Part (a) If 93 % of this is supplied by the…

A: Power output of the Sun is The amount of power supplied in proton-proton cycle is Note:Distance…

Q: A(n) 12-kg particle has energy 14,026 kg c2. Calculate gamma (γ)

Q: Suppose you use a photon with a wavelength of 4.65 m in an MRI machine to transfer a nucleus between…

A: Given quantities: wavelength of the photon (λ) = 4.65 m Let, the Planck's constant be denoted as…

Q: What is the total energy of all the radiation in the current Hubble Radius (Length)? Assume H0=70…

Q: Why wouldn't you expect to detect strong 21 cmt emission from an HIl region?

A: The 21 cm line corresponds to the wavelength of hydrogen gas. At 1420 Mhz the radiation released by…

Q: The 2-H formed in the first reaction has less mass than the two 1-H that form it; the missing mass…

A: Two hydrogen atoms combine via a fusion reaction to form a single deuterium atom, the reaction…

Q: The power output of the Sun is 4 × 1026 W. Part (a) If 88 % of this is supplied by the…

Q: While monitoring the solar wind at 1 A.U. we notice an abrupt increase in the magnetic field…

A: Given :-the solar wind at 1 A.U. we notice an abrupt increase in the magnetic field strength and…

Q: Compare the energy produced per kg of fuel for the combustion of coal, d-d fusion and d-t fusion

A: Energy released in 1 kg of coal is about 30 MJ For d-d : 7.9×107 MJ/kg For d-T : 3.4×108 MJ/kg

Q: How much energy (in x 1016 Joule) does the Sun burn 1 kg of hydrogen fuel in a nuclear reaction?

A: Given data: Mass of hydrogen fuel, m=1 kg Speed of light, c=3×108m/s

Q: Why is it important to measure neutrinos and positrons coming from the sun?

A: Neutrinos are subatomic particles that are created in nuclear reactions, such as those that occur in…

Q: What is the difference between fision and fusion? Fission is about one nucleus breaking apart while…

A: Fission : The phenomenon of splitting of a heavy , unstable nucleus into two or more lighter nuclei…

Q: Most radiation detectors are gas-filled and solid-state detectors, but liquid scintillation…

A: Gas filled detectors are one of the most commonly used radiation detectors. They work on the general…

Q: Exercise 2. Electrons in the outer and inner Van Allen radiation belts have energy as listed below.…

A: Given that, Outer radiation belt: Ek = 4.0 x 10^4 eV Inner radiation belt: Ek = 1.6 x 10^6 eV

Q: Tc-MAA has a physical half-life of 6 hours and a biological half-life of 2 hours. What is its…

A: Given: The physical half life is 6 hours. The biological half life is 6 hours. To…

Q: For 208Fr, what is the contribution of the asymmetry term in the binding energy formula of the…

Q: The fusion reaction shown is part of the proton-proton chain that occurs in the core of the sun.

Q: 2310Ne is unstable. Complete the schematic energy diagram to the right by drawing in the protons…

Q: Cs137 emit a gamma ray of energy 663 KeV. Describe th

A: Cs 137 emit gamma rays of energy 663 KeV. a) Energy resolution: This converts channel number to the…

Q: Recall that the solar constant-the flux of solar energy reaching Earth's vicinity- is about 1380…

Q: If a gamma ray from super nova emission has a packet of 10^20photon per one second, the wavelength…

Question

We saw that, on Earth, the number flux of solar neutrinos from the p-p chain is 6.7E10 s^-1 cm^-². Other nuclear reactions in the Sun supplement this neutrino flux with a small additional flux of higher-energy neutrinos. A neutrino detector in Japan, named Super Kamiokande, consists of a tank of 50kton of water, surrounded by photomultiplier tubes. The tubes detect the flash of Cerenkov radiation emitted by a recoiling electron when a high-energy neutrino scatters on it. Calculate the detection rate for neutrino scattering in events per day, if 10^-6 of the solar neutrinos have a high enough energy to be detected by this experiment, and each electron poses a scattering cross section=10^-43 cm. Hint: Consider the density of neutrino targets "seen" by an individual electron, with a relative velocity of c between the neutrinos and the electron, to obtain the rate at which one electron interacts with the incoming neutrinos, and multiply by the total number of electrons (I've already done this: 1.4E34 electrons) to obtain the rate in the entire detector.

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

This is a popular solution!

SEE SOLUTION Check out a sample Q&A here

Step 1

VIEW

Step 2

VIEW

Trending now

This is a popular solution!

Step by step

Solved in 2 steps with 5 images

SEE SOLUTION Check out a sample Q&A here

Similar questions

Why was the Davis experiment only able to detect one-third of the neutrinos originally predicted? Most of the neutrinos were absorbed by Earth’s atmosphere. The neutrinos combined with other particles as they entered Earth’s atmosphere. The neutrinos distributed evenly among three different flavors while traveling to Earth. The number of neutrinos was too great to be held in the tank that Davis designed. The other two-thirds of neutrinos dissipated while traveling to Earth.
please answer fully
Fermi’s original reactor was just “barely” critical because the natural uranium that he used contained less than 1% of the fissionable isotope U-235 (half-life 713 million years). What if, in 1942, Earth had been 9 billion years old instead of 4.5 billion years old. Would Fermi have been able to make a reactor go critical with natural uranium?
The radio-active decay reaction is given by e¯ +e* →y+y. Calculate the wavelength of y photon produced in the given radio-active decay.
Why is uranium-235 used in nuclear fission? why is uranium-235 one of the only elements ideal for nuclear fission to create energy? Is there a link between its stability and its size?
Question: The radionuclide Tc-99m is a gamma photon emitter. The emitted gamma photonenergy is 141 keV. The scintillation crystal in a Gamma camera will convert the single gammaphoton to a burst of visible photons. Assuming the generated visible photons wavelength is 550nm, calculate how many visible 550-nm photons will have the same amount of energy as a single141-keV gamma photon?
how did we find ca(t) and cb(t)? please explain in detail
true or false: The maximum energy of the ejected electrons is proportional to the velocity of the photons.
(a) Calculate the rate at which the Sun generates neutrinos. Assume that energy production is entirely by the proton–proton fusion cycle. (b) At what rate do solar neutrinos reach Earth?
A robot spacecraft returned samples from the planetesimal 98765 ALEKS, located in the outer Solar System. Mass-spectroscopic analysis produced the following data on the isotopes of tin in these samples: isotope 118 "Sn 120 Sn Use these measurements to complete the entry for tin in the Periodic Table that would be used on 98765 ALEKS. Be sure your answers have the correct number of significant digits. Caution: your correct answer will have the same format but not necessarily the same numbers as the entry for tin in the Periodic Table we use here on Earth. 0 Sn mass relative (amu) abundance 117.9 54.% 0 119.9 Continue 46.% X S evee muuraw Hill LLC. All Rights Reserved. Submit Assignment Terms of Use | Privacy Center Accessibility
Hypothetically if the 100W bulb only produced green light, and 10% of the energy consumed was used to produce green light (λ=500nm), the number of green photons produced each second is ___x1019
Sr-90 (A=90, Z = 38) decays via B decay. Calculate the energy of the antineutrino (in keV) if the beta particle has a kinetic energy of (2.82x10^2) keV. %3D Note you can look the atomic masses up online or in the appendix of the textbook 1, Assume all the energy released are shared by the kinetic energy of the beta particle and antineutrino. Note: Your answer is assumed to be reduced to the highest power possible. Your Answer: х10 Answer