Charles E Milliken

Title: Innovations of Charles E Milliken

Introduction

Charles E Milliken is an accomplished inventor based in Evans, GA (US). He holds a total of 2 patents that showcase his contributions to the field of electrochemical detection and monitoring. His work has significant implications for microbial stress detection and the assessment of biofilms and corrosion.

Latest Patents

One of Milliken's latest patents is titled "Electrochemical detection of microbial stress." This invention outlines a method for detecting microbial stress through an electrochemical device that includes a reference electrode and a working electrode. The process involves providing a source of electrical energy, detecting electron transfer from the working electrode to the fermenting microbe, and taking remedial action based on the indication of microbial stress.

Another notable patent is "Non-contact monitoring of biofilms and corrosion on submerged surfaces with electrochemical impedance spectroscopy." This patent describes systems and methods for monitoring microorganisms on surfaces without direct contact. A patterned sensing electrode is used in conjunction with an aqueous medium to measure changes in an alternating current signal, which can indicate the presence of microorganisms and their associated characteristics.

Career Highlights

Throughout his career, Charles E Milliken has worked with prominent organizations such as Savannah River Nuclear Solutions, LLC and Battelle Savannah River Alliance, LLC. His experience in these companies has contributed to his expertise in electrochemical applications and microbial monitoring.

Collaborations

Milliken has collaborated with notable colleagues, including Charles E Turick and Scott D Greenway. These partnerships have likely enhanced his research and development efforts in the field.

Conclusion

Charles E Milliken's innovative patents and career achievements reflect his significant contributions to the field of electrochemical detection and monitoring. His work continues to influence advancements in understanding microbial stress and surface monitoring.