The σ2s orbital is lower in energy than the π2p and σ2p orbitals in homonuclear diatomic molecules.

In O2, the highest occupied molecular orbital (HOMO) is π2p.

The highest energy orbital in O2 is σ*2p, which is an antibonding orbital.

s and s orbitals can combine to form a sigma bond.

Sigma bonds are formed by the head-on overlap of s and p orbitals.

The leading zeros are not significant, but the trailing zero is significant. Therefore, it has 4 significant figures.

The significant figures are 7, 8, 9, and the leading zeros are not counted.

Without a decimal point, 2500 has 2 significant figures.

4500 has 2 significant figures unless specified with a decimal point.

5000 has 1 significant figure unless specified with a decimal point (e.g., 5000.).

The kinetic energy of the emitted electrons is given by KE = hf - φ. If the frequency is doubled, the kinetic energy increases by a factor of four, since KE is proportional to the frequency.

Increasing the intensity of light increases the number of emitted electrons, as intensity is related to the number of photons hitting the surface.

The kinetic energy of the emitted electrons in the photoelectric effect depends on the frequency of the incident light, as per Einstein's photoelectric equation.

The work function is the minimum energy required to remove an electron from the surface of a metal.

The work function is the minimum energy required to remove an electron from the surface of the metal.

At the threshold frequency, the energy of the incident photons is equal to the work function, resulting in emitted electrons having zero kinetic energy.

The excess energy of the photon becomes the kinetic energy of the emitted photoelectrons.

The kinetic energy of emitted electrons remains the same as it depends on the frequency, not intensity.

The kinetic energy of emitted electrons increases linearly with the frequency of the incident light, according to the equation KE = hf - φ.

The kinetic energy of the emitted electrons increases with the frequency of the incident light, as given by the equation KE = hf - φ, where φ is the work function.

Increasing the frequency beyond the threshold increases the kinetic energy of the emitted electrons, as per the equation KE = hf - φ.

Increasing the wavelength decreases the frequency of the light, which reduces the energy of the incident photons, thus decreasing the kinetic energy of emitted electrons.

The kinetic energy of the emitted electron is equal to the energy of the incident photon minus the work function of the metal.

The frequency of light must be above a certain threshold to emit electrons, but once that is achieved, the photoelectric current depends on the intensity, not the frequency.

Zinc (Zn) is oxidized to Zn2+.

Ag+ is reduced as it gains electrons to form Ag.

In AgNO3, silver has an oxidation state of +1.

Zinc is oxidized from an oxidation state of 0 to +2.

Cr2O7^2- is reduced to Cr^3+, making it the oxidizing agent.

4 moles of Fe produce 4 moles of FeCl3. Mass of FeCl3 = 4 moles * 162.5 g/mole = 650 g.