Difference between revisions of "2008 NSF Proposal"

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= NSF Proposal Guide=
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[[ForestNSFInterimReport_8-31-10]]
  
d. Project Description (including Results from Prior NSF Support)
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[[ForestNSFInterimReport_8-31-11]]
 
 
(i) Content
 
 
 
All proposals to NSF will be reviewed utilizing the two merit review criteria described in greater length in GPG Chapter III.
 
 
 
The Project Description should provide a clear statement of the work to be undertaken and must include: objectives for the period of the proposed work and expected significance; relation to longer-term goals of the PI's project; and relation to the present state of knowledge in the field, to work in progress by the PI under other support and to work in progress elsewhere.
 
 
 
The Project Description should outline the general plan of work, including the broad design of activities to be undertaken, and, where appropriate, provide a clear description of experimental methods and procedures and plans for preservation, documentation, and sharing of data, samples, physical collections, curriculum materials and other related research and education products. It must describe as an integral part of the narrative, the broader impacts resulting from the proposed activities, addressing one or more of the following as appropriate for the project: how the project will integrate research and education by advancing discovery and understanding while at the same time promoting teaching, training, and learning; ways in which the proposed activity will broaden the participation of underrepresented groups (e.g., gender, ethnicity, disability, geographic, etc.); how the project will enhance the infrastructure for research and/or education, such as facilities, instrumentation, networks, and partnerships; how the results of the project will be disseminated broadly to enhance scientific and technological understanding; and potential benefits of the proposed activity to society at large.
 
 
 
= Project Summary =
 
\begin{flushright}
 
\today
 
\end{flushright}
 
 
 
\centerline{{\bf Project Summary}: Experimental Nuclear Physics at Jefferson Lab}
 
 
 
\centerline{{\bf PIs}: Tony Forest, Phil Cole, and Dan Dale}
 
 
 
 
 
This proposal requests support for a program using electromagnetic probes
 
to study hadronic matter
 
on a fundamental level at the Thomas Jefferson National Accelerator Facility.
 
Although the group recently formed at Idaho State Univeristy, each
 
of the senior level participants has a history of intense involvement in the Jefferson
 
Lab physics program.  We are requesting support from the NSF to allow our graduate students
 
to complete their Ph.D. degrees with our current physics program and facilitate the construction
 
of equipment for the 12 GeV JLab upgrade.
 
 
 
==Intellectual Merit==
 
 
 
\begin{center}
 
{\it \underline {The Intellectual Merit of the Proposed Activities}}
 
\end{center}
 
 
 
 
 
Our group is currently focused on three fundamental experiments.
 
The $Q_{weak}$ experiment will utilize parity violating electron
 
scattering to measure the weak mixing angle, $sin^2(\theta_w)$. This measurement represents
 
a stringent test of the Standard Model or alternatively, a search for new physics beyond
 
the Standard Model. Led by Dr. Tony Forest, Idaho State University's contribution to the $Q_{weak}$ program
 
includes a major instrumentation component, namely,
 
the Region 1 Detector and the Front End electronics.
 
Dr. Philip Cole is focusing on comprehensive
 
measurements of vector meson and hyperon photoproduction utilizing linearly polarized photons
 
to improve our understanding of the underlying symmetry of the quark degrees of freedom in the
 
nucleon, the nature of the parity exchange between the incident photon and the target nucleon,
 
and the mechanism of associated strangeness production in electromagnetic reactions.
 
Dr. Dan Dale is a spokesperson for the {\em PrimEx} Collaboration which seeks to perform a high
 
precision measurement of the neutral pion lifetime as a test of the chiral anomaly in QCD, along
 
with different approaches to corrections to the anomaly. Using photoproduction in the Coulomb
 
field of a nucleus, this measurement
 
will provide a stringent test of the predictions of quantum chromodynamics in the confinement scale regime.
 
With a view toward the future upgrade of the Jefferson Lab accelerator, the Idaho State University group
 
is proposing to built the Region 1 drift chambers at ISU for the Hall-B 12 GeV program.
 
Clean room facilities are currently being designed at Idaho State University for this effort.
 
 
 
==Broader Impacts==
 
 
 
\begin{center}
 
{\it \underline {Broader Impacts of the Proposed Activities}}
 
\end{center}
 
 
 
 
 
In addition to the scientific program described here, this proposal represents a major effort in the area
 
of educating future scientists. The present shortage of graduate students in experimental and
 
theoretical nuclear physics is having a detrimental impact on our
 
national laboratories and facilities which posses a plethora of
 
data but limited manpower for analyzing and disseminating the
 
information.  The Idaho State University Department of Physics is
 
comprised of twelve tenure
 
track faculty, all of whom have research interests which are in some way connected to nuclear physics
 
and are in a position to directly address the shortage of graduate students.
 
With its on campus accelerator and detector laboratories, the Department focuses on experimental and
 
applied physics, giving students a strong ``hands on''educational experience. ISU's physics program
 
is relatively new and rapidly growing. Last year, ISU physics faculty brought in approximately
 
\$8 million in external research funds. Its Ph.D. program, begun in the Fall 0f 2005, presently has approximately
 
30 students with an additional 30 students pursuing research at the
 
M.S. level.
 
 
 
The PI's are further strengthening our graduate program by making particular efforts to recruit high quality
 
students from Latin America.
 
Latin and South America are an untapped
 
intellectual resource which can be a beneficial international
 
partner in research and education.  The Intermediate Energy
 
Nuclear Physics Group has established a bridge for collaboration
 
with Brazil and Argentina which during its
 
short lifetime has brought five talented graduate students
 
into nuclear physics.  The activities within this proposal will
 
provide another avenue through which the program can continue to
 
solidify this mutually beneficial bridge of collaboration between
 
the Americas.
 
 
 
=Intellectual Merit of the Proposed Activity=
 
 
 
'''A Program to Study Hadronic Matter using Electromagnetic Probes at JLab'''
 
 
 
We are requesting continuing NSF support for our established program studying hadronic
 
matter using electromagnetic probes. This program currently supports three graduate
 
students, who are in mid stride towards completing their Ph.D.s~in experimental
 
nuclear physics. Even though the group was recently formed at Idaho State University,
 
each of the senior-level participants have an established history of intense involvement
 
in the Jefferson Lab physics program from their research at their former universities.
 
The PIs, moreover, have a strong record of constructing scientific instrumentation with
 
NSF funding and each has made substantial impacts to the field. The significance of our
 
research and the objectives for the proposed work period are described in
 
section~\ref{section:IntelectMerits}. Through our well established partnership
 
with several universities in the Americas, we discuss in section~\ref{section:BroaderImpacts}
 
our continued recruitment of underrepresented groups in physics. The requested funding will
 
not only enable our graduate students to complete the JLab data analysis in a timely
 
manner and obtain their Ph.D.~degrees, but these monies will further provide the
 
necessary support to enable Idaho State University to construct the six inner drift
 
chambers for the 12 GeV upgrade to Hall B of JLab; these tracking chambers being a
 
critical-path item for the upgrade.
 
 
 
== The ISU Physics Program==
 
 
 
===Q_{weak}===
 
 
 
The $Q_{weak}$ experiment (E05-008), scheduled for installation in 2010,
 
will use parity violating (PV)
 
electron-proton scattering
 
at very low momentum transfers $(Q^2  \sim  0.03~ \rm{GeV}^2)$ to measure
 
the weak mixing
 
angle $\sin^2(\theta_W)$.
 
The dominant contribution to the PV
 
asymmetry measured by $Q_{weak}$ is given by the weak charge of
 
the proton, $Q_W^p = 1-4\sin ^2 \theta _W$,
 
with small corrections of order $Q^4$ from nucleon
 
electromagnetic form factors.
 
This measurement will be a
 
standard model test
 
of the running of the electroweak coupling constant, sin$^2$($\theta_W$).
 
Any significant deviation of $\sin ^2 \theta _W$ from the
 
standard model prediction at
 
low $Q^2$ would be a signal of new physics, whereas agreement
 
would place new and significant
 
constraints on possible standard model extensions including new
 
physics. 
 
A brief
 
description of the physics behind the $Q_{weak}$ experiment and the
 
crucial contributions of this proposal to the $Q_{weak}$ experiment are
 
given below.
 
 
 
An essential prediction of the Standard Model is the variation of
 
$\sin ^2 \theta _W$
 
with $Q^2$, often referred to as the ``running of $\sin ^2 \theta
 
_W$.'' Testing this prediction requires
 
a set of precision measurements at a variety of $Q^2$ points,
 
with sufficiently small and well
 
understood theoretical uncertainties associated with the
 
extraction of $\sin ^2 \theta _W$.
 
It also requires a careful evaluation of the radiative
 
corrections to $\sin ^2 \theta _W$ in
 
the context of the renormalization group evolution (RGE) of the
 
gauge couplings. Such tests
 
have been crucial in establishing QCD as the correct theory of
 
strong interactions~\cite{Hin00}. 
 
The RGE evolution of the QED coupling has also been
 
demonstrated experimentally~\cite{TOP97,VEN98,OPAL00,L300}.
 
The gauge coupling of the weak interaction, however, represented at low energies by the weak mixing angle
 
$\sin ^2 \theta _W$, has not yet been studied successfully in this respect.
 
 
 
 
 
 
 
[[Image:Qweak_s2w_Precision.jpg | 200 px]][[Image:Qweak_s2w_Precision.eps]]
 
[[Image:A-d_Delta_Prec.xfig.jpg | 200 px]][[Image:A-d_Delta_Prec.xfig.eps]]
 
 
 
 
 
 
 
\begin{figure}[htbp]
 
%\vspace{-1in}
 
\begin{center}
 
{
 
\scalebox{0.2} [0.2]{\includegraphics{Graphs/s2w_2004_4_new_2.eps}}
 
\scalebox{0.25} [0.25]{\includegraphics{Graphs/A_d_Delta_Prec.xfig.eps}}
 
}
 
\caption{The dependence of $\sin^2 \theta_W$ as a function of $Q^2$ cast in the MS bar scheme of reference~\cite{Erler}.  The solid line represents the Standard Model prediction. The results from four experiments (APV~\cite{APV}, $Q_W(e)$~\cite{E158}, $\nu$-DIS~\cite{NuTeV}, Z-pole~\cite{Zpole} are shown together with the expected precision from the $Q_{weak}$ experiment (Q$_W(p)$~\cite{Qweak}.  Expected precision of an inelastic asymmetry measured in one week using the Q$_{weak}$ apparatus  compared with the expected asymmetry for several values of the low energy constant $d_{\Delta}$.  The rectangular box indicates both the Q$^2$ bin and the asymmetry uncertainty.}
 
\label{fig:PVAsym}
 
\end{center}
 
\end{figure}
 
 
 
Figure~\ref{fig:PVAsym} shows the Standard Model prediction in a particular scheme~\cite{QweakAp} for $\sin ^2 \theta _W$
 
versus $Q^2$ along with existing and proposed world data. As seen in this Figure, the very
 
precise measurements near the $Z^0$ pole merely set the overall magnitude of the curve; to test
 
its shape one needs precise off-peak measurements. Presently, there
 
are only three off-peak measurements
 
of $\sin ^2 \theta _W$ which test the running at a significant
 
level: one from APV~\cite{APV}, one from high energy neutrino-nucleus
 
scattering~\cite{NuTeV}, and the recently completed SLAC
 
experiment E-158(Q$_w$(e))~\cite{E158}. The measurement of $Q_W^p$ described here 
 
will be performed with smaller statistical and systematic errors and has a much cleaner
 
theoretical interpretation than existing low $Q^2$ data. In addition, this measurement resides in the
 
semi-leptonic sector, and is therefore complimentary to experiment E-158 at SLAC, which 
 
resides in the pure leptonic sector and
 
has determined $\sin ^2 \theta _W$ from PV $\vec e e$ (Moller) scattering
 
to roughly a factor of two less precision at low $Q^2$~\cite{E158}.
 
The total statistical and systematic error anticipated
 
on $Q_W^p$ from these measurements is around 4\%~\cite{Qweak},
 
corresponding to an uncertainty in
 
$\sin ^2 \theta _W$ of $\pm$0.0007.  This would establish the
 
difference in radiative corrections
 
between $\sin ^2 \theta _W (Q^2 \approx 0)$ and $\sin ^2 \theta
 
_W (M_Z )$ as a 10 standard
 
deviation effect.
 
 
 
\medskip
 
\begin{center}
 
\underline{\sf ISU's role in $Q_{weak}$}
 
\end{center}
 
 
 
PI Forest is currently the work package manager of the Region 1 detector
 
and front end electronics for $Q_{weak}$. 
 
The Region 1 tracking system detectors are being assembled and will be
 
tested by the end of 2008.
 
This proposal will support the installation of a front end electronics
 
system from CERN to digitize the analog
 
output of the detectors. 
 
PI Forest has been using his startup funds to develop the infrastructure
 
needed to implement this system in $Q_{weak}$.  A critical milestone in the work plan,
 
outlined in Table~\ref{table:Timeline}, will be the testing of the integrated tracking system
 
during the summer of 2009 at JLab in preparation for the installation of the system in early 2010.
 
Support from this proposal will be used to complete the front end electronics
 
installation and maintain the Region 1 tracking system during the calibration
 
phase of the $Q_{weak}$ experiment currently scheduled to begin installation in
 
JLab's Hall C in early 2010.
 
 
 
In addition to providing a key component to the $Q_{weak}$ tracking system, PI Forest has
 
also outlined a week long experiment to measure $d_{\Delta}$ using the
 
$Q_{weak}$ apparatus~\cite{Qweak} to a statistical precision of less than 0.1 ppm as
 
shown in Figure~\ref{fig:PVAsym}~\cite{LOIdDelta}.
 
This low energy constant $d_{\Delta}$ was discovered while evaluating the radiative corrections for the
 
PV $N\rightarrow \Delta$ transition~\cite{Zhu012}.  The authors in Ref.~\cite{Zhu012} used Siegert's
 
theorem to show the presence of a non-vanishing PV asymmetry at $Q^2=0$ which is proportional
 
to $d_{\Delta}$.
 
A measurement of the PV asymmetry in the $N\rightarrow \Delta$ transition at the
 
photon point, or at very low $Q^2$ would provide a direct measurement of the
 
low energy constant $d_{\Delta}$.
 
 
 
The low energy constant $d_{\Delta}$ is a fundamental constant
 
which has implications to other long standing physics questions.
 
The same PV electric dipole matrix element which results in
 
$d_{\Delta}$ also drives the asymmetry
 
parameter ($\alpha_{\gamma}$) in radiative hyperon decays, e.g. $\Sigma ^+ \rightarrow p\gamma$.
 
Although Hara's theorem~\cite{Hara64} predicts that the asymmetry
 
parameter ($\alpha_{\gamma}(\Sigma ^+ \rightarrow p\gamma$)) should
 
vanish in the exact SU(3) limit,  the Particle Data
 
Group~\cite{PDGAlphaSigma} reports a measured value of
 
$\alpha_{\gamma}(\Sigma ^+ \rightarrow p\gamma) = -$0.72$\pm$ 0.08.
 
While typical SU(3) breaking effects are of order $(m_s - m_u )/1$GeV $\sim$ 15\%,
 
the above asymmetry parameter is experimentally
 
found to be more than four times larger.
 
A solution proposed by the authors of Ref.~\cite{Bor99}
 
involves including high mass intermediate state resonances $(1/2 ^- )$,
 
where the weak Lagrangian allows the coupling of both the hyperon and daughter
 
nucleon to the intermediate state resonances, driving the asymmetry parameter
 
to large negative values.
 
This same reaction mechanism was also shown to
 
simultaneously reproduce the $s$- and $p$-wave amplitudes in non-leptonic
 
hyperon decays, which has also been a long standing puzzle in hyperon decay
 
physics. If the same underlying dynamics is present in the
 
non-strange sector ($\Delta S = 0$) as in the
 
strangeness changing sector ($\Delta S = 1$), one would expect
 
$d_{\Delta}$ to be enhanced over its natural scale ($g_{\pi}$ =
 
3.8$\times 10^{-8}$, corresponding to the scale of charged
 
current hadronic PV effects~\cite{Des80,Zhu00}).
 
The authors of Ref.~\cite{Zhu012} estimate that this enhancement may
 
be as large as a factor of 100, corresponding to an asymmetry of
 
$\sim$ 4 ppm.  This is comparable to the size of the effects due to the
 
axial response and therefore easily measurable. Thus, a
 
measurement of this quantity could provide a window into the
 
underlying dynamics of the unexpectedly large QCD symmetry
 
breaking effects seen in hyperon decays.
 
 
 
 
 
 
 
===Vector Meson and Hyperon Photoproduction with Linearly Polarized Photons===
 
 
 
 
 
The probe afforded by a beam of linearly-polarized photons allows one to gain access to several observables in photonucleon reactions, which otherwise would not be measurable. The polarization axis defines a unique direction in space whereby the angular distributions of the final-state particles can be uniquely referenced. The polarization axis of the photon beam breaks the azimuthal symmetry of the reaction, thereby introducing an azimuthal ($\Phi$) dependence to the differential cross section. This additional information on the angular dependence opens the door to the measurement of a host of observables which are accessible only with a beam of linearly-polarized photons; consequently it provides important constraints on the nature of the photon-nucleon reaction. Such polarization observables are necessary for extracting the spin/parity of the broadly overlapping baryon resonances and measuring such parameters over a large energy range with full angular coverage is crucial for disentangling such contributions. 
 
CoPI Cole is the contact person of the experiments which comprise the g8 run~\cite{Cole94,Ted98,FKlein99,Sanabria01,Pasyukg8,g8papers}. The scientific purpose of g8 is to improve the understanding of the underlying symmetry of the quark degrees of freedom in the nucleon, the nature of the parity exchange between the incident photon and the target nucleon, and the mechanism of associated strangeness production in electromagnetic reactions. With the high-quality beam of the tagged and collimated linearly-polarized photons and the nearly complete angular coverage of the Hall-B spectrometer, we seek to extract the differential cross sections and polarization observables for the photoproduction of vector mesons and kaons at photon energies ranging between 1.10 and 2.20~GeV.
 
 
 
In preparation for the g8a run, we commissioned the Coherent Bremsstrahlung Facility, which was essentially a new beamline in Hall B for producing a tagged and collimated beam of linearly polarized photons, where the mean polarization in the energy range of 1.8 to 2.2~GeV was 71\%. We enjoyed a reasonably successful two-month run for g8a, which so far, has culminated in two Ph.D. theses~\cite{CGordon, JMelone}, two master's theses~\cite{APuga, JSalamanca}, and one of the two NSF graduate research fellowships~\cite{RMammei} awarded in nuclear physics in 2003.
 
We seek to build upon our earlier work and investigate the nature of resonant baryon states by probing protons with polarized photons. The set of experiments forming the first phase of the g8 run took place in the summer of 2001 (6/04/01 - 8/13/01) in Hall B of Jefferson Lab. These experiments made use of a beam of linearly-polarized photons produced through coherent bremsstrahlung and represents the first time such a probe was employed at Jefferson Lab. The second time this probe was used took place in the summer of 2005 (6/20/05 - 9/01/05) for the second
 
phase of g8 (g8b), followed by g13b (3/08/07 - 6/29/07) and
 
g9a (10/17/07 - 2/11/08). The g8 set of experiments, therefore, was a vital first step for establishing the Coherent Bremsstrahlung Facility and this experience paved the way for the successful runs with linearly polarized photons in Hall B of JLab: g13b ($\vec{\gamma}d$), and g9a ($\vec{\gamma}\vec{p}$). The lessons learned in calibration and cooking for g8b have accelerated the analyses for the g13a/b and g9a. And in the three years since the end of the g8b run, we have or are near completion of three Ph.D. theses: a) Craig Paterson~\cite{Paterson-g8b}, University of Glasgow, $\vec{\gamma}p \rightarrow K\Lambda, K\Sigma^{\circ}$, Aug.~2008), b) Patrick Collins~\cite{Collins-g8b}, Arizona State University, $ \vec{\gamma}p \rightarrow p\eta, p\eta^{\prime}$, Nov.~2008, and c) Juli\'{a}n Salamanca~\cite{Salamanca-g8b,LASNPA-7}, Idaho State University, $\vec{\gamma}p \rightarrow p\phi$, May~2009. \\
 
 
 
\noindent \underline{\bf Photoproduction of the $\phi(1020)$} \\
 
Vector meson photoproduction at high energies, as is well known, proceeds primarily through pomeron exchange rather than by $\pi$ or $\eta$ meson exchange, which are respectively termed natural and unnatural parity exchange. In the baryon resonance energy regime
 
($E_{\vec{\gamma}}\sim 2.0$ GeV) and at low four-momentum transfer squared, $t$,
 
the peak structure of the coherent $\phi$-meson photoproduction cross section
 
is not well explained at threshold by a pure pomeron-exchange-based model~\cite{mibe}. The extraction of the Spin Density Matrix Elements (SDMEs) from $\phi$-meson decay angular distributions will shed light on the proportion of natural and unnatural parity exchange involved in the reaction mechanism~\cite{shilling} at low $t$, which is further to be compared to the predicted values of the Vector Dominance Model (VDM)~\cite{sakurai}.
 
We have several thousand $\phi$s mesons at both low and high $t$
 
in the baryon resonance regime of $2.02 < \sqrt{s} < 2.11$ GeV.  With the exception of this
 
g8 dataset, there are no photoproduced phi mesons with linearly polarized photons measured in the central region in the world data set. Extracting the SDMEs for the phi channel at high $|t|$ will therefore hold discovery potential for non-VDM mechanisms at higher four-momentum transfers squared. 
 
After making the necessary momentum, timing, particle ID, and Dalitz mass cuts we separate the data into unpolarized (AMO), perpendicular (PERP) polarization, and parallel (PARA) polarization. We fit a Breit-Wigner to the phi meson peak constrained with a decay width $\Gamma$ of 4.26~GeV with a second-order polynomial for fitting the background and a gaussian for representing the detector uncertainties. Below we display the phi peak obtained from extracting the $K^-$ from missing mass and then forming the invariant mass of the $K^+K^-$ separated in PERP and PARA orientations for the cms energy of $2.11 < \sqrt{s} < 2.20$~GeV.
 
 
 
[[Image:phi_mass_para_perp.eps]]
 
 
 
\begin{figure}[h!]
 
\begin{center}
 
\includegraphics[height=.18\textheight]{Graphs/Cole_phi_mass_para_perp.eps} \caption{\small $K^+K^-$ invariant mass in the cms energy range of $2.11 < \sqrt{s} < 2.20$~GeV fit with a Breit-Wigner + Gaussian + 2nd order polynomial. The decay width is fixed at 4.26~GeV. (RHS) parallel (LHS) perpendicular polarizations.} \label{fig:phi_mass} \end{center} \end{figure}
 
Below we plot the combination of parallel (PARA) and perpendicular (PERP) photoproduced phi mesons for all $t$ to obtain the photon beam asymmetry parameter: \\
 
%\begin{equation}
 
$$\Sigma = (W^{PARA} - W^{PERP})/(W^{PERP} + W^{PARA}).$$
 
%\end{equation}
 
These values are consistent with what we would expect from the Vector Dominance Model. We are presently working on separating the data into low- and high-$|t|$ regimes, but are not prepared to show it until we have authorization from the CLAS collaboration.
 
 
 
[[Image:asym_all.eps]]
 
 
 
\begin{figure}[h!]
 
\begin{center}
 
\includegraphics[height=.18\textheight]{Graphs/Cole_asym_all.eps}
 
\caption{\small Beam asymmetry for the phi meson channel over the full range of $t$ for (a) $1.9 < E_{\gamma} < 2.1$~GeV and (b) $1.7 < E_{\gamma} <1.9$~GeV. The photon beam polarization is 75\%.}
 
\label{fig:asym} \end{center} \end{figure}
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
=== Primakoff===
 
 
 
CoPI Dale is a spokesperson for the {\em PrimEx} Collaboration. At present, the scientific goal of the Collaboration is to perform a high precision measurement of the neutral pion lifetime as a test of the chiral anomaly in QCD, along with different approaches to corrections to the anomaly.
 
 
 
The two-photon decay mode of the $\pi^{0}$ reveals one of the most profound symmetry issues in quantum chromodynamics, namely, the explicit breaking of a classical symmetry by the quantum fluctuations of the quark fields coupling to a gauge field~\cite{book}. This phenomenon, called anomalous symmetry breaking, is of pure quantum mechanical origin. The axial anomaly of interest to us involves the corresponding coupling of the quarks to photons~\cite{anomaly}. In the limit of exact isospin symmetry, the $\pi^{o}$ couples only to the isotriplet axial-vector current
 
$\bar{q}I_3\gamma_\mu \gamma_5 q$, where $q=(u,\; d)$, and
 
$I_3$ is the third isospin generator. In the
 
limit of two quark flavors, the electromagnetic current is given by $\bar{q}(1/6+ I_3/2)\gamma_\mu q$. When coupling to the photon,
 
the isosinglet and isotriplet components of the electromagnetic
 
current
 
lead to an anomaly that explicitly breaks the symmetry associated
 
with the axial-vector current
 
$\bar{q}\;I_3\;\gamma_\mu \gamma_5\;q$, and this in turn
 
directly affects the coupling of the $\pi^{o}$ to two photons. The conservation of the  axial U(1) current,
 
to which the $\eta'$ meson couples,  as well as the
 
$\bar{q} \frac{1}{2}\lambda_{8}\gamma_\mu \gamma_5 q$, to which the $\eta$ meson couples, are similarly affected by the electromagnetic field.
 
 
 
For vanishing quark masses, the anomaly leads to the
 
predicted width of the $\pi^{o} \rightarrow \gamma \gamma$ decay:
 
\begin{equation} \Gamma=M_{\pi}^{3}\frac{ \mid A_{\gamma \gamma} \mid^{2}}{64\pi}= 7.725 \pm 0.044 ~\rm{eV}, \end{equation}
 
where the reduced amplitude is
 
\begin{equation} A_{\gamma \gamma} =\frac{\alpha_{em}}{\pi F_{\pi}} = 2.513 \cdot 10^{-2} ~\rm{GeV}^{-1} \end{equation}
 
 
 
In this expression, there are no free parameters. Since the mass of the $\pi^0$ is the smallest in the hadron spectrum, higher order corrections to this prediction are small and can be calculated with sub-percent accuracy.
 
The current experimental
 
value is $7.84 \pm 0.56$ eV~\cite{PDB} and is in good agreement with the predicted value with the chiral limit amplitude. This number is an average of several experiments~\cite{PDB}. Even at the 7\% level quoted by the Particle Data Book~\cite{PDB}, the accuracy is not sufficient for a test of the new calculations which take the finite quark masses into account. The level of precision of $\simeq 1.4\%$, which is the goal of {\em PrimEx}, will satisfy these requirements.
 
Stimulated by the
 
{\em PrimEx} project, several new theoretical calculations have been published in recent years, and are shown in Figure~\ref{fig:theory}. The first two independent
 
  calculations of the chiral corrections were performed in the 
 
combined framework of chiral perturbation theory (ChPT) and the $1/N_c$ expansion up to ${\cal{O}}(p^6)$ and ${\cal{O}}(p^4\times 1/N_c)$ in the decay amplitude~\cite{Goity}~\cite{Mou02}. The $\eta'$ is explicitly included in the analysis as it plays as important a role as the $\eta$ in the mixing effects. It was found that the decay width is enhanced by about 4\% with respect to the value stated in equation (1). This enhancement is almost entirely due to the mixing effects. The result of this next-to-leading order analysis is $\Gamma_{\pi^0\to\gamma\gamma}=8.10~ {\rm eV}$ with an estimated uncertainty of less than 1\%. Another theoretical calculation based on QCD sum rules~\cite{Ioffe07}, also inspired by the {\em PrimEx} experiment, has recently been published with a theoretical uncertainty less than 1.5\%. Here, the only input parameter to the calculation is the $\eta$ width.
 
 
 
 
 
 
 
[[Image:pio_width_new_theory_prel_result.eps]]
 
 
 
\begin{figure}
 
\begin{center}
 
%\begin{minipage}[t]{0.58\linewidth}
 
\begin{minipage}[t]{0.38\linewidth}
 
\scalebox{0.5} [0.55]{\includegraphics{Graphs/Pio_width_new_theory_prel_result.eps}}
 
%\epsfig{file=Graphs/Pio_width_new_theory_prel_result.eps,width=\linewidth}
 
\end{minipage}\hfill
 
%\begin{minipage}[t]{0.38\linewidth}
 
\begin{minipage}[t]{0.48\linewidth}
 
\vspace*{-10cm}\caption{$\pi^{o} \rightarrow \gamma \gamma$ decay width in
 
eV. The
 
dashed horizontal line is the leading order prediction
 
of the axial anomaly~\cite{book,
 
anomaly}.The left hand side shaded band is the recent QCD sum rule
 
prediction and the
 
right hand side shaded band is the  next-to-leading order chiral theory
 
predictions.
 
The experimental results with errors are for : (1)~the direct
 
method~\cite{At85};
 
(2, 3, 4)~the Primakoff method~\cite{Br74,Bel70,Kr70}; (5)~the preliminary
 
result from the first
 
{\em PrimEx} data set;
 
(6)~the expected
 
error for the final goal of the {\em PrimEx} experiment, arbitrarily
 
plotted to agree with
 
the leading order prediction. prediction.\label{fig:theory}}
 
\end{minipage}
 
\label{fig:Primextheory}
 
\end{center}
 
\end{figure}
 
 
 
 
 
 
 
 
 
We are using quasi-monochromatic photons of energy 4.6-5.7~GeV from the Hall~B photon tagging facility to measure the absolute cross section of small angle $\pi^{o}$ photoproduction from the Coulomb field of complex nuclei. The invariant mass and angle of the pion are reconstructed by detecting the $\pi^{o}$ decay photons from the $\pi^{o} \rightarrow \gamma \gamma$ reaction.
 
For unpolarized photons, the Primakoff cross section is given by:
 
\begin{equation} \frac{d\sigma_P}{d\Omega}=\Gamma_{\gamma \gamma}\frac{8{\alpha}Z^2}{m^3}\frac{\beta^3{E^4}}{Q^4}|F_{e.m.}(Q)|^ 2 \sin^{2}\theta_{\pi} \end{equation}
 
\noindent where $\Gamma_{\gamma \gamma}$ is the pion decay width, $Z$ is the atomic number, $m$, $\beta$, $\theta_{\pi}$ are the mass, velocity and production angle of the pion, $E$ is the energy of incoming photon, $Q$ is the momentum transfer to the nucleus, and $F_{e.m.}(Q)$ is the nuclear electromagnetic form factor, corrected for final state interactions of the outgoing pion.
 
As the Primakoff effect is not the only mechanism for pion photoproduction at high energies, some care must be taken to isolate it from competing processes. In particular, the full cross section is given by:
 
\begin{equation} \frac{d\sigma}{d\Omega_{\pi}} = \frac{d \sigma_P}{d\Omega} + \frac{d\sigma_C}{d \Omega} + \frac{d \sigma_I}{d\Omega}+ 2 \cdot \sqrt{\frac{d\sigma_{P}}{d\Omega} \cdot \frac{d\sigma_{C}}{d\Omega}} cos(\phi_1 + \phi_2) \end{equation}
 
\noindent where the Primakoff cross section, $\frac{d \sigma_P}{d\Omega}$, is given by equation (4). The nuclear coherent cross section is given by: \begin{equation} \frac{d\sigma_C}{d \Omega} = C \cdot A^2 |F_N(Q)|^2 \sin^2\theta_{\pi} \end{equation} and the incoherent cross section is: \begin{equation}
 
\frac{d \sigma_I}{d\Omega}=\xi A (1-G(Q)) \frac{d
 
\sigma_H}{d\Omega} \end{equation} where $A$ is the nucleon number, $C \sin^2\theta_{\pi}$ is the square of the isospin and spin independent part of the neutral meson photoproduction amplitude on a single nucleon, $|F_N(Q)|$ is the form factor for the nuclear matter distribution in the nucleus, (corrected for final state interactions of the outgoing pion), $\xi$ is the absorption factor of the incoherently produced pions, $1-G(Q)$ is a factor which reduces the cross section at small momentum transfer due to the Pauli exclusion principle, and $\frac{d \sigma_H}{d\Omega}$ is the $\pi^o$ photoproduction cross section on a single nucleon. The relative phase between the Primakoff and nuclear coherent amplitudes without final state interactions is given by $\phi_1$, and the phase shift of the outgoing pion due to final state interactions is given by $\phi_2$.
 
The angular dependence of the Primakoff signal is different from the background processes, allowing $\Gamma(\pi^0\rightarrow \gamma\gamma)$ to be extracted from a fit to the angular distribution of photo-produced $\pi^0$. Measurements of the nuclear effects at larger angles are necessary to determine the unknown parameters in the production mechanism and thus make an empirical determination of the nuclear contribution in the Primakoff peak region. Consequently, this experiment uses a $\pi^{o}$ detector with good angular resolution to eliminate nuclear coherent production, and good energy resolution in the decay photon detection will enable an invariant mass cut to suppress multi-photon backgrounds.
 
%Image:Primex pb cross color.ps
 
%\begin{figure} %\centerline{\epsfxsize=200pt \epsfbox[200 150 430 500]{pb_cross_color.ps}} %\vspace{1cm} %\caption{Angular behavior of the electromagnetic and nuclear %$\pi^o$ photoproduction cross sections for %$^{208}$Pb in the 6.0~GeV energy range. } %\label{fig3} %\end{figure}
 
 
 
We submitted our first proposal (E-99-014) to PAC15 in December of 1998. It was approved by PAC15 and
 
reconfirmed in  jeopardy review later by PAC22  with an ``A'' rating. An NSF MRI proposal for \$970k
 
was awarded (PIs: D.S.~ Dale, A.~Gasparian, R.~Miskimen, S.~Dangoulian) for the construction of a multichannel neutral pion calorimeter. This was successfully designed, constructed, and commissioned over the period 2000-2004. The first experiment on two targets ($^{12}$C and $^{208}$Pb) was performed in 2004. A second run (E-08-023, spokespersons: D.~Dale, A.~Gasparian, M.~Ito, R.~Miskimen) was approved by PAC33 with an $A-$ rating for 20 days of running to reach the proposed goal of $\sim 1.4\%$ accuracy. While the CoPI of this funding proposal has been involved in all aspects of this program, he has taken primary responsibility for the flux normalization. This has involved the design, construction, and commissioning of the {\em PrimEx} pair spectrometer. In addition, along with his students, he has been responsible for the analysis of the resulting data. This has also included a high precision measurement of the absolute cross section of a well known QED process, pair production, to verify that the flux determination was correct.
 
%To date, the CoPI has supervised to completion one Ph.D. student (A. Teymurazyan) and one M.S. student on this work. One more Ph.D. student (O. Kosinov) is currently working toward his degree.
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
== Prior and Future use of NSF Funds==
 
 
 
[[Image:BremFacility.jpg | 200 px]][[Image:PairSpectrometer_NSF08.jpg| 200 px]][[Image:Qweak_BottomDetector_HVboard_Cathode_and_Bolts_2.jpg|200px]]
 
 
 
 
 
[[Image:BremFacility.eps]][[Image:PairSpectrometer_NSF08.eps]][[Image:AssembledQweakDetector.eps]]
 
 
 
=== Prior use of NSF funds===
 
\begin{figure}[htbp]
 
%\vspace{-1in}
 
\begin{center}
 
{
 
\scalebox{0.2} [0.4]{\includegraphics{Graphs/Cole_BremHist.eps}}
 
\scalebox{0.25} [0.25]{\includegraphics{Graphs/DalePairSpect.eps}}
 
\scalebox{0.15} [0.15]{\includegraphics[angle=90]{Graphs/QweakAssembledDetector.eps}}
 
}
 
\caption{The histograms show the improvement to Hall B's
 
linearly polarized photon beam using the collimator designed and calibrated by CoPI Cole. 
 
The middle picture shows the pair spectrometer system installed in Hall B by CoPI Dale and his collaborators.
 
The right most picture is of an assembled GEM detector for $Q_{weak}$'s Region 1 tracking system designed,
 
machined and assembled by PI Forest and his students at ISU. 
 
}
 
\label{fig:PriorNSFProducts}
 
\end{center}
 
\end{figure}
 
 
 
 
 
 
 
The PIs in this proposal have a strong record of receiving external funding from the
 
NSF and a history of
 
effectively using those funds to make substantially
 
contributions to the infrastructure of the nuclear
 
physics program described in this proposal, as summarized in Figure~\ref{fig:PriorNSFProducts}.
 
The bremsstrahlung facility in JLab's Hall-B is one example
 
of CoPI Cole's efforts to enhance the capabilities of Hall B's photon physics program. CoPI Dale has used NSF
 
funds to install a pair spectrometer facility in Hall B. The Region 1 tracking system for $Q_{weak}$ was
 
constructed by PI Forest using NSF funds.
 
 
 
 
 
====Coherent Bremsstrahlung Facility====
 
An instrumented collimator, having an aperture of 2.0 mm in diameter, is installed in the Hall-B beamline downstream of the tagger magnet and is located 22.9 m away from the diamond radiator. The collimator~\cite{collimator-cole}, designed and calibrated by CoPI Cole, forms part of the Coherent Bremstrahlung Facility; it serves to enhance the degree of linear polarization, $P$, within the coherent peak. As shown in Fig~\ref{fig:PriorNSFProducts}, the coherent distribution, peaked at 2.1~GeV, is considerably enhanced by tightly collimating the photon beam to one half of a characteristic angle. The spectra were taken with an electron beam energy of 4.5 GeV. Since the merit function
 
%scales as $1/P_{\gamma}^2$
 
inversely scales with the photon poloarization squared,
 
the collimation as shown in Figure~\ref{fig:PriorNSFProducts} enhances the quality of the polarization data by at least 30\%.
 
 
 
 
 
====pair spectrometer====
 
In 2000, an NSF MRI proposal (grant \# PHY-0079840) for \$970k was awarded (PIs: D.S.~Dale, A.~Gasparian, R.~Miskimen, S.~Dangoulian) for the construction of a multichannel neutral pion calorimeter, a pair spectrometer for flux monitoring, as well as a number of other pieces of experimental instrumentation for the {\em PrimEx} experiment. CoPI Dale was involved in all aspects of the experimental design and construction, and was the lead on the design, construction, and testing of the pair spectrometer. This pair spectrometer was successfully commissioned in 2002, and is now a part of the standard beamline instrumentation in Hall B.
 
 
 
==== Qweak Detector Construction====
 
The design, construction, and testing of the Region 1 tracking system for the $Q_{weak}$ experiment at Jefferson Lab has been the main research activity supported by PI Forest's previous NSF grant. The $Q_{weak}$ Region 1 tracking system is one of three tracking systems designed to measure the $Q^2$ profile of elastically scattered electrons as well as background contributions to the parity violating signal~\cite{Qweak}. The Region 1 tracking system is located behind the first collimator at a distance of about 550 cm from the main torus magnet (200 cm from the target). The high radiation flux and the small detector footprint are two of the biggest challenges facing the Region 1 tracking system. As a result, an ionization chamber equipped with Gas Electron Multipliers (GEM) was chosen in order to accommodate the high radiation flux near the target. The GEM preamplifiers allow smaller ionization cell sizes thereby resulting in ionization chamber rise times of 50 nanoseconds or less.
 
Figure~\ref{fig:PriorNSFProducts} below shows the custom designed GEM detector for the $Q_{weak}$ Region 1 tracking system. Engineers from the Idaho Accelerator Center (IAC) designed the GEM preamplifiers. 
 
This is a clear example of how the infrastructure at the IAC can be leveraged in support of our physics mission. The remaining detector design, machining, and assembly was completed using both graduate and undergraduate students.
 
 
 
=== Future Use of NSF funds===
 
 
 
\begin{figure} [!hbp]
 
\begin{center}{
 
\scalebox{0.25} [0.35]{\includegraphics{Graphs/deltad_CLAS12.eps}}
 
\scalebox{0.2} [0.3]{\includegraphics{Graphs/p11_high.eps}}
 
}
 
\caption{ The left figure represents a comparison between the measurement to be made
 
using an energy upgraded JLab with fits of the world data set for $\frac{\Delta d}{d}$.
 
The expected data have been drawn along the pQCD and CQM prediction.  The right figure
 
represents the high $Q^2$ measurements that are possible after the upgrade to Hall B.
 
Projected $N^*$ electrocoupling for the Roper $P_{11}(1440)$ as a function of $Q^{2}$ where
 
the open circles with error bars are from our expected experiment~\cite{NSTAR12}, the
 
closed squares are from the available CLAS data on single pion electroproduction~\cite{Aznauryan-2005},
 
and the solid blue squares are the preliminary data from analysis of e1-6 run
 
overlaid with the results from the combined analysis of single and double pion
 
electroproduction off protons~\cite{Aznauryan-2005-1}.}
 
\label{fig:JLab12GeVPhysics}
 
\end{center}
 
\end{figure}
 
==== Work Plan====
 
 
 
The work undertaken to satisfy the objectives for the funding cycle of this proposal involves the
 
completion of the Region 1 tracking system for $Q_{weak}$ and the construction of drift chambers for the
 
Hall B 12 GeV upgrade according to the milestones shown in Table~\ref{table:Timeline}. 
 
The construction of the $Q_{weak}$ Region 1 tracking system detector will be completed before the
 
current NSF funding cycle expires.  The R1 tracking system is expected to be delivered to JLab
 
during the summer of 2009 and be integrated with other tracking system components to test the
 
system before the scheduled installation in early 2010.  PI Forest will play a critical role
 
integrating the detector and front end electronics into the rest of the tracking system during the
 
first few months of this proposal as well as during the installation and operation of the system
 
in the two years that follow.  During the same time frame, CoPIs Cole and Dale will be responsible
 
for installing a clean room facility at ISU which will be used to construct drift chambers for
 
JLab's Hall B starting in early 2010.  The class-10,000 clean room for this project has been designed in collaboration with JLab's drift chamber management group and bids have been received.  The drift chamber construction for Hall B is
 
a critical component in support of the 12 GeV upgrade program at JLab and will
 
support the ISU physics program.
 
 
 
 
 
\begin{table}[h]
 
\begin{center}
 
\begin{tabular}{ll}
 
\multicolumn{1}{r}{Date}&
 
\multicolumn{1}{c}{Objective}\\
 
\hline\hline
 
06/09 & Begin installing a clean room for constructing Hall B R1 Drift Chambers \\
 
& at the Idaho Accelerator Center \\
 
09/09 & Complete testing of the $Q_{weak}$ Region 1 tracking system at JLab \\
 
01/10 & Begin Construction of R1 Chambers \\
 
03/10 & Complete installation of  $Q_{weak}$ Region 1 tracking system in JLab's Hall C \\
 
06/10 & Quality Assurance Tests for the First R1 Drift Chambers \\
 
10/12 & Install all R1 chambers in Hall-B \\
 
08/09 - 07/11 & Continue efforts with the Americas \\
 
% & in Latin America through the Latin American Symposia for \\
 
% & Nuclear Physics and Applications and further recruit students \\
 
% & into areas of research involving JLab physics. \\
 
08/09 - 07/11 & Analyze g8b and g13a/b data:  omega and charged rho production.  \\
 
\hline
 
\end{tabular}
 
\end{center}
 
\caption{Work Plan Timeline}
 
\label{table:Timeline}
 
\end{table}
 
 
 
====ISU's 12 GeV Physics Program====
 
 
 
The ISU group is currently the spokespersons on two experiments proposed for a 12 GeV upgraded Hall B. 
 
The first experiment, PR12-06-109, will make measurements that contribute
 
substantially to our knowledge of polarized parton distribution
 
functions for all quark flavors and even the polarized
 
gluon distribution $\Delta g$.  One particular outcome, shown in Figure~\ref{fig:JLab12GeVPhysics},
 
will improve our ability to test the high-x prediction made by pQCD and the constituent quark model. 
 
While pQCD predicts that $\frac{\Delta d}{d}$ should go to unity at $x_{bjk} =1$,
 
the constituent quark model, with hyperfine interactions, predicts a value closer to $-$1/3.  A second
 
component to ISU's 12 GeV program will seek to measure the exclusive
 
single- and double-pion channels
 
produced when 11-GeV electrons are directed onto a proton target with an upgraded CLAS detector. 
 
The goal will be to perform measurements of resonances, like the
 
$P_{11}(1440)$ resonance shown in Figure~\ref{fig:JLab12GeVPhysics}, which will be used as input
 
to models describing such transitions.  The Excited Baryon Analysis Center (EBAC) at JLab is one such
 
effort which will use an advanced coupled-channel approach in these fits.  These studies will
 
afford us the means to sample the transition from the hadronic
 
to partonic regime.
 
 
 
====List of Currently supported students====
 
 
 
{| border="1"  |cellpadding="20" cellspacing="0
 
|-
 
|Student|| Classification || Expected Grad Yr
 
|-
 
|Julian Salamanca|| Ph. D.  || 2009
 
|-
 
|Tamar Didbarize|| Ph. D.  || 2010
 
|-
 
|Danny Martinez|| Ph. D.  || 2012
 
|-
 
|Oleksei Kosinov|| Ph. D.  || 2012
 
|-
 
| Adrianne Spilker || M.S. ||2009
 
|-
 
|Shadike Saitiniyazi  || M.S.  || 2009
 
|-
 
|Jordan Keough || BS  || 2011
 
|-
 
|Nathan Lebaron|| BS  || 2012
 
|}
 
 
 
==The Broader Impact of the Idaho State University Nuclear Physics Research Program}\label{section:BroaderImpacts}
 
\subsection{The Americas}==
 
 
 
 
 
Our broader impacts activities are directed
 
towards the Americas, central and south. 
 
Over the past nine years, the two CoPIs have
 
have been active in outreach towards Latin America. 
 
CoPIs Dale and Cole can both communicate in Spanish.  Indeed,
 
this past year CoPI Cole
 
successfully completed Spanish 201 and 202 at ISU, as a Freshman
 
with an undeclared major, and he is presently enrolled in an advanced
 
Spanish composition course at the 300-level in the effort to attain fluency.
 
Speaking Spanish is necessary for our broader impacts activities.
 
South American physics students tend to read English
 
rather well, but speaking good 
 
English is entirely another matter.  To attract students,
 
one needs to present the many
 
research opportunities in medium energy nuclear physics in the United States while
 
dispelling subtle and not-so-subtle misconceptions, which abound. 
 
And to communicate these matters, it is imperative to speak good Spanish. 
 
 
 
We seek to promote dialogue between faculty members of North-American and
 
Latin-American institutions by finding common interests in research which
 
will allow for coordinating our programs in nuclear physics research.
 
Through this effort, we  expect to strengthen existing links and forge
 
new ones within the broad scope of the international nuclear physics
 
community. CoPI Cole has been a PI four times and a CoPI  twice on six separate
 
Americas Program grants, which amounts in \$130k in funding.
 
 
 
 
 
 
 
\medskip
 
\begin{center}
 
\underline{\sf Funding History}
 
\end{center}
 
 
 
\begin{itemize}
 
\item The {\sf III Latin American Workshop on Nuclear and Heavy Ion Physics}
 
(PI: Phil Cole) NSF-INT-9907453 for \$15,000
 
 
 
\item {\sf A Collaborative Effort between the U.S. and Colombia on the Physics
 
with Linearly Polarized Photons}. (PI: Phil Cole) NSF-OISE-0101815 for \$32,590.
 
 
 
\item {\sf Americas Program: Student Sponsorship at the Fourth Latin
 
American Symposium on Nuclear Physics, Mexico City, Mexico, September 24-28,
 
2001.}  (PI: Phil Cole)
 
NSF-OISE-0117545  for \$23,369
 
 
 
 
 
\item {\sf US-Brazil Student Sponsorship at the Fifth Latin American Symposium on Nuclear Physics; Santos, Brazil, September 1-5, 2003}
 
(PI: Phil Cole, CoPI Jorge Lopez) NSF-OISE-0313656  for \$18,000
 
 
 
\item {\sf U.S.-Argentina Collaborative Workshop in Nuclear Physics
 
and Its Applications} (PI: Chaden Djalali, CoPI: Phil Cole) NSF-OISE-0527110
 
for \$32,200.
 
 
 
\item {\sf US-Peru Workshop in Nuclear Physics and Its Applications,
 
June 11-16, 2007, Cusco, Peru} (PI: Chaden Djalali, CoPI: Phil Cole)
 
NSF-OISE-0652360 for \$32,200.  See:  VII Latin American Symposium on
 
Nuclear Physics and Applications, AIP Conference Proceedings 947 (2007),
 
Editors: Ricardo Alarcon, Philip L.~Cole, Chaden Djalali, and Fernando Umeres.
 
 
 
\end{itemize}
 
 
 
Recent outcomes of our links with the Latin American community
 
include Mr. Tulio Rodrigues' visit to Jefferson Lab in August 2004 to work
 
with CoPI Dan Dale
 
on theoretical calculations for the {\em PrimEx} experiment.  At the time
 
CoPI Dale was at the University of Kentucky.
 
Mr.~Rodrigues was supervised by Dr.~Arruda-Neto, head of the Nuclear Reactions
 
and Structure Research Group at the Physics Institute of the University of
 
S\~{a}o Paulo and received his Ph.D. in 2006.  Dr.~Rodrigues has visited ISU
 
twice in the past two years to work on {\em PrimEx}-related physics.
 
Another graduate student, Mr.~Vladimir Montealegre from the
 
Universidad de los Andes in Bogot\'{a}, Colombia, entered the Ph.D. program
 
at the University of South Carolina. 
 
Our recruitment efforts are paying off. 
 
Our group now has two strong Ph.D. students, Juli\'{a}n Salamaca and Danny
 
Mart\'{\i}nez, from Colombia and upon processing the necessary paperwork,
 
two more Ph.D. students from Colombia will join us in January, 2009. 
 
 
 
 
\medskip
 
\begin{center}
 
\underline{\sf The Need}
 
\end{center}
 
 
 
Lack of modern equipment is one of the main obstacles to research
 
in the less-developed Latin American countries.  There is, however,
 
considerable variation in the size and influence of the physics community by
 
individual countries~\cite{MoranLopez}.
 
A few groups have managed to pursue successful
 
experimental programs in countries with comparatively long traditions in
 
applied and basic research in the nuclear sciences; the chief examples
 
being Argentina, Brazil, Chile, and Mexico, countries where research is
 
fostered through collaborative efforts through annual national nuclear
 
physics conferences. Two of these countries  Brazil, site of the V LASNP,
 
and Argentina, site of the VI LASNPA,  have launched initiatives to
 
construct large facilities allowing for their use by the wider international
 
nuclear physics community: the Brazilian National Synchrotron Light Laboratory
 
(LNLS) in Campinas (about 70 miles west of S\~{a}o Paulo) and the Tandar heavy
 
ion accelerator in Buenos Aires, Argentina.  Other countries in the region
 
which have recently initiated activities aimed to improve their academic and
 
scientific infrastructure in the nuclear sciences include Bolivia, Colombia,
 
Peru and Venezuela. 
 
 
 
\medskip
 
\begin{center}
 
\underline{\sf The Opportunity}
 
\end{center}
 
 
 
There is ample room for collaborative overlap between the two hemispheres.
 
Establishing links between the United States and Latin America will provide a
 
means for recruiting high-caliber graduate-level students and post-doctoral
 
fellows to pursue research at US institutions and laboratories such as JLab,
 
RHIC, ORNL, RIA, and IAC.  Such an academic relationship between North and
 
South America will further strengthen the scientific endeavors of the nuclear
 
physics communities of both continents. There is at present a dearth of
 
graduate students pursuing advanced degrees in experimental and theoretical
 
nuclear physics at US universities. This shortage is keenly felt at the
 
national laboratories and facilities, where there is an abundance of Ph.D.
 
theses topics and a paucity of graduate students. 
 
The goal is to build
 
ties with faculty and students. While attracting students to US graduate
 
programs, we also wish to build new groups and infrastructure in Latin
 
America that would give the students an attractive career option in their
 
home country after graduation.
 
 
 
%\newpage
 
%\medskip
 
\begin{center}
 
\underline{\sf The Means and the Goals}
 
\end{center}
 
 
 
We seek to grow these outreach efforts and our group
 
will continue to write funding grants to the NSF Americas Program
 
for sponsoring students to attend future interactions of the Latin
 
American Symposium for Nuclear Physics and Applications.  CoPI Cole
 
was recently elected to the ten-member board International Organizing Committee
 
of the VIII Latin American Symposium on Nuclear Physics and Applications
 
to be held in Santiago, Chile, December 15-19, 2009.  As in the past,
 
the Committee's
 
responsibilities include the scientific program, formation of an
 
International Advisory Board, and some key aspects of the overall
 
organization of the Symposium.  Of this membership, three members are
 
from Universities in the United States.  With a colleague in Argentina, CoPI Cole further will
 
write a grant to the International Atomic Energy Agency to help defray
 
travel expenses for non-U.S.~students in Latin America, where typically
 
funding from the NSF cannot be obtained.
 
 
 
\subsection{Graduate Student Training and Marketability}
 
 
 
\hspace{0.5in} The role graduate students play in the experiments which take place within
 
our program provide them with marketable skill sets.  Maria Novovic and Jena Kraft are clear
 
examples of the impact members of this group have had training an underrepresented group in physics.
 
Maria Novovic was trained in data acquisition, scintillator construction, and data analysis.
 
She is currently a staff physicist at the University of Southern Alabama and is responsible for the
 
undergraduate physics laboratories in addition to her undergraduate instructor role. The graduate
 
training and experiences in PI Forest's lab were instrumental in securing her current position.
 
Jena Kraft, who found a position in industry, reported that her design skills acquired while making a high pressure gas chamber for the GEM detector during her thesis were a key ingredient to her current position. The detector construction and instrumentation projects described in this proposal will continue to be effective in training graduate students for the market place.
 
The Intermediate Energy Nuclear Physics Group at Idaho State University currently has three graduate students, listed in Table~\ref{table:Students}, working on JLab physics.  Our expectation is that this number will increase with the addition of two faculty with JLab projects and the annual influx of more than 10 incoming graduate students per year.
 
 
 
 
 
==Facilities==
 
 
 
 
 
\hspace{0.5in}The Idaho State University Department of Physics Strategic Plan
 
identifies the use of experimental nuclear physics techniques as
 
its focus area to addressing problems in both fundamental and
 
applied science.  The major efforts of the department include
 
fundamental nuclear and particle physics, nuclear reactor fuel
 
cycle physics, nuclear non-proliferation and homeland security,
 
accelerator applications, radiation effects in materials and
 
devices, biology and health physics.  Because of this focus, the
 
department has been characterized as one of the largest nuclear
 
physics graduate programs in the nation with an average of over
 
50 graduate students.  One of the key
 
ingredients to the department's success has been the completion
 
of the Idaho Accelerator Center (IAC) on April 30, 1999.  A substantial
 
amount of lab space (4000 sq. ft.) within the department has
 
become available due to a combination of the IAC and a remodeling
 
of the physics building.  A detector lab with the potential to
 
construct proto-type drift chambers in a clean room environment
 
is currently planned as part of the lab space renovation.
 
 
 
The Idaho Accelerator Center (IAC) is located less than a mile
 
away from campus and will provide a machining facility for
 
detector construction, an electronics shop for installation of
 
instrumentation, and beam time for detector performance studies.
 
The IAC houses ten operating accelerators as well as a machine and
 
electronics shop with a permanent staff of 8 Ph.D.'s and 6
 
engineers.  Among its many accelerator systems, the Center
 
houses a Linac capable of delivering 20 ns to 2 $\mu$s electron
 
pulses with an instantaneous current of 80 mA up to an energy of 25
 
MeV at pulse rates up to 1kHz.  The IAC has donated beam time to
 
the Q$_{weak}$ project for the purpose of testing detector
 
performance.  One of the goals of these tests will be to evaluate
 
the Q$_{weak}$ detector at high rates.  The IAC is well suited
 
for these rate tests as the Q$_{weak}$ calibration rates will be
 
much lower than the electron and photon rates the IAC is capable of
 
generating. A full description of the facility is available at
 
the web site (www.iac.isu.edu). 
 
 
 
The Beowulf REsource for Monte-carlo Simulations (BREMS) is
 
a 12 node, 64 bit cluster housed in the ISU physics department
 
which can support the high performance computing needs of
 
the physics research program.  This facility is the result of an
 
investment made by NSF award PHYS-987453.  This infrastructure
 
will be an effective means for performing GEANT4 simulations of
 
the Q$_{weak}$ experiment as well as Garfield simulations of the
 
Region II drift chamber design.  Simulation speed is increased on
 
BREMS by running the simulation in parallel on many CPUs.
 
A version of GEANT4 known as ParGeant4~\cite{ParGeant4} has recently been
 
distributed which will allow these simulations to be run in parallel.
 
 
 
=The Broader Impact of the Idaho State University Nuclear Physics Research Program=
 
== The Americas ==
 
 
 
 
 
Our broader impacts activities are directed
 
towards the Americas, cental and south. 
 
Over the past nine years, the two CoPIs have
 
have been active in outreach towards Latin America. 
 
CoPIs Dale and Cole can both communicate in Spanish.  Indeed,
 
this past year CoPI Cole
 
successfully completed Spanish 201 and 202 at ISU, as a Freshman
 
with an undeclared major, and he is presently enrolled in an advanced
 
Spanish composition course at the 300-level in the effort to attain fluency.
 
Speaking Spanish is necessary for our broader impacts activities.
 
South American physics students tend to read English
 
rather well, but speaking good 
 
English is entirely another matter.  To attract students,
 
one needs to present the many
 
research opportunities in medium nuclear physics the United States while
 
dispelling subtle and not-so-suble misconceptions, which abound. 
 
And to communicate these matters, it is imperative to speak good Spanish. 
 
 
 
We seek to promote dialogue between faculty members of North-American and
 
Latin-American institutions by finding common interests in research which
 
will allow for coordinating our programs in nuclear physics research.
 
Through this effort, we  expect to strengthen existing links and forge
 
new ones within the broad scope of the international nuclear physics
 
community. CoPI has been a PI four times and a CoPI  twice on six separate
 
Americas Program grants, which amounts in \$130k in funding.
 
 
 
 
 
 
 
\medskip
 
\begin{center}
 
\underline{\sf Funding History}
 
\end{center}
 
 
 
\begin{itemize}
 
\item The {\sf III Latin American Workshop on Nuclear and Heavy Ion Physics}
 
(PI: Phil Cole) NSF-INT-9907453 for \$15,000
 
 
 
\item {\sf A Collaborative Effort between the U.S. and Colombia on the Physics
 
with Linearly Polarized Photons}. (PI: Phil Cole) NSF-OISE-0101815 for \$32,590.
 
 
 
\item {\sf Americas Program: Student Sponsorship at the Fourth Latin
 
American Symposium on Nuclear Physics, Mexico City, Mexico, September 24-28,
 
2001.}  (PI: Phil Cole)
 
NSF-OISE-0117545  for \$23,369
 
 
 
 
 
\item {\sf US-Brazil Student Sponsorship at the Fifth Latin American Symposium on Nuclear Physics; Santos, Brazil, September 1-5, 2003}
 
(PI: Phil Cole, CoPI Jorge Lopez) NSF-OISE-0313656  for \$18,000
 
 
 
\item {\sf U.S.-Argentina Collaborative Workshop in Nuclear Physics
 
and Its Applications} (PI: Chaden Djalali, CoPI: Phil Cole) NSF-OISE-0527110
 
for \$32,200.
 
 
 
\item {\sf US-Peru Workshop in Nuclear Physics and Its Applications,
 
June 11-16, 2007, Cusco, Peru} (PI: Chaden Djalali, CoPI: Phil Cole)
 
NSF-OISE-0652360 for \$32,200.  See:  VII Latin American Symposium on
 
Nuclear Physics and Applications, AIP Conference Proceedings 947 (2007),
 
Editors: Ricardo Alarcon, Philip L.~Cole, Chaden Djalali, and Fernando Umeres.
 
 
 
\end{itemize}
 
 
 
Recent outcomes of our links with the Latin American community
 
include Mr. Tulio Rodrigues visit to Jefferson Lab in August 2004 to work
 
with Dr.~Dan Dale
 
on theoretical calculations for the PrimEx experiment.  At the time
 
CoPI Dale was at the University of Kentucky.
 
Mr.~Rodrigues was supervised by Dr.~Arruda-Neto, head of the Nuclear Reactions
 
and Structure Research Group at the Physics Institute of the University of
 
S\~{a}o Paulo and received his PhD in 2006.  Dr.~Rodrigues has visited ISU
 
twice in the past two years to work on PrimEx-related physics.
 
Another graduate student, Mr.~Vladimir Montealegre from the
 
Universidad de los Andes in Bogot\'{a}, Colombia, entered the PhD program
 
at the University of South Carolina. 
 
Our recruitment efforts are paying off. 
 
Our group now has two strong PhD students, Juli\'{a}n Salamaca and Danny
 
Mart\'{\i}nez, from Colombia and upon processing the necessary paperwork,
 
two more PhD students from Colombia will join us in January, 2009. 
 
 
 
 
\medskip
 
\begin{center}
 
\underline{\sf The Need}
 
\end{center}
 
 
 
Lack of modern equipment is one of the main obstacles to applied research
 
in the less-developed Latin American countries.  There is, however,
 
considerable variation in the size and influence of the physics community by
 
individual countries ~\cite{MoranLopez}.
 
A few groups have managed to pursue successful
 
experimental programs in countries with comparatively long tradition in
 
applied and basic research in the nuclear sciences; the chief examples
 
being Argentina, Brazil, Chile, and Mexico, countries, where research is
 
fostered through collaborative efforts through annual national nuclear
 
physics conferences. Two of these countries  Brazil, site of the V LASNP,
 
and Argentina, site of the VI LASNPA,  have launched initiatives to
 
construct large facilities allowing for its use by the wider international
 
nuclear physics community: the Brazilian National Synchrotron Light Laboratory
 
(LNLS) in Campinas (about 70 miles west of S\~{a}o Paulo) and the Tandar heavy
 
ion accelerator in Buenos Aires, Argentina.  Other countries in the region
 
which have recently initiated activities aimed to improve their academic and
 
scientific infrastructure in the nuclear sciences include Bolivia, Colombia,
 
Peru and Venezuela. 
 
 
 
\medskip
 
\begin{center}
 
\underline{\sf The Opportunity}
 
\end{center}
 
 
 
There is ample room for collaborative overlap between the two hemispheres.
 
Establishing links between the United States and Latin America will provide a
 
means for recruiting high-caliber graduate-level students and post-doctoral
 
fellows to pursue research at US institutions and laboratories such as JLab,
 
RHIC, ORNL, RIA, and IAC.  Such an academic relationship between North and
 
South America will further strengthen the scientific endeavors of the nuclear
 
physics communities of both continents. There is at present a dearth of
 
graduate students pursuing advanced degrees in experimental and theoretical
 
nuclear physics at US universities. This shortage is keenly felt at the
 
national laboratories and facilities, where there are an abundance of PhD
 
theses topics and a paucity of graduate students. 
 
The goal is to build
 
ties with faculty and students. While attracting students to US graduate
 
programs, we also wish to build new groups and infrastructure in Latin
 
America that would give the students an attractive career option in their
 
home country after graduation.
 
 
 
%\newpage
 
\medskip
 
\begin{center}
 
\underline{\sf The Means and the Goals}
 
\end{center}
 
 
 
We seek to grow these outreach efforts and our group
 
will continue to write funding grants to the NSF Americas Program
 
for sponsoring students to attend future interations of the Latin
 
American Symposium for Nuclear Physics and Applications.  CoPI Cole
 
was recently elected to the ten-member board International Organizing Committee
 
of the VIII Latin American Symposium on Nuclear Physics and Applications
 
to be held in Santiago, Chile, December 15-19, 2009.  As in the past,
 
the Committee's
 
responsibilities include the scientific program, formation of an
 
International Advisory Board, and some key aspects of the overall
 
organization of the Symposium.  Of this membership, four members are
 
from Universities in the United States.  CoPI Cole further will
 
write a grant to the International Atomic Energy Agency to help defray
 
travel expenses for non-U.S.~students in Latin America, where typically
 
funding from the NSF cannot apply.
 
 
 
==Graduate Student Training and Marketability==
 
 
 
hspace{0.5in} The role graduate students play in the experiments which take place within our program provide them with marketable skill set.  Maria Novovic and Jena Kraft are clear example of the impact member of this group has had train ing an underrepresented goup in physics. Maria Novovic was trained in data acquisition, scintillator construction, and data analysis. She is currently a staff physicist at the University of Southern Alabama and is responsible for the undergraduate physics laboratories in addition to her undergraduate instructor role. The graduate training and experiences in Dr. Forest's lab were instrumental in securing her current position. Jena Kraft, who found a position in industry, reported that her design skills acquired while making a high pressure gas chamber for the GEM detector during her thesis were a key ingredient to her current position. The detector construction and instrumentation projects described in this proposal will continue to be effective in training graduate students for the market place.
 
The Intermediate Energy Nuclear Physics Group at Idaho State University currently has three graduate students, listed in table~\ref{table:currentstudents}, working on JLAB physics.  Our expectation is that this number will increase with this years addition of two faculty with JLAB projects and the annual influx of more than 10 incoming graduate students per year.
 
 
 
=Budget Justification=
 
 
 
The three senior personnel on this project, Dr. Phil Cole, Dr. Dan Dale, and Dr. Tony Forest, each have established physics programs at Jefferson Lab and will continue to pursue those endeavors using the support itemized in the budget.  Almost 40% of the budget in this proposal is devoted to supporting several graduate students currently pursuing their Ph. D. degrees within the JLab research program.  Two undergraduate students will also continue to be supported by this grant.  Undergraduates supported in past years have made substantial contributions to the program while gaining research experience.  The support from this grant will be used to extend those experiences to include accelerator operations.  We plan to use undergraduates as operators of the accelerators we will be using to provide ionizing radiation for testing the detectors we build.
 
 
 
Our travel budget is based on the number of shifts we expect to take at JLAB as well as several collaboration meetings we will need to attend.  The ISU group was assigned 32 CLAS shifts in 2008 which requires at most 8 trips to JLab when the shifts are taken in blocks of 4.  Our past experiences indicate that the costs of an individual trip to JLAB from Idaho range between $1,200 and $2,000 per trip.  We estimate that we will spend approximately $16,000 per trip in order to absorb the market fluctuations as well as the probably increases in travel costs.  Each PI expects to attend at least 3 collaboration meetings per year.  The PI's have substantial roles in the Qweak, PRIMEX, and CLAS collaborations.  We estimate a cost of $18,000 for this travel.  We also expect to present the results of our work at conferences each year and request $4,000 to defray those costs. 
 
 
 
A shipping budget for $100 is requested to support the exchange of materials between JLab and ISU as we move towards construction of the RI tracking system for CLAS12.  Our Laboratory for Detector Science expends on average $3000 in consumables each year.
 
We expect to upgrade or replace an average of 1 computer each year which is used for data acquisition or analysis at a cost of $2000.  We will also add to our data acquisition system by purchasing a NIM/VME modules at a cost of $5000. During the first we plan to purchase two gate generators for digital signal generation and a VME module for producing LVDS signals.  The LVDS signal module will be used to test the front end electronics of the Qweak Region 1 tracking system.  In year two we plan on purchasing F1 TDC's for the purpose of measuring the performance of Drift Chambers developed as part of the CLAS 12 GeV upgrade.  We plan on purchasing several more channels of leading edge discriminators and post amplifiers in the final year to increase the number of detector channels we are capable of measuring with out current CODA based DAQ system.
 
 
 
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Latest revision as of 22:02, 23 August 2011