201. A threshold-relation record is shown below.
| Row | Quantity | Relation for the same metal |
| P | Work function and threshold frequency | \(\phi_0=h\nu_0\) |
| Q | Work function and threshold wavelength | \(\phi_0=\frac{hc}{\lambda_0}\) |
| R | Threshold frequency and threshold wavelength | \(\nu_0\lambda_0=c\) |
| S | Threshold wavelength and work function | \(\lambda_0\propto\phi_0\) |
The mismatched row is
ⓐ. P
ⓑ. Q
ⓒ. R
ⓓ. S
Correct Answer: S
Explanation: Row P is correct because at threshold the photon energy \(h\nu_0\) equals the work function. Row Q is correct because using \(c=\nu_0\lambda_0\) gives \( \phi_0=\frac{hc}{\lambda_0} \). Row R is correct because threshold frequency and threshold wavelength refer to the same threshold radiation. Row S is mismatched because \( \lambda_0 \) is inversely proportional to \( \phi_0 \), not directly proportional to it. A metal with a larger work function needs a higher threshold frequency and therefore a smaller threshold wavelength.
202. The work function of a metal is \(2.8\,eV\). If \(h=4.0\times10^{-15}\,eV\,s\), the threshold frequency is
ⓐ. \(5.0\times10^{14}\,Hz\)
ⓑ. \(7.0\times10^{14}\,Hz\)
ⓒ. \(1.12\times10^{15}\,Hz\)
ⓓ. \(2.8\times10^{15}\,Hz\)
Correct Answer: \(7.0\times10^{14}\,Hz\)
Explanation: \( \textbf{Given work function:} \) \( \phi_0=2.8\,eV \).
\( \textbf{Planck constant:} \) \(h=4.0\times10^{-15}\,eV\,s\).
\( \textbf{Required quantity:} \) Threshold frequency \( \nu_0 \).
\( \textbf{Threshold relation:} \)
\[
\phi_0=h\nu_0
\]
\( \textbf{Rearrangement:} \)
\[
\nu_0=\frac{\phi_0}{h}
\]
\( \textbf{Substitution:} \)
\[
\nu_0=\frac{2.8}{4.0\times10^{-15}}\,s^{-1}
\]
\( \textbf{Coefficient:} \)
\[
\frac{2.8}{4.0}=0.70
\]
\( \textbf{Power of ten:} \)
\[
\frac{1}{10^{-15}}=10^{15}
\]
\( \textbf{Final simplification:} \)
\[
\nu_0=0.70\times10^{15}\,Hz=7.0\times10^{14}\,Hz
\]
\( \textbf{Final answer:} \) The threshold frequency is \(7.0\times10^{14}\,Hz\).
203. For threshold frequency \( \nu_0=5.0\times10^{14}\,Hz \), radiation of frequency \(8.0\times10^{14}\,Hz\) is incident on the same metal. If \(h=6.6\times10^{-34}\,J\,s\), \(K_{\max}\) is
ⓐ. \(1.98\times10^{-19}\,J\)
ⓑ. \(3.30\times10^{-19}\,J\)
ⓒ. \(5.28\times10^{-19}\,J\)
ⓓ. \(8.58\times10^{-19}\,J\)
Correct Answer: \(1.98\times10^{-19}\,J\)
Explanation: \( \textbf{Threshold frequency:} \) \( \nu_0=5.0\times10^{14}\,Hz \).
\( \textbf{Incident frequency:} \) \( \nu=8.0\times10^{14}\,Hz \).
\( \textbf{Planck constant:} \) \(h=6.6\times10^{-34}\,J\,s\).
\( \textbf{Useful relation:} \)
\[
K_{\max}=h(\nu-\nu_0)
\]
\( \textbf{Why this applies:} \) The work function is \(h\nu_0\), so only the excess frequency above threshold contributes to maximum kinetic energy.
\( \textbf{Frequency excess:} \)
\[
\nu-\nu_0=3.0\times10^{14}\,Hz
\]
\( \textbf{Substitution:} \)
\[
K_{\max}=(6.6\times10^{-34})(3.0\times10^{14})\,J
\]
\( \textbf{Coefficient product:} \)
\[
6.6\times3.0=19.8
\]
\( \textbf{Power of ten:} \)
\[
10^{-34}\times10^{14}=10^{-20}
\]
\( \textbf{Final simplification:} \)
\[
K_{\max}=19.8\times10^{-20}\,J=1.98\times10^{-19}\,J
\]
\( \textbf{Final answer:} \) \(K_{\max}=1.98\times10^{-19}\,J\), based on the excess frequency above threshold.
204. The formula \(K_{\max}=hc\left(\frac{1}{\lambda}-\frac{1}{\lambda_0}\right)\) is physically meaningful for photoemission when
ⓐ. \(\lambda\geq\lambda_0\)
ⓑ. \(\lambda=\frac{h}{p}\)
ⓒ. \(\lambda\nu_0=e\)
ⓓ. \(\lambda\leq\lambda_0\)
Correct Answer: \(\lambda\leq\lambda_0\)
Explanation: The formula compares incident photon energy \( \frac{hc}{\lambda} \) with the work function \( \frac{hc}{\lambda_0} \). For photoemission, the incident photon energy must be at least equal to the work function. This requires \( \lambda\leq\lambda_0 \), because shorter wavelength means higher photon energy. If \( \lambda\gt\lambda_0 \), the expression would give a negative value, which means no photoelectron is emitted rather than a negative kinetic energy. The wavelength condition is the reverse of the frequency condition because frequency and wavelength are inversely related.
205. For a threshold wavelength of \(500\,nm\), light of wavelength \(400\,nm\) falls on the metal. Using \(hc=1240\,eV\,nm\), the maximum kinetic energy is closest to
ⓐ. \(2.48\,eV\)
ⓑ. \(3.10\,eV\)
ⓒ. \(0.62\,eV\)
ⓓ. \(5.58\,eV\)
Correct Answer: \(0.62\,eV\)
Explanation: \( \textbf{Incident wavelength:} \) \( \lambda=400\,nm \).
\( \textbf{Threshold wavelength:} \) \( \lambda_0=500\,nm \).
\( \textbf{Given constant product:} \) \(hc=1240\,eV\,nm\).
\( \textbf{Incident photon energy:} \)
\[
E=\frac{hc}{\lambda}=\frac{1240}{400}\,eV=3.10\,eV
\]
\( \textbf{Work function:} \)
\[
\phi_0=\frac{hc}{\lambda_0}=\frac{1240}{500}\,eV=2.48\,eV
\]
\( \textbf{Maximum kinetic energy:} \)
\[
K_{\max}=E-\phi_0
\]
\( \textbf{Substitution:} \)
\[
K_{\max}=3.10\,eV-2.48\,eV
\]
\( \textbf{Result:} \)
\[
K_{\max}=0.62\,eV
\]
\( \textbf{Final answer:} \) The maximum kinetic energy is \(0.62\,eV\), and both wavelengths must be used through inverse wavelength.
206. A photoelectron has \(K_{\max}=1.6\,eV\). Using \(1\,eV=1.6\times10^{-19}\,J\), the maximum speed \(v_{\max}\) is found from
ⓐ. \(1.6(1.6\times10^{-19})\,J=\frac{1}{2}m_ev_{\max}^2\)
ⓑ. \(1.6(1.6\times10^{-19})\,J=m_ev_{\max}\)
ⓒ. \(1.6(1.6\times10^{-19})\,J=\frac{h}{m_ev_{\max}}\)
ⓓ. \(1.6(1.6\times10^{-28})\,J=\frac{1}{2}m_ev_{\max}^2\)
Correct Answer: \(1.6(1.6\times10^{-19})\,J=\frac{1}{2}m_ev_{\max}^2\)
Explanation: Maximum kinetic energy of a non-relativistic photoelectron is related to its maximum speed by \(K_{\max}=\frac{1}{2}m_ev_{\max}^2\). The right side is in joules when SI units are used, so \(1.6\,eV\) must first be converted into joules for a numerical speed calculation. Since \(1\,eV=1.6\times10^{-19}\,J\), the energy becomes \(1.6(1.6\times10^{-19})\,J\). The expression \(m_ev_{\max}\) represents momentum, not kinetic energy. The relation \(\frac{h}{m_ev_{\max}}\) belongs to de Broglie wavelength, not directly to speed from kinetic energy.
207. If incident radiation produces photoelectrons with stopping potential \(1.5\,V\) from a metal of work function \(2.0\,eV\), the incident photon energy and threshold-frequency relation are
ⓐ. \(h\nu=2.0\,eV\) and \(h\nu_0=3.5\,eV\)
ⓑ. \(h\nu=1.5\,eV\) and \(h\nu_0=2.0\,eV\)
ⓒ. \(h\nu=0.5\,eV\) and \(h\nu_0=1.5\,eV\)
ⓓ. \(h\nu=3.5\,eV\) and \(h\nu_0=2.0\,eV\)
Correct Answer: \(h\nu=3.5\,eV\) and \(h\nu_0=2.0\,eV\)
Explanation: \( \textbf{Work function:} \) \( \phi_0=2.0\,eV \).
\( \textbf{Stopping potential:} \) \(V_0=1.5\,V\).
\( \textbf{Maximum kinetic energy:} \)
\[
K_{\max}=eV_0=1.5\,eV
\]
\( \textbf{Einstein equation:} \)
\[
h\nu=\phi_0+K_{\max}
\]
\( \textbf{Photon energy:} \)
\[
h\nu=2.0\,eV+1.5\,eV=3.5\,eV
\]
\( \textbf{Threshold relation:} \)
\[
\phi_0=h\nu_0
\]
\( \textbf{Thus:} \)
\[
h\nu_0=2.0\,eV
\]
\( \textbf{Final answer:} \) The incident photon energy is \(3.5\,eV\), while the threshold photon energy is only the work function \(2.0\,eV\).
208. For one metal, \(K_{\max}\) is plotted against \( \nu \).
The graph is a straight line that crosses the frequency axis at \(6.0\times10^{14}\,Hz\). The slope is \(6.6\times10^{-34}\,J\,s\).
The work function of the metal is
ⓐ. \(1.1\times10^{-48}\,J\)
ⓑ. \(6.0\times10^{-14}\,J\)
ⓒ. \(3.96\times10^{-19}\,J\)
ⓓ. \(6.6\times10^{-34}\,J\)
Correct Answer: \(3.96\times10^{-19}\,J\)
Explanation: \( \textbf{Frequency-axis intercept:} \) \( \nu_0=6.0\times10^{14}\,Hz \).
\( \textbf{Slope of } K_{\max}\textbf{-}\nu \textbf{ graph:} \) \(h=6.6\times10^{-34}\,J\,s\).
\( \textbf{Threshold relation:} \)
\[
\phi_0=h\nu_0
\]
\( \textbf{Why this applies:} \) At the frequency intercept, \(K_{\max}=0\), so the photon energy equals the work function.
\( \textbf{Substitution:} \)
\[
\phi_0=(6.6\times10^{-34})(6.0\times10^{14})\,J
\]
\( \textbf{Coefficient product:} \)
\[
6.6\times6.0=39.6
\]
\( \textbf{Power of ten:} \)
\[
10^{-34}\times10^{14}=10^{-20}
\]
\( \textbf{Final simplification:} \)
\[
\phi_0=39.6\times10^{-20}\,J=3.96\times10^{-19}\,J
\]
\( \textbf{Final answer:} \) The work function is \(3.96\times10^{-19}\,J\).
209. A comparison of formulas is shown below.
| Situation | Suitable relation |
| P. Threshold condition using frequency | \(\phi_0=h\nu_0\) |
| Q. Threshold condition using wavelength | \(\phi_0=\frac{hc}{\lambda_0}\) |
| R. Maximum kinetic energy using threshold frequency | \(K_{\max}=h(\nu-\nu_0)\) |
| S. Maximum kinetic energy using wavelength | \(K_{\max}=hc\left(\frac{1}{\lambda_0}-\frac{1}{\lambda}\right)\) |
The row needing correction is
ⓐ. P
ⓑ. Q
ⓒ. S
ⓓ. R
Correct Answer: S
Explanation: Rows P and Q correctly express the work function in terms of threshold frequency and threshold wavelength. Row R correctly follows from \(K_{\max}=h\nu-\phi_0\) and \( \phi_0=h\nu_0 \). Row S has the inverse-wavelength terms in the wrong order. Since \(K_{\max}=E-\phi_0\), the correct wavelength form is \(K_{\max}=hc\left(\frac{1}{\lambda}-\frac{1}{\lambda_0}\right)\). This order gives a positive value when the incident wavelength is shorter than the threshold wavelength.
210. Under ideal threshold conditions, radiation of wavelength \(550\,nm\) falls on a metal with \( \lambda_0=550\,nm \). The fastest photoelectrons have
ⓐ. \(K_{\max}=\frac{hc}{550\,nm}\)
ⓑ. \(K_{\max}=2\phi_0\)
ⓒ. \(K_{\max}=e(550\,V)\)
ⓓ. \(K_{\max}=0\)
Correct Answer: \(K_{\max}=0\)
Explanation: At the threshold wavelength, the incident photon energy is exactly equal to the work function. The electron just escapes from the surface, so no excess energy remains for maximum kinetic energy. In equation form, \(K_{\max}=hc\left(\frac{1}{\lambda}-\frac{1}{\lambda_0}\right)\). When \( \lambda=\lambda_0 \), the two reciprocal terms are equal and their difference is zero. Threshold emission should therefore be understood as just possible emission, not energetic emission.
211. From a surface whose threshold wavelength is \(400\,nm\), a \(300\,nm\) beam produces photoelectrons. If the wavelength is changed to \(350\,nm\) with the same metal, the maximum kinetic energy
ⓐ. increases because wavelength becomes closer to \( \lambda_0 \)
ⓑ. decreases but remains non-zero
ⓒ. becomes zero because \(350\,nm\lt400\,nm\)
ⓓ. becomes negative and the electrons move backward
Correct Answer: decreases but remains non-zero
Explanation: For a fixed metal, \( \lambda_0=400\,nm \) is the maximum wavelength that can cause emission. Both \(300\,nm\) and \(350\,nm\) are shorter than \(400\,nm\), so both can produce photoemission. However, \(350\,nm\) is longer than \(300\,nm\), so its photon energy is smaller. The excess energy after the work function is therefore smaller at \(350\,nm\). The maximum kinetic energy decreases but does not become zero because the wavelength is still below the threshold wavelength.
212. A photoelectric calculation gives \(K_{\max}=-0.4\,eV\) after substituting values into \(K_{\max}=h\nu-\phi_0\). The correct physical interpretation is
ⓐ. no emission because photon energy is below \(\phi_0\)
ⓑ. the emitted photoelectron moves opposite to the incident light
ⓒ. the stopping potential is \(-0.4\,V\) as a measured magnitude
ⓓ. the metal work function has become negative
Correct Answer: no emission because photon energy is below \(\phi_0\)
Explanation: Kinetic energy of an emitted electron cannot be negative. If substitution in \(K_{\max}=h\nu-\phi_0\) gives a negative value, it means \(h\nu\lt\phi_0\). The incident photon does not have enough energy to liberate an electron from the surface. Therefore, the correct conclusion is no photoelectric emission, not negative motion or negative work function. The formula must be used together with the emission condition \(h\nu\geq\phi_0\).
213. In a \(K_{\max}\)-versus-incident-frequency graph for a photoemissive metal, the slope of the straight line is
ⓐ. \(\frac{h}{e}\)
ⓑ. \(h\)
ⓒ. \(\phi_0\)
ⓓ. \(e\)
Correct Answer: \(h\)
Explanation: Einstein’s photoelectric equation can be written as \(K_{\max}=h\nu-\phi_0\). This is a straight-line relation between \(K_{\max}\) and \( \nu \). Comparing it with \(y=mx+c\), the coefficient of \( \nu \) is the slope. Therefore, the slope is \(h\), Planck’s constant. The quantity \(\frac{h}{e}\) appears as the slope of a \(V_0\)-\( \nu \) graph, so the vertical-axis quantity must be checked before choosing the slope.
214. In a \(K_{\max}\)-\( \nu \) graph for a given metal, the frequency-axis intercept represents
ⓐ. stopping potential
ⓑ. saturation current
ⓒ. threshold frequency
ⓓ. threshold wavelength \(\lambda_0\)
Correct Answer: threshold frequency
Explanation: The frequency-axis intercept is the point where \(K_{\max}=0\). At this point, the incident photon has just enough energy to remove an electron from the surface. No excess energy remains as kinetic energy, so this is the threshold condition. Hence the intercept gives \( \nu_0 \), the threshold frequency of the metal. Saturation current belongs to a current-potential graph, not to a \(K_{\max}\)-frequency graph.
215. The vertical intercept of a \(K_{\max}\)-\( \nu \) graph, if the straight line is extended to \( \nu=0 \), is
ⓐ. \(+\phi_0\)
ⓑ. \(h\)
ⓒ. \(\nu_0\)
ⓓ. \(-\phi_0\)
Correct Answer: \(-\phi_0\)
Explanation: The graph relation is \(K_{\max}=h\nu-\phi_0\). If the straight line is mathematically extended to \( \nu=0 \), the equation gives \(K_{\max}=-\phi_0\). This negative intercept is not a physically measured negative kinetic energy. It shows the energy gap that must first be supplied before emission can begin. The physically meaningful part of the graph for emission starts at \( \nu=\nu_0 \), where \(K_{\max}=0\).
216. If the frequency-axis intercept of a \(K_{\max}\)-\( \nu \) graph for a metal is \(4.5\times10^{14}\,Hz\), and \(h=6.6\times10^{-34}\,J\,s\), the work function is closest to
ⓐ. \(1.47\times10^{-19}\,J\)
ⓑ. \(2.97\times10^{-19}\,J\)
ⓒ. \(4.50\times10^{-19}\,J\)
ⓓ. \(6.60\times10^{-19}\,J\)
Correct Answer: \(2.97\times10^{-19}\,J\)
Explanation: \( \textbf{Frequency-axis intercept:} \) \( \nu_0=4.5\times10^{14}\,Hz \).
\( \textbf{Planck constant:} \) \(h=6.6\times10^{-34}\,J\,s\).
\( \textbf{Required quantity:} \) Work function \( \phi_0 \).
\( \textbf{Threshold relation:} \)
\[
\phi_0=h\nu_0
\]
\( \textbf{Reason:} \) At the frequency-axis intercept, \(K_{\max}=0\), so the photon energy just equals the work function.
\( \textbf{Substitution:} \)
\[
\phi_0=(6.6\times10^{-34})(4.5\times10^{14})\,J
\]
\( \textbf{Coefficient product:} \)
\[
6.6\times4.5=29.7
\]
\( \textbf{Power of ten:} \)
\[
10^{-34}\times10^{14}=10^{-20}
\]
\( \textbf{Final simplification:} \)
\[
\phi_0=29.7\times10^{-20}\,J=2.97\times10^{-19}\,J
\]
\( \textbf{Final answer:} \) The work function is \(2.97\times10^{-19}\,J\), obtained from the threshold-frequency intercept.
217. Two metals give straight \(K_{\max}\)-\( \nu \) graphs. The two lines have the same slope but different frequency-axis intercepts. This happens because
ⓐ. work function is different for different metals
ⓑ. Planck’s constant is different for different metals
ⓒ. electron charge is different for different metals
ⓓ. photon speed is different in vacuum for different metals
Correct Answer: work function is different for different metals
Explanation: The slope of a \(K_{\max}\)-\( \nu \) graph is \(h\), which is a universal constant. Therefore, different metals should give parallel straight lines when \(K_{\max}\) is plotted against \( \nu \). Their frequency-axis intercepts differ because their threshold frequencies differ. Since \(\phi_0=h\nu_0\), different threshold frequencies mean different work functions. The graph separates a universal slope from a material-dependent intercept.
218. A data set for one metal is shown below.
| Frequency \( \nu \) | \(K_{\max}\) |
| \(5.0\times10^{14}\,Hz\) | \(0\) |
| \(7.0\times10^{14}\,Hz\) | \(1.32\times10^{-19}\,J\) |
The value of \(h\) obtained from the graph is
ⓐ. \(3.3\times10^{-34}\,J\,s\)
ⓑ. \(6.6\times10^{-34}\,J\,s\)
ⓒ. \(1.32\times10^{-33}\,J\,s\)
ⓓ. \(2.64\times10^{-33}\,J\,s\)
Correct Answer: \(6.6\times10^{-34}\,J\,s\)
Explanation: \( \textbf{First graph point:} \) \( \nu_1=5.0\times10^{14}\,Hz \), \(K_1=0\).
\( \textbf{Second graph point:} \) \( \nu_2=7.0\times10^{14}\,Hz \), \(K_2=1.32\times10^{-19}\,J\).
\( \textbf{Slope of } K_{\max}\textbf{-}\nu \textbf{ graph:} \)
\[
h=\frac{\Delta K_{\max}}{\Delta \nu}
\]
\( \textbf{Change in kinetic energy:} \)
\[
\Delta K_{\max}=1.32\times10^{-19}\,J
\]
\( \textbf{Change in frequency:} \)
\[
\Delta \nu=2.0\times10^{14}\,Hz
\]
\( \textbf{Substitution:} \)
\[
h=\frac{1.32\times10^{-19}}{2.0\times10^{14}}\,J\,s
\]
\( \textbf{Simplification:} \)
\[
h=0.66\times10^{-33}\,J\,s=6.6\times10^{-34}\,J\,s
\]
\( \textbf{Final answer:} \) The graph gives \(h=6.6\times10^{-34}\,J\,s\), with the threshold point acting as one point on the line.
219. Use the graph description below.
For metal \(P\), the \(K_{\max}\)-\( \nu \) line cuts the frequency axis at \(4.0\times10^{14}\,Hz\). For metal \(Q\), the corresponding line cuts it at \(6.0\times10^{14}\,Hz\). The two lines are parallel.
For the same incident frequency \(8.0\times10^{14}\,Hz\), which metal gives larger \(K_{\max}\)?
ⓐ. Metal \(P\)
ⓑ. Metal \(Q\)
ⓒ. Both give equal \(K_{\max}\)
ⓓ. Neither emits because both frequencies are below threshold
Correct Answer: Metal \(P\)
Explanation: The frequency-axis intercept gives the threshold frequency. Metal \(P\) has \( \nu_{0P}=4.0\times10^{14}\,Hz \), while metal \(Q\) has \( \nu_{0Q}=6.0\times10^{14}\,Hz \). For a fixed incident frequency, \(K_{\max}=h(\nu-\nu_0)\). The excess frequency above threshold is larger for metal \(P\) than for metal \(Q\). Therefore, metal \(P\) gives the larger maximum kinetic energy.
220. A row in a graph summary says that the \(K_{\max}\)-\( \nu \) graph for all metals has the same energy-axis intercept. This row is flawed because
ⓐ. slope \(h\) is the same for all such graphs
ⓑ. frequency intercept gives the threshold frequency
ⓒ. intercept \(-\phi_0\) depends on the metal
ⓓ. energy intercept is negative for nonzero work function
Correct Answer: intercept \(-\phi_0\) depends on the metal
Explanation: The equation \(K_{\max}=h\nu-\phi_0\) shows that the energy-axis intercept is \(-\phi_0\). Work function depends on the material and surface condition of the metal. Therefore, different metals generally have different vertical intercepts. The common feature is the slope \(h\), not the intercept. Treating the intercept as universal would incorrectly imply that all metals have the same threshold frequency.