A Degree PATHe As Unique As You Are

Every student wants to hear "graduate earlier" and "save money".

Two of the greatest challenges adult students face are time and money. To help reduce these barriers Champlain has developed PATHe (Personalized Access To Higher education). 

PATHe allows students to earn up to 90 credits toward a bachelor's degree through prior college learning and life experience; leaving potentially only ten upper-level courses (30 credits) to complete and earn their bachelor's degree.

For student John Clingerman of D4 eDiscovery, the new PATHe program is already paying off. "With PATHe, I'll graduate six months earlier - which will also save me thousands of dollars. My job often requires I put in long hours, gathering and interpreting digital forensic evidence for lawyers, so Champlain's online courses have been a godsend, allowing me to study whenever I have some quiet moments available"

To learn more about how PATHe can help you save time and money visit us at online.champlain.edu/pathe.

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Mercury in fluorescent bulbs has unique isotope fingerprint

(Phys.org)—Many consumers have started replacing traditional incandescent light bulbs with compact fluorescent light bulbs (CFLs) to reduce utility bills. CFLs are made of glass tubes filled with gas and a small amount of mercury. 

In an online article posted on Chemical & Engineering News Feb. 22, writer Catherine M. Cooney reviews research recently published in the journal Environmental Science and Technology and highlights the importance of tracking mercury's movement in the environment.

As more people start using the newer lighting source, increasing numbers of fluorescent bulbs end up in landfills, where the toxic metal contained in the bulbs could leach into groundwater.

Research by Chris Mead, a graduate student in ASU's School of Earth and Space Exploration, published in the Feb. 4 issue of the journal Environmental Science and Technology, suggests that researchers could track the mercury from fluorescent bulbs by looking for its unique isotopic signature. This distinct isotope signal could help researchers track the toxic metal's movement in the environment.

As part of his graduate work, Mead developed an improved method for analyzing mercury isotopes.

"We were all very surprised by just how unusual the isotope fractionation – or signal – was in the CFLs. The mystery of how that fractionation could occur turned out to be very interesting to solve," says Mead. The research was conducted in the lab of Ariel Anbar, Mead's advisor and a professor in ASU's Department of Chemistry and Biochemistry and the School of Earth and Space Exploration in the College of Liberal Arts and Sciences.

More information: cen.acs.org/articles/91/web/2013/02/Mercury-Fluorescent-Bulbs-Unique-Isotope.html

Journal reference: Environmental Science and Technology

Provided by Arizona State University

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