A laser pulse with wavelength 510 nm contains 4.85 mJ of energy.
0%
1.24×10^16
0%
1.60×10^143.16×10^157.40×10^134.02×10^13
0%
n=3,l=2,ml=3
0%
6.06 nm
Q.2.
List the following types of electromagnetic radiation in order of increasing wavelength.List the following types of electromagnetic radiation in order of increasing energy per photon.
Which set of quantum numbers cannot specify an orbital?
0%
1.24×10^16
0%
6.06 nm
0%
an electron in a 2s orbital
0%
n=3,l=2,ml=3
Q.4.
According to the quantum-mechanical model for the hydrogen atom, which of the following electron transitions would produce light with the longer wavelength: 2p→1s or 3p→1s?
0%
2p→1s
0%
1.60×10^143.16×10^157.40×10^134.02×10^13
0%
t= 760s
0%
344 nm
Q.5.
The distance from the sun to Mars is 2.279×108 km .How long does it take light to travel from the sun to Mars?
0%
t= 760s
0%
1.24×10^16
0%
6.06 nm
0%
2p→1s
Q.6.
Which electron is, on average, closer to the nucleus: an electron in a 2s orbital or an electron in a 3s orbital?
0%
n=3,l=2,ml=3
0%
6.15x10^142.45×10^95.77×10^18
0%
1.60×10^143.16×10^157.40×10^134.02×10^13
0%
an electron in a 2s orbital
Q.7.
Calculate the energy of a photon of electromagnetic radiation at each of the following wavelengths.632.8 nm (wavelength of red light from a helium-neon laser)12.24 cm (wavelength of a microwave oven)337.1 nm (wavelength of a nitrogen laser)
0%
2.18×10^−18 J 91.2 nm
0%
6.15x10^142.45×10^95.77×10^18
0%
3.14×10^−191.63×10^−245.90×10^−19
0%
1.60×10^143.16×10^157.40×10^134.02×10^13
Q.8.
Calculate the frequency of the light emitted when an electron in a hydrogen atom makes each of the following transitions.n=4→n=3n=5→n=1n=5→n=4n=6→n=5
0%
1.60×10^143.16×10^157.40×10^134.02×10^13
0%
3.14×10^−191.63×10^−245.90×10^−19
0%
6.15x10^142.45×10^95.77×10^18
0%
1.24×10^16
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