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The Annual Poster Session and Patterson College Chemistry Awards Poster Session and Awards Programs The Annual Patterson Chemistry Program is held in the spring of the year at a local four-year college that offer degree programs in chemistry: Chemists at all levels - whether they are practicing professional chemists, graduate students or undergraduate students - are invited to present their latest research to the wider community of chemists in Dayton – this year, the Dayton Local Section of the American Chemistry Society is honored to present the program at Central State University, in the Joshua I. Smith Center for Education & Natural Sciences Building (Atrium, 1st floor), located at 1400 Brush Row Road, Wilberforce OH, Tuesday, April 5 2016.
Dayton Local Section, American Chemical Society http://www.daytonacs.org
4/5/2016
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Program Agenda, Tuesday, 5 April 2016 Central State University
Joshua I. Smith Center for Education & Natural Sciences Building (CENS) Atrium, 1st floor
1400 Brush Row Road Wilberforce Ohio 45384
Poster Setup: 5:30 PM - 6:00 PM
Poster Judging: 6:00 PM - 7:00 PM
Poster Viewing: 6:00 PM - 7:30 PM
Awards: 7:30 PM - 8:15 PM
2016 DAYTON SECTION OFFICERS, American Chemical Society (ACS)
Chair: Freddie L. Jordan, Ph.D. Chair-Elect: Jenny Iskrenova-Ekiert, Ph.D. Immediate Past Chair: Wayne Cook, Ph.D. Secretary: Ms. Kerra R. Fletcher Treasurer: Prakriti Pollak, Ph.D.
Dayton Section Web Site:
http://DaytonACS.org Like us on Facebook
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History of the Dayton Section of the American Chemical Society The beginnings of the Dayton Section date back to 1929. The first official Chair of the Section was Dr. C. A. Thomas, who served from 1931-1932. Our current membership is about 450, covering the counties of Montgomery, Greene, Miami, Clarke, Preble, and Darke. Section meetings, featuring national and local speakers, are held quarterly and include a local poster session. In addition, the last meeting of the year honors the 50-year and 60-year members. The Section has a long history of administering local philanthropy:
The Patterson High School Chemistry Awards go to winners of the Patterson High School Chemistry Competition, which consists of two stages: examination and essay. First, second, and third prizes are $1000, $750, and $500. Originally established by Charles A. Thomas and Carroll A. Hochwalt, former Dayton chemists and Monsanto researchers, the top chemistry students in the area have been recognized since 1943. In 1990, the family of the late Austin M. Patterson, also a prominent Dayton chemist, assumed sponsorship.
Last year, a new competition was offered to encourage high school students who have an interest and aptitude in chemistry to persist in their STEM education. This competition is open to any chemistry student enrolled in one of the high schools within Dayton City Schools. The Marie Daly Award is named for Marie Daly, who in 1947 became the first African American woman to earn a Ph.D. in chemistry. This competition will be continued this year.
Recipients of The Patterson College Chemistry Awards are chosen by the faculty of each of the universities within the Dayton Section from their outstanding junior chemistry majors using the general criteria of scholarship, character, extra-curricular involvement, and potential for success after college. Winners receive a certificate of recognition and a check for $400.
The Patterson-Crane Award was originally established in 1949 as the Austin M. Patterson Award to acknowledge meritorious contributions to chemical literature and documentation of chemistry. Dr. Patterson was the first recipient for his work as editor of Chemical Abstracts from 1909-1914. The biennial award was expanded in 1975 to honor another Chemical Abstracts editor (1915-1958) and 1953 award recipient, E. J. Crane. The award, which includes a monetary honorarium, is now funded by a bequest of the Patterson family, by the Helen G. Crane Fund of the Columbus Foundation, and by the Patterson-Crane Award Fund of the Dayton and Columbus Sections.
The Dayton Section also participates and supports the Dayton/Miami Valley TechFest,
and contributes funds and judges for the West District Science Fair.
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History of the Society for Applied Spectroscopy
The Society for Applied Spectroscopy (SAS) is a non-profit, international, professional membership organization for scientists in all fields of spectroscopy, including physics, chemistry and other allied sciences. SAS is dedicated to those interested in all phases of spectroscopy: the science and art of light absorption, light emission, Raman scattering, and related forms of light-matter interaction for determining the composition and structure of matter.
History of our Host Venue
The history of Central State University, an 1890 Land-Grant Institution begins with our parent institution, Wilberforce University (WU), named in honor of the great abolitionist William Wilberforce. Established in 1856 at Tawawa Springs, Ohio, WU is affiliated with the African Methodist Episcopal Church and is one of the oldest Black-administered institutions of higher education in the nation. In 1887, the Ohio General Assembly enacted legislation that created a Combined Normal and Industrial Department at Wilberforce University. The objectives of this new state-sponsored department were to provide teacher training and vocational education, and to stabilize these programs by assuring a financial base similar to that of other state-supported institutions. The statue establishing the Combined Normal and Industrial Department declared that the institution was “open to all applicants of good and moral character” thereby indicating no limitations as to race, color, sex, or creed. It was clear, however, that the Department and its successors were designed to serve the educational needs of African-American students. Although this Department operated as part of Wilberforce University in most respects, a separate board of trustees was appointed to govern the state-financed operations. In 1941, the department expanded from a two- to a four-year program, and in 1947, it legally split from Wilberforce, becoming the College of Education and Industrial Arts at Wilberforce. The name was changed in 1951 to Central State College, and in 1965, the institution achieved university status. The University has grown steadily since its’ founding. In recent years, it has added new academic programs, established a new College of Science and Engineering, constructed a new academic building, four new residence halls, and began the construction of a new University Center scheduled for completion in Fall 2015. In February 2014, the 113th Congress of the United States designated Central State University an 1890 Land-Grant Institution. This designation is a distinct recognition for an Ohio institution of higher education, and Central State is one of two institutions to hold this distinction. The major impetus of the designation is to provide access to education and to promote opportunities for students with interest in Science, Technology, Engineering, Mathematics and Agriculture (STEM-A) integrated through all academic disciplines. In tandem with progressive academic achievement, the University has embodied tenets of Service…Protocol…Civility®. Its faculty, staff, and students will provide service to the institution, and various communities for the greater good; be guided by protocol and adherence
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to best practices in order to gain desired results; and actively demonstrate civility with the understanding that respect for each voice is essential to a learned society. Much more has changed at Central State University throughout its history. However, one constant is the commitment to providing an excellent, affordable education to the residents of Ohio and beyond. In concert with the mission of the University, Chemistry faculty foster the professional development of students through academic excellence, and provide educational opportunities to students to be competitive in a technological society. The specific objectives of the discipline are to provide students with; 1) a thorough understanding of basic and modern concepts of chemistry and 2) the ability to analyze and apply chemical concepts to technical problems through the development of laboratory skills. Opportunities exist for undergraduate research experience, both on campus and through summer internships. Development of a strong sense of professionalism, with the motivation to pursue graduate study is encouraged. Professional programs include preparation for dental, medical, pharmacy and veterinary schools. An option in forensic science will prepare students for jobs or graduate school in forensic science. The program leads to a Bachelor of Science; in addition, a student may receive a B.S. degree in Secondary Education in middle school education in the Physical Sciences. 129 Years of Service and Excellence 1887–2016 The Dayton Section of the American Chemical Society thanks Provost and Vice President for Academic Affairs, Charles Wesley Ford, Jr., Ph.D., Chemistry Department Interim Chair, Dr. Ibrahim Katampe, as well as all the department faculty and students of Central State University for welcoming, hosting, and providing support for the 2016 ACS Poster Session.
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Patterson College Chemistry Awards 2016
As noted previously, the Patterson College Chemistry Awards
are administered by the Dayton Local Section of the American
Chemical Society and are presented annually to outstanding junior
chemistry majors at each university within the Section’s boundaries.
For 2016, the awardees are:
Phuc (Leo) Vo Wittenberg University
Michael Coladipietro University of Dayton
Kara N. Sulek Cedarville University
Kristy Rochon Central State University
Nick Yahna Wright State University
The following pages contain short biographies of the honorees. The
Dayton Section offers its most sincere congratulations to these
distinguished college chemistry students.
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2016 Patterson College Chemistry Award Recipient for Wittenberg University,
Springfield Ohio*
Phuc (Leo) Vo is an undergraduate Chemistry major at
Wittenberg University, class of 2017. He grew up in Saigon,
Vietnam, and spent the last two years of high school in Fleetwood,
England. During his time at Wittenberg, he has taken part in
summer research projects, utilizing molecular dynamic and
quantum mechanical simulations to study protein – ligand
interactions as well as organic reaction mechanisms. He was also
given the opportunity to present on his computational research at
the annual MERCURY Consortium at Bucknell University, Pennsylvania, as well as at the COMP
Division of the 251st ACS National Meeting and Exposition in San Diego, California. In his college
studies, Leo greatly enjoys organic chemistry and biochemistry, with a flickering interest in
biology. He also enjoys learning programming and computer science, which is possible through
spending numerous hours on the computer doing research. After college, he hopes to pursue a
Doctorate in computational chemistry and pharmacology either in the States or abroad, and
then to pursue a career in the pharmaceutical industry. In his free time away from the
computer or the lab, Leo enjoys playing the guitar, watching and playing basketball and soccer,
videogames and cycling. He is also an active and dedicated member of Wittenberg’s Chemistry
Club, where he served as Vice President during the 2015 – 2016 academic year, and has also a
member of Greek Life at Wittenberg since his freshman year. Leo is currently working on
finishing his summer research on the mechanism of the nucleophilic acyl substitution by the
end of 2016, and getting the project published in the future.
*Recipient Department submission:
Justin Houseknecht, Ph.D.
Chair, Department of Chemistry
Leadership Board, Organic Educational Resources (OrganicERs.org)
Science 245E
Wittenberg University
PO Box 720
Springfield, OH 45501-0720
(937)327-6437
jhouseknecht@wittenberg.edu
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http://userpages.wittenberg.edu/jhouseknecht/
2016 Patterson College Chemistry Award Recipient for the
University of Dayton, Dayton Ohio*
Michael Coladipietro is a junior
undergraduate student at the University of
Dayton pursuing a degree in Medicinal
Pharmaceutical Chemistry with minors in
Mathematics and Biology. Outside of the classroom, Michael has
devoted a substantial amount of time in Dr. Shawn Swavey’s lab
as well as tutoring for general and organic chemistry. He has also
instructed organic chemistry lab, and most recently consults for
organic chemistry labs, performing experiments and commenting
on the potential implementation into the curriculum. Michael also
serves as the treasurer of Alpha Epsilon Delta, the Pre-health
professions honor society, as well as the volunteer coordinator for the Red Cross Club. He is
a member of the Power Lifting Club at the University of Dayton, where he trains with other
members for competitions.
Michael aspires to continue his education pursuing a dual degree MD-PhD to be trained as
both a physician and a scientist. He came into college with aspirations to become a
physician. But, an increasing interest in the complexities of chemistry and new found love of
research have influenced a desire to continue studying chemistry in hopes of earning a PhD.
Education has always been something that has been strongly emphasized by his parents
and grandparents, so it is no surprise he wants to spend at least 8 more years in school.
He permanently resides in Joliet, IL with his parents, Marco and Lynn, and sister, Marisa. In
his free time, Michael enjoys watching sports, but loves watching baseball and the Chicago
Cubs. He also enjoys playing racquetball and pick-up basketball and ping pong and any type
of cards.
*Recipient Department submission:
Department of Chemistry
University of Dayton
Science Center Room 178
300 College Park
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Dayton, OH 45469
(937) 229-2631
2016 Patterson College Chemistry Award Recipient for Cedarville University,
Cedarville Ohio*
Kara N. Sulek grew up in
Cedar Rapids, Iowa, and from
an early age, she always loved
learning about the world
around her and how the
intricately designed universe
functions. When she started
college, chemistry seemed like a
natural choice for a major so that she could keep learning
about science. In her time at Cedarville, in addition to classes, she has enjoyed being
involved in the chemistry club for two years, she has had the privilege of serving as an
resident assistant in the dorms, and she’s been able to go on two short-term domestic
missions trips. Next year, she plans on applying to a program called the Memphis
Teacher Residency (MTR), which is a four year program starting immediately after
graduation. MTR is a program that involves earning a master’s degree in urban
education in order for her to able to teach chemistry to high school students at an inner-
city school in Memphis, TN.
*Recipient Department submission:
Dennis R. Flentge, Ph.D.
Senior Professor of Chemistry
Chair, Department of Science & Mathematics
Cedarville University
flentged@cedarville.edu
(937)-766-7949
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2016 Patterson College Chemistry Award Recipient for Central State University,
Wilberforce Ohio*
Kristy Rochon is a dual major at
Central State University pursuing
Bachelor's of Science degrees in
Chemistry and Biology. She served
as a Public Affairs Officer in the
United States Air Force and has
started two companies--Totem Design Group,
a graphic design and consulting company and
InfiniPure a technology company
commercializing Air Force Research Laboratory technology to remove harmful ions
from residential water. Her undergraduate research studies have included the
development of organic dyes with possible antibacterial properties and the feasibility
of establishing bio-fuel energy generators in rural India. Kristy is in the honors
program at CSU and on the Dean’s list. She was recently accepted to participate in
the University of Cincinnati's National Science Foundation-sponsored Research
Experiences for Undergraduates where she will intern for ten weeks and participate
in research projects that focus on Sensory Ecology – the study of how animals
acquire and respond to information about their environment. Kristy plans to pursue
a graduate program where she can study prion diseases and pursue a research
career in medical and biochemistry disciplines.
*Recipient Department submission:
Dr. Ibrahim Katampe
Interim Chair, Department of Natural Science
Central State University
1400 Brush Row Road
Wilberforce Ohio 45384
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2016 Patterson College Chemistry Award Recipient for Wright State University,
Dayton, Ohio*
Nick Yahna was
born in Dayton, Ohio on 11/22/94 and
have lived there my entire life. He
attended Wayne High School where he
graduated 5th in his class (out of 420) with
a 4.31 GPA. He has always excelled in
science and math and while taking a
chemistry class his senior realized he really
enjoyed it. Through his first three years at
Wright State he accumulated a 4.0 GPA. He is also the recipient of the Gupta
Chemistry Scholarship for the 2015-2016 school year and has maintained the
Dean’s List four times. Additionally, he is a member of the honors program and
has been doing undergraduate research with Dr. Feld since summer 2015; also
maintains a job through Dr. Feld, working with Wright Patterson Air Force base
synthesizing starting materials.
*Recipient Department Submission:
David A. Grossie, PhD Chair and Associate Professor Chemistry Department Tel. (937) 775-2855 202 Oelman Hall Direct Tel. (937) 775-2210 Wright State University Fax: (937) 775-2717 3640 Colonel Glenn Hwy. URL: http://www.chm.wright.edu/grossie/ Dayton, Ohio 45435-0002 david.grossie@wright.edu
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Poster No. 1
Formation of Insulating Oxide Films with Hydrolysis Reaction of Alkoxides in
Supercritical CO2: Chemistry, Morphology, Characterization and Film
Thickness
Joanna Wang(1); Gail Brown(1); Chien Wai(2); Scott Apt(1); Howard Smith(1); Laraba
Kendig(1)
1Materials and Manufacturing Directorate, Wright-Patterson Air Force Base, Wright Patterson
AFB, OH, United States. 2University of Idaho, Moscow, ID, United States.
1Graduate Presenter
Abstract
Insulating SiO2 films can be produced by hydrolysis of metal alkoxide
tetraethylorthosilicate (TEOS) in the presence of an acid catalyst in supercritical CO2 (sc-
CO2). SiO2 films are formed on substrates using TEOS as a source of silicon, and acetic
acid (HAc) as a catalyst. The chemical equation of the SiO2 film formation can be
expressed as Si(OCH2CH3)4 + 2H2O -- SiO2 + 4CH3CH2OH. Water required for the
hydrolysis is from in situ generation of esterification reactions involving HAc and the
alcohol produced. Without the catalyst, the hydrolysis of TEOS proceeds very slowly.
The acid catalyzed deposition reaction actually starts at room temperature but produces
decent films in sc-CO2 at moderately high temperatures. Supercritical CO2 is known to
have near zero surface tension and provides an ideal medium for fabrication of SiO2
films. Formation of SiO2 films via hydrolysis in sc-CO2 is more rapid compared to the
traditional hydrolysis reactions at room temperature. Metal alkoxide hydrolysis reactions
carried out in a closed sc-CO2 system is not affected by moisture in air compared with
traditional open-air hydrolysis systems. Using sc-CO2 as a reaction medium also
eliminates undesirable organic solvents utilized in traditional alkoxide hydrolysis
reactions. The ATR-FTIR, EDS, XRD, XPS spectroscopy, and electron diffraction (ED)
measurements were conducted to characterize the films. XRD and ED measurements
demonstrated the SiO2 films produced were amorphous. EDS, ATR-FTIR and XPS
spectra showed elemental composition of the films formed on the substrate surfaces to be
SiO2. The amount of catalyst on the film thickness is discussed.
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Poster No. 2
Comparison of the Thermal Properties of Poly(arylene ether)s Prepared from
of N,N-dialkyl-2,4-difluorobenzenesulfonamide and N,N-dialkyl-3,5-
difluorobenzenesulfonamide
James Waweru1, Steven Ujvary, Jasper van den Hoek, Eric Fossum*
Department of Chemistry, Wright State University, 202 Oleman Hall, 3640 Colonel Glenn Highway,
Dayton, OH 45435, USA
Graduate Award Presenter1
Abstract
A series of poly(arylene ether)s was synthesized by the nucleophilic aromatic
substitution (NAS) polycondensation reactions of N,N-dialkyl-2,4-
difluorobenzenesulfonamide and N,N-dialkyl-3,5-difluorobenzenesulfonamide. The
sulfonamide-activated monomers were synthesized by reacting 2,4- and 3,5-
difluorobenzenesulfonyl chloride with a series of dialkyl amines, ranging from n-propyl
to n-octyl. The poly(arylene ether)s, prepared with bisphenol-A as the nucleophilic
reaction partner, were characterized by 1H and
13C NMR spectroscopy, TGA, DSC and
SEC. The thermal properties of the N,N-dialkyl-2,4-difluorobenzenesulfonamide
polymers were compared to those of the N,N-dialkyl-3,5-difluorobenzenesulfonamide
system. Poly(arylene ether)s prepared from the 2,4-monomers possessed consistently
higher glass transition temperatures than those from the 3,5-monomers. While the 5%
weight loss temperatures were similar for both systems, there were observable differences
in the TGA traces, indicating that the decomposition pathways may not be the same.
F
F
SO O
NR R
+
F
SO O
NR R
NMP, K2CO3
185 0C, 21H
SO O
NR R
+
SO O
NR R
NMP, K2CO3
185 0C, 21H
FF
HO Ar OH
O Ar O
HO Ar OH O Ar O n
Fn
R = propyl, iso-propyl, butyl, hexyl, cyclohexyl, octyl, and iso-octyl.
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Poster No. 3
Synthesis of Functionalized PEEK Analogues via “One-Pot” Synthesis
Zachary Ewing1 and Eric Fossum Wright State University
ewing.51@wright.edu
1Graduate Student Presenter
Abstract
Poly(ether ether ketone), PEEK, is known for its high thermal stability, chemical and
corrosion resistance, and versatility. When functional groups are introduced to PEEK,
crystallinity is often disrupted causing some of the desirable properties to diminish.
Synthetic routes that allow functionalization, but permit the crystallinity to be maintained
are highly desirable. This presentation will focus on our attempts to prepare functional,
semi-crystalline PEEK analogues. The overall project has two goals: 1) to demonstrate
semi-crystalline properties in copolymers of PEEK with pendent functionalization sites,
and 2) to synthesize copolymers of PEEK with pendent functional groups. The optimum
percentage of traditional PEEK in the copolymers was investigated, as was the
importance of the monomer addition order. The level of crystallinity was determined via
DSC and X-ray diffraction analyses. Copolymers of PEEK containing up to 25 % of
repeat units derived from 3,5-difluorobenzophenone remain semi-crystalline, but with
better solubility than PEEK.
Scheme 1
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Poster No. 4
A Sequence Comparison of Cytochrome Oxidase I in Hadenoecus
cumberlandicus populations found in the Sloans Valley Cave System, Pulaski
County, Kentucky
Rebecca Holmes1
and Brandon Miner1
1Undergraduate Presenter(s)
Abstract
Sloan’s Valley Cave, located in Pulaski County, KY, is one of the largest cave
systems in the Cumberland Plateau, with at least 39 km of documented passage and 16
entrances. The distribution entrances throughout the system, allow for a greater diversity
of organisms to enter and exit the system, contributing to the balance of the cave's
ecosystem.
Hadenoecus cumberlandicus is one of several troglophiles that inhabit the Sloan’s
Valley Cave. These crickets migrate within the cave throughout the year, staying deeper
in the system during cold months and closer to an entrance during warm months. At each
point of their migration these crickets may have contact with outside populations; other
entrance populations at interior cave locations in the cold months, and exterior
populations from neighboring caves during warm months. These outside contacts allow
for interbreeding of the populations, increasing the genetic diversity of a given entrance
population.
After collecting samples of H. cumberlandicus from five entrances, DNA was
purified from a single hind femur from all collected samples. Regions of the COXI gene
were amplified by PCR. Four of the ten UEA primers within the 1500bp segment were
selected to produce two overlapping fragments to be used later to sequence about one-
fourth of the gene. Amplification with primers UEA7 and UEA10 selected a 550 bp
fragment and primers UEA5 and UEA8 selected a 220 bp fragment . The PCR products
were purified, with a yield of 2.71∗10 2ng/μl determined by Abs 260 . Sequencing of
these purified amplification products permits identification and analysis of single
nucleotide polymorphisms (SNPs) to assess the genetic variability within and among the
populations and determine the level of genetic mixing.
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Poster No. 5
Reduced Order Experimental Configuration Studies of Wood Combustion
Sari S. Miraa, Robert D. Stachler
a, and Joshua S. Heyne
a
aUniversity of Dayton, Department of Mechanical and Aerospace Engineering, 300
College Park Ave, Dayton, OH 45469
miras1@udayton.edu
(Academic advisor is Dr. Joshua Heyne; Associate Professor in the Department of
Mechanical and Aerospace Engineering at the University of Dayton.)
Graduate Award Presenter(s): S. Mira and R. Stachler
Abstract
Wood is one of the largest renewable biomass energy resources used today, yet it is not
necessarily a clean source of energy. The combustion process of wood is largely
unoptimized, as it is inherently multidimensional and multi-phase, and the formation of
emissions such as CO, NOx, and other particulates are results of both deficient and
copious mixing. Thus, standard experiments characterizing the emissions/speciation and
performance of wood combustion using various fundamental and applied experimental
configurations can contribute in part to the reduction of emissions and increases in
efficiency. Previous studies focused on experimental configurations similar to so-called
stove combustion (i.e. multiphase, multidimensional). This model reduces computational
and experimental complexity and simulation cost, while validating wood combustion
apparatus designs. Here, we discuss an experimental configuration in which the
initial/boundary conditions are both well-characterized and entirely gaseous, and the
geometry can be modeled as zero or one-dimensional. Thus, a preliminary study of gas-
phase wood specific species was conducted in order to design and speculate the potential
benefits of these reduced order experimental configurations. The study consists of
building a model capable of producing results for one of these configurations, a
counterflow diffusion flame experiment, validated by existing and established
experimental results. The developed model will be used to produce results for dry
hardwood following the work of Ranzi et al. (Ranzi, Couci, Faravelli, et al., 2008).
Future work will be building the established experimental counterflow diffusion flame
apparatus to validate the dry hardwood model and to build more comprehensive biomass
kinetic mechanisms.
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Poster No. 6
Fabrication of a gold nanoparticle-functionalized paper microfluidic device
for the detection of biomarkers from whole blood
Anna Gutridge1
and Veronica Betancur2, Xuefei Gao
2, Nick Wu
2, Yuxin Liu
3
1Department of Biochemistry, Wittenberg University, Springfield, OH 45501,
2Department of
Mechanical Engineering and Aerospace Engineering, 3Lane Department of Computer Science
and Electrical Engineering, West Virginia University, Morgantown, WV 26505
Undergraduate Presenter1
Abstract
Diagnostic testing is widely unavailable in the developing world due to a lack of
healthcare, medical instruments and health professionals. As a result, there are great
needs for diagnostic tools with low fabrication costs, ease of interpretation, and
compatibility with low sample volumes. An integrated paper based device with flow
directed by hydrophobic wax channels and propelled by capillary action has been
developed allowing for plasma separation from whole blood through a plasma separation
membrane, detection of a targeted biomarker (IgG) down to 0.05 mg/mL, easy handling
for the user and low fabrication costs. Using gold nanoparticles (AuNPs), which exhibit
colorimetric properties, the detection of proteins in the blood can be made possible by
linking the AuNPs to antibodies corresponding to the targeted biomarker using gold
nanoparticle-based colorimetric sandwich immunoassay. In the design and fabrication of
the integrated device, the amount of antibodies and AuNPs to functionalize the paper
substrate were modified. With further modification, this platform can be used to test for a
multitude of biomarkers in the body.
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Poster No. 7
Grafted and Untreated Activated Carbon for Use as Solid Phase Extraction
Media for Preconcentrating Copper and Lead Ions
Margaret A Colea and Dr. Kristin K Cline
b
a) Wittenberg University
Colem@Wittenberg.edu
Undergraduate Award Presentera
Abstract
Following published procedures, carboxybenzenediazonium and
nitrobenzenediazonium ions were synthesized in the presence of carbon particles. Cyclic
voltammetry of the product solution showed characteristic diazonium reduction peaks
and carbon paste electrodes made from the modified carbon particles showed evidence of
nitrophenyl groups, suggesting that this method is successful in grafting the carbon.
Bare carbon and grafted carbon particles, as well as commercial SPE tubes, were
compared for their ability to trap copper (II) and lead (II) ions. Acid-eluted metal ions
were quantified with flame atomic absorption spectroscopy. Initial results show no
significant difference for copper and lead extraction on unmodified vs. carboxybenzene-
grafted carbon particles. Both unmodified and carboxybenzene-grafted carbon particles
showed about 90% recovery for copper(II) (0.2 mg/L) and lead(II) (0.5mg/L), while
commercial tubes had recovery of about 30% at low level concentrations and 0.4% for
higher level concentrations of lead(II) solutions. Concentration factors of up to 20 were
achieved.
**Undergraduate competing for awards.
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Poster No. 8
Dioxyalkylene PEEK polymers containing vanillin subunits
James Herborta and W.A. Feld
a
a) Wright State University
James.Herbort@hotmail.com
Undergraduate Presenter – J. Herbort
Abstract
Vanillin has many interesting properties and is frequently used as a building block in
organic synthesis. Poly(ether ether ketone)s (PEEK) have been known to exhibit thermal
stability, solvent resistance, and excellent mechanical properties. A series of
dioxyalkylene based monomers containing vanillin subunits were generated via a three-
step process, 1) a Williamson ether synthesis, 2) a Grignard reaction with p-
bromofluorobenzene, and 3) a Jones oxidation. The monomer was then polymerized in an
A2B2 Nucleophilic aromatic substitution (NAS) polymerization with Bisphenol-A. The
polymers exhibited thermal stability with 5% weight loss occurring at about 390 °C and
Tg occurring around 100 °C.
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Poster No. 9
Synthesis, Characterization, and Polymerization of Sulfonamide Based
Bifunctional Monomers
Brady Hall1, Jessica Munch, Luke Meyer, Eric Fossum
1Graduate Award Presenter
Abstract
Bifunctional monomers, monomers containing two distinct polymerizable moieties, aid in
pre- or post polymerization functionalization. This project seeks to develop bifunctional
monomers in which one of the polymerizable moieties can undergo nucleophilic aromatic
substitution (NAS) reactions. The overall project has two goals: 1) to synthesize
bifunctional monomers, such as N,N-diallyl-3,5-difluorobenzenesulfonamide, and 2) to
form polymers using acyclic diene metathesis (ADMET), radical cyclopolymerization,
and NAS, followed by the appropriate functionalization chemistry. The monomers were
prepared via the reaction of diallyl amine with the appropriately substituted
benzenesulfonyl chloride. The ADMET and radical cyclopolymerizations were
monitored by 1H NMR spectroscopy, observing the disappearance of signals for the allyl
groups and the appearance of broad aliphatic signals. The polymers formed via NAS
reactions were followed by DEPT 90 13
C NMR spectroscopy. Additionally, GPC, DSC,
and TGA were used to characterize the polymers, which indicated successful ADMET,
cyclopolymerization, and NAS reactions.
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Poster No. 10
Extraction of Natural Dyes: Effect of pH on Color Process and Application
Leanne Petrya,*, Craig George
b, Amanda Grear
c, and Ibrahim Katampe
a
aCentral State University, 1400 Brush Row Rd, Wilberforce OH 45384
bGreeneview Local Schools,
cUpper Valley Career Center
*Corresponding Author Email: lpetry@centralstate.edu
Keywords
Dyes, pH, extraction, anthocyanin, spectroscopy
Abstract
Colorants are used to modify the color of commercially manufactured natural and
synthetic materials. Natural dyes have been used by numerous ancient cultures to dye
handmade goods. Natural dyes extracted from sources containing anthocyanin will have
color variations based on the pH of the dye solution and substrate. Understanding how
the pH affects natural dyes during extraction and application will allow more variety of
colors to be produced and will expand their relevance to manufacturing materials. To
examine how pH affects the colors of natural dyes during extractions and to investigate
how pH affects the color of natural dyes on different substrates, natural dyes were
extracted from several plants using a variety of methods. The pH was modified during
and after the extraction process. The resultant dyes were analyzed by UV-Vis
Spectroscopy and then applied to natural fibers and bioplastics. Results will be presented
and discussed.
P a g e | 21
Poster No. 11
Synthesis of Azo Dyes: Effect of pH on Color Process and Application
Leanne Petrya,*, Craig George
b, Amanda Grear
c, and Ibrahim Katampe
a
aCentral State University, 1400 Brush Row Rd, Wilberforce OH 45384
bGreeneview Local Schools,
cUpper Valley Career Center
Corresponding Author Email: lpetry@centralstate.edu
Keywords
Dyes, azo, pH, spectroscopy, natural, synthetic, fibers
Abstract
Colorants are used to modify the appearance of commercially available manufactured
materials. At least 66% of all colorants are of the azo type. Azo dyes are a nitrogen-
containing compound created by combining a diazo aniline and a coupling agent during a
coupling process where pH has been observed to modify the resulting color.
Understanding how the pH affects the azo dye during all stages of the synthesis process
will enable a greater matrix to be developed, tested, and modeled relative to natural dyes
thereby expanding their manufactured end use possibilities. Thus, various azo dyes were
synthesized inhouse, modifying the pH throughout different steps in the process to
examine how pH affects the colors of azo dyes during synthesis. The resultant dyes were
analyzed by UV-Vis Spectroscopy and then applied to natural fibers and bioplastics to
investigate how pH affects the colors of azo dyes versus natural dyes on different
substrates. Results will be presented and discussed.
P a g e | 22
Poster No. 12
Natural and Synthetic Dyes: Application to Fibers and Bioplastics
Leanne Petrya,*, Joseph Duncan
b, Linda Gillum
c, Miyong Hughes
a, and Ibrahim Katampe
a
aCentral State University, 1400 Brush Row Rd, Wilberforce OH 45384
Kettering City Schools, cSpringboro City Schools
*Corresponding Author Email: lpetry@centralstate.edu
Keywords
Dyes, spectroscopy, natural, synthetic, fibers, bioplastics
Abstract
Civilizations have extracted colorants from organic sources, with the earliest found in
prehistoric cave paintings. The first recorded mention of fabric dyeing was using natural
pigments mixed with water and oil to decorate skin, jewelry and clothing. The synthetic
organic chemistry industry began preparing the dye mauve from coat-tar chemicals.
Today, most clothing is dyed synthetically, with synthetic azo dyes being the most
predominant. Synthetic dyes are cheap to produce, do not vary batch to batch, and will
dye a wide range of substances. However, chemical dyeing can cause significant
environmental degradation and harm to workers when not handled properly. The
wastewater from textile plants is classified as the most polluting of all industrial sectors
with dye wastewater becoming one of the substantial sources of severe pollution
problems. Toxic chemicals are absorbed into the skin of the workers when they come
into prolonged contact with the synthetic dyes. A return to the use of natural dyes and
bioplastics would benefit both the workforce and the planet. Natural dyes from various
plants were extracted using aqueous materials. Diazo dyes were synthesized from
phenol, naphthol, and resorcinol. The isolated dyes were characterized using UV-Vis
Spectroscopy and applied onto fibers and bioplastics. The dyed materials were further
evaluated for stability using fastness testing. Results will be presented and discussed.
P a g e | 23
Poster No. 13
Synthesis and Studies of Some New Hydrazophosphonates and
Azophosphonates
Maeve Meiera, Albert Fratini and Vladimir Benin
1
b) Department of Chemistry, University of Dayton, 300 College park, Dayton, OH 45469-2357
Presenting author email address: meierm2@udayton.edu
1Graduate Award Presenter
We are reporting the preparation and studies of some novel structures, containing one
(compounds 1,3) or two phosphonate moieties (compounds 2,4), connected to a central hydrazo
or azo core. These are some of a series of P – N containing compounds, that are being prepared
and studies by us in terms of their potential as reactive flame retardants. However, both classes
of substances are unknown and this has necessitated thorough structural investigation.
Preparation of the hydrazophosphonates 1,2 was achieved via interaction of the
corresponding carbazates or phosphonyl hydrazines with the appropriate phosphoryl chlorides.
The resultant hydrazophosphonates were further oxidized with either N-bromosuccinimide
(structures 1) or lead tetraacetate (structures 2), leading to the corresponding azophosphonates
3,4. The azo compounds have been the subject of detailed structural investigation, including
single crystal X-ray, thermal decomposition and kinetic studies, and elaborate theoretical
analysis. We have also started studies of their reactivity in cycloaddition (Diels-Alder type)
reactions.
P a g e | 24
Poster No. 14
Poly(arylene ether)s with Ammonium Groups Located on Pendent Phenyl
Sulfonyl Moieties for use as Anionic Exchange Membranes
Trevor I. Schumachera, Eric Fossum
b, Juxiang Yang
b
a) Wright State University graduate student, would like to be considered for a reward
b) Advisor and past student that inspired the present project
Abstract:
A series of poly(aryl ether)s with varying percentages of ammonium groups,
located on truly pendent positions, was prepared and characterized. The initial polymers
were prepared by nucleophilic aromatic substitution (NAS) polycondensation reactions of
varying ratios of 3,5-difluorophenylsulfonyl toluene and 4,4’-difluorodiphenylsulfone,
with bisphenol-A as the nucleophilic reaction partner. The tolyl groups in the resulting
polymers were subjected to radical bromination with N-bromosuccinimide, followed by
amination with three different amines: trimethylamine, dimethylhexadecylamine, and N-
methyl-imidazole. The polymers were characterized by 1H and
13C NMR spectroscopy,
thermogravimetric analysis, and differential scanning calorimetry. With the exception of
the 100% functionalized polymers, tough films were observed after casting from
solutions in dimethylformamide. The films were evaluated for potential use as alkaline
exchange membranes (AEM) by determining their water uptake and ion exchange
capacity values.
Scheme:
P a g e | 25
Poster No. 15
Polymerization of PEEK AA+BB monomers containing meta substituted
oxyalkylene linkages
James Ohaeri1
and William A. Feld
Department of Chemistry, Wright State University, 3640 Colonel Glenn Hwy, OH 45435
Email: ohaeri.2@wright.edu
Graduate Poster Presenter1
Poly(ether ether ketone)s – PEEK polymers are known for their unique properties
including excellent thermal stability, solvent resistance and mechanical properties. Since
their discovery, various alterations have been done to enhance its properties. A series of
Poly(ether ether ketone)s – PEEK monomers have been synthesized via a three step
process involving oxyalkylene dibenzaldyde synthesis, Grignard reaction to aid the
addition of benzofluoro groups and subsequent oxidation to form a ketone.
Polymerization occurred in an A2+B2 fashion with Bisphenol-A under NAS conditions
(NMP, Toluene, Potassium carbonate). Previous work has shown the synthesis of para
substituted PEEK systems that formed flexible, colorless, transparent films, and exhibited
excellent thermal stability. Current research investigates synthesizing similar PEEK
systems with meta substituted oxyalkylene linkages.
Polymerization of PEEK AA+BB monomers containing meta substituted oxyalkylene linkages
P a g e | 26
The Dayton Local Section Officers would like to thank all participants, their
department chairs and institutions for their involvement in the 2016 Annual
Poster Session. We extend congratulations to (all) for their research
contributions and participation in this event. It is our hope that you will
continue to be enlightened and enriched by your research endeavors as you
navigate your professional destination.
Concerning the Patterson College Chemistry Awards, we also extend a personal
thanks for the support and coordination provided by Dr. Barry Farmer, Chair of
the Patterson College Chemistry Awards Committee. A special thank you as well
to Dr. Leanne Petry for support and guidance while navigating many logistical
matters and the hospitality extended to the Section as our host site - Central
State University.
Finally, we thank our Treasurer, Dr. Prakriti Pollack, our Section Secretary, Ms.
Kerra Fletcher and Dr. Yu Kay Law, for continual management of our social media
venues. You enhance our effort to stay connected with our community partners
and those we serve.
The Dayton Local Section Officers 2016