Thursday, October 26, 2017

Student Outreach for National Chemistry Week


Students from the IU South Bend Biology and Chemistry Club kicked off National Chemistry Week (October 22-28) with a program at the River Park Public Library on Saturday October 21. The theme for National Chemistry Week this year was chosen by the American Chemical Society to be Geochemistry. This was a good choice because we all know that "Chemistry Rocks!". At the library, our college students helped children explore the chemistry of rocks and minerals with hands-on ACS-approved experiments and demonstrations. Thanks to the club and its dedicated members for providing this opportunity to the community.


Wednesday, October 18, 2017

Students present at LSMCE conference

 
Analytical chemist Grace Muna accompanied three students to the 5th annual 2017 Louis Stokes Midwest Center of Excellence (LSMCE) Conference this October where she served as one of the judges for the student poster competition. Physics major E-Lexus Thornton (shown presenting his poster, above left) and Biology major Keon Jones (with Muna, above right) showcased their summer work under the LSAMP program at IU South Bend. Award-winning biochemistry major Michele Costantino also attended the conference to present her summer work under an REU at IUPUI. Presenting at a conference is a great way to end a project, like icing on a cake, but can also be a great way to start new beginnings by making contact with students and faculty from other institutes. Special thanks are due to these three students for representing IU South Bend and showing the Midwest states what quality students our campus has. Abstracts of the students' posters are given below.


Michele Costantino (Poster #55)
The effect of ionic solutions on surface potential of lipid membranes

Cellular membranes provide a barrier between two environments and are composed of a variety of lipid molecules. The composition of the membrane determines its function and as such can be influenced by ions and molecules in the surrounding environment. Amongst the factors affected is the electric charge and the surface potential (zeta potential) of the membrane. The mechanism by which the zeta potential of membranes is affected by water soluble ions and molecules involves, not only the net electrical charge, but also a physical property called electrical polarizability. In the lab, we use a method by which electrical polarizability is determined from measurements of index of refraction and mass density as a function of solute concentration. This research will provide understanding in how polarizability of a molecule affects a cellular membrane by observing the zeta potential of a lipid vesicle at varying concentrations of one molecule in solution. The dioleoylphosphatidylserine (DOPS) lipid was utilized, which contains two monounsaturated hydrocarbon chains with eighteen carbons each and a negatively charged head group that consists of both an amine and carboxylic acid. The results showed that while the vesicles maintained approximately a -60 mV charge in water, addition of ions altered the zeta potential in the positive direction as the concentration increased. However, this trend does not immediately appear upon adding ions, instead the charge fluctuates at lower concentrations. The trend has been observed in both divalent chlorides and adenosine triphosphate solutions. Future research will focus on other divalent chlorides—including magnesium, manganese, and cobalt—as well as organic phosphates and phospholipids with different head groups such as dilauroylphosphatidylcholine (DLPC), a neutral lipid. This research will help us to further understand how molecules and ions in the surrounding environments affect cellular membranes in regards to zeta potential, size, and formation of multilamellar vesicles (MLVs). Funding: National Science Foundation Research Experience for Undergraduates (REU) Award #1659688


Keon Jones (Poster #82)
A sensitive electrochemical method to determine lead in water and soil

Lead is one of the most toxic heavy metal in the environment. Its presence is due to human activities notably, lead in gasoline, lead-based paint, lead-containing pesticides, lead in ammunition and sinkers, and incinerator ash or water from lead pipes. Lead poisoning can cause a number of adverse human health effects but it’s particularly detrimental to the neurological development of growing children. Therefore, frequent testing and precise monitoring of Pb in soil and water is important to assess and control lead contamination. We hereby report on developing a stripping voltammetric method using glassy carbon electrodes modified with bismuth nanoparticles (GC-BiNPs) to detect lead in drinking water and soil. Voltammetric stripping measurements have historically utilized mercury in the forms of hanging mercury drop and mercury film electrode to measure heavy metal ions. This is mainly because clean surfaces can be easily be regenerated with a new mercury drop. However, because of mercury toxicity and risks associated with its disposal its use as an electrode material for stripping measurements is severely restricted. We’re utilizing the unique properties of bismuth such as its ability to form alloys with different metals, to develop a sensitive method to detect lead. Preliminary results show that using GC-BiNPs we can detect low levels of lead down to 1 parts per billion in water. The research findings on the stripping voltammetric method development will be presented. Funding: LSAMP; SMART ; IUSB


E-Lexus Thornton (Poster #119)
Modification of the microchannel plate (MCP) detectors in the recoil mass separator St. George

The Recoil Mass Separator St George in Notre Dame’s Nuclear Science Laboratory (NSL) is being used for the study of low level (α,γ) reactions using inverse kinematics to better understand the helium burning processes in a star. ST GEORGE has two MCP detectors that amplify and multiply electrons into electrical pulses that can be seen on an oscilloscope. To make the MCP detectors display a better pulse, and to make the MCP detectors conveniently easy to remove from the mass separator, we decided to modify the makeup of both MCP detectors and add two delay boards and a basic circuit board to both MCP detectors. The Autodesk Inventor software was used for the drawing process and the circuit board was designed by hand. The process and/or results of the modifications and new additions will be described. Funding: NSF Grant PHY-0959816

Friday, October 13, 2017

ChemOffice Professional Comes to IU South Bend


The software suite ChemOffice Profesional is now available to IU South Bend faculty and staff. It can be downloaded and installed on personal computers from IUware. It houses an array of software, but most interesting to students will be the components ChemDraw and Chem3D.

ChemDraw allows users to draw high-quality two-dimensional molecular structures in skeletal form. It can compute simple properties such as molecular mass and elemental composition, but also has a wide range of stored information about existing compounds such as their melting and boiling points. ChemDraw can also determine the IUPAC name of compounds (see below left - please click on photo for higher resolution) and likewise produce the structure given the name. It can even predict NMR spectra for compounds (see below right  - please click on photo for higher resolution), which will surely aid students of organic chemistry to test their ability to interpret and predict NMR spectra.
 
Chem3D allows a two-dimensional structure from ChemDraw to be visualized and manipulated in three dimensions.  Bond lengths and bond angles are predicted based on average empirical data, but better estimates of these properties and many others can be obtained from built-in molecular modelling capabilities. Chem3D even interfaces with quantum mechanical software to allow Hartree-Fock and density functional calculations. We interfaced with GAMESS to produce the image above of one of two HOMO for benzene. (Paradox = How can you have two HOMOs?)
                    

Tuesday, October 10, 2017

Nanotechnology - Size Matters!


Last week the First Year Seminar students in Dr. Anderson's CHEM-N 190 Nanotechnology: Size Matters class made solar cells from raspberry juice and titanium dioxide on a semiconductive glass surface. This is an example of Dye Sensitized Solar Cells which are at the cutting edge of thin film solar photovoltaic technology. With two-inch square panels, students cranked out a satisfying 0.3 volts per panel (see bottom left picture)!  It helped that the day happened to be mostly sunny. With this experience making solar cells, they should be well-informed for this week's field trip to Inovateus Solar.  Anderson's course is the second course offered at IU South Bend to focus on nanotechnology to support the new nanotechnology tracks offered for certain STEM majors.