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{\par \bf 17.} [3pt]
Match the appropriate letter on the diagram  with each organelle in the sequence in which they are listed. 
(Example: If the first organelle corresponds to D on the diagram and the next to C, begin your answer with DC...) 
\\ \epsfxsize=90mm \epsffile {/demolibrary/Graphics/Gtype_botany/organelles8.eps} \setlength{\unitlength}{1mm} \\ \begin{picture}(0,0)(0,-5)
\put(4,38){\bf \normalsize W}\put(3,50){\bf \normalsize R}\put(1.5,81){\bf \normalsize T}\put(1,95){\bf \normalsize P}\put(4,103){\bf \normalsize O}\put(13,115){\bf \normalsize N}\put(85,58){\bf \normalsize M}\put(86,42){\bf \normalsize Q}\put(85,32){\bf \normalsize S}\put(68,6){\bf \normalsize V}\put(61,2){\bf \normalsize U}\put(43,1){\bf \normalsize X}\put(37,91){\bf \normalsize Y}\end{picture}
                   
\vspace*{-4mm} \begin{choicelist}
\item[]  1) Nucleus
\item[]  2) Ribosomes
\item[]  3) Nuclear Envelope
\item[]  4) Cell Wall
\item[]  5) Plastid (Chloroplast, proplastid, ...
\item[]  6) Nucleolus
\item[]  7) Endoplasmic Reticulum
\item[]  8) Golgi Body
\item[]  9) Vacuole
\item[]  10) Cell or Plasma Membrane
\item[]  11) Peroxisome
\item[]  12) Tonoplast or Vacuolar Membrane
\item[]  13) Mitochondrion
\end{choicelist}
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{\par \bf 18.} [1pt]
Consider the reaction of nitrous oxide N$_2$O  with oxygen O$_2$  to form nitrogen dioxide NO$_2$:
$$ \rm 2N_2O_{(g)} + 3O_{2(g)} \rightarrow 4NO_{2(g)}$$   A 5.0 liter vessel contains N$_2$O  gas at 5.0$\, atm$ pressure.  A second vessel, 2.0 L in volume contains oxygen at 5.0$\, atm$ pressure. Now suppose that the two vessels are connected by a pipe of negligible volume and the two gases mix and react to produce as much nitrogen dioxide as possible. Assume that the temperature remains constant.  What is the pressure in the apparatus at the end of the reaction?
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{\par \bf 19.} [2pt]\\ 
\parbox{1 in}{\centerline{\epsfxsize=0.6 in \hskip -.05in \epsffile{/demolibrary/Graphics/Gtype09/prob89_Atwood1.eps}}}\parbox{2.4 in}{A frictionless, massless pulley   is attached to the ceiling, in a gravity field of 9.81$\, m / s^2$. Mass $M_2$ is greater than mass $m_1$.  The quantities $T_n$ and $g$ are  magnitudes. (For each statement select T-True,  F-False,  G-Greater than,  L-Less than,  or E-Equal to. )}

\begin{choicelist}
\item[]  A) $m_1$g + $M_2$g is  .... $T_3 \ $
\item[]  B) $T_2 \ $ is .... $T_1 \ $
\item[]  C) $m_1$g is  ... $T_1 \ $
\item[]  D) The center-of-mass does not accelerate.
\item[]  E) The magnitude of the acceleration of $M_2$ is   ... the magnitude of the acceleration of $m_1$.
\item[]  F) $T_3 \ $ is .... $T_1 \ $+$T_2 \ $
\end{choicelist}

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{\par \bf 20.} [2pt]
Asteroids {\bf X}, {\bf Y}, {\bf Z} have equal mass  (6$\, kg$ each). They orbit around a planet with M=$7 \times 10^{24}$$\, kg$. The orbits are in the plane of the paper and are drawn to scale. 
\\ \centerline {\epsfxsize=90mm \epsffile{/demolibrary/Graphics/Gtype30/prob13a_ThreeEllipsesD.eps}}\setlength{\unitlength}{1mm} \\ \begin{picture}(0,0)(0,-5)
\put(10,31){\large 7}\put(35,42){\large 3}\put(52,45){\large 5}\put(85,25){\large 1}\put(51,17){\large 6}\put(22,2){\large 4}\put(2,9){\large 2}\put(3,40){\large {\bf Y}}\put(45,5){\large {\bf X}}\put(72,23){\large {\bf Z}}\end{picture}
            
              
\vspace*{-.25in}
TE, KE and PE represent Total, Kinetic and Potential energies. 
Select  G-Greater than, L-Less than, or E-Equal to. (If the first is G and the rest L, enter GLLLLLL).  
\begin{choicelist}
\item[]  A) The KE of {\bf Y} at 3 is .... its value at 2.
\item[]  B) The speed of {\bf Z} at 6 is .... it is at 5.
\item[]  C) The PE of {\bf X} at 4 is .... the PE of {\bf Y} at 4.
\item[]  D) The PE of {\bf X} at 4 is .... the PE of {\bf Y} at 3.
\item[]  E) The TE of {\bf Z} is .... the TE of {\bf X}.
\item[]  F) The TE of {\bf Y} is .... the TE of {\bf X}.
\item[]  G) The PE of {\bf X} at 7 is .... its value at 6.
\end{choicelist}

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{\par \bf 21.} [5pt]
Write a short essay (200 words or less) about the experiment shown in PHY183 class on Tuesday, November 24, and its interpretation. 
The text of the video can be found in http://capa2.nscl.msu.edu/demolibary/Links/ALNf7/freefall.html. \newline Submit your answer via CAPA (Not by e-mail). Teams of up to five students may collaborate on a single submission.
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{\par \bf 22.} [2pt]
Vector {\bf C} = {\bf A}$\times${\bf B}, where \newline
\centerline{${\bf A} = 15{\bf i} -17{\bf j} -20{\bf k}$} 
\centerline{${\bf B} = 15{\bf i} +25{\bf j} -20{\bf k}$}\newline
The unit vectors in the x, y and z directions are {\bf i}, {\bf j} and {\bf k} respectively. {\bf A} is a displacement and has units of $\, m$, and {\bf B} is a force and has units of $\, N$. Calculate vector {\bf C} and enter the numerical values of its x, y, and z components.
\vskip .05in \hrule width3.55in height0.6pt \hfill \vskip -.07in \noindent {\tiny College of Natural Science, Michigan State University \dotfill  {CAPA\copyright msu}}
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