Types of Jobs in Nuclear Engineering

Because nuclear science and engineering has such a broad range, graduates can be prepared for a wide variety of careers. Today's graduates enjoy research and teaching jobs at universities; they work at power plants and in government and industrial laboratories. They have launched LED lighting companies. They manage hedge funds, create interactive science and art displays, design new reactors, improve aircraft components, attend medical school, and design domestic energy policies.

Bureau of Labor statistics for 2011 show nuclear engineers earning a mean annual wage of $105,160, a bottom average wage of $67,100, and a top wage of $147,670. Rise in employment was estimated at 9.4 percent.

Some professional organizations for nuclear engineers are the American Nuclear Society, the American Physical Society, the Health Physics Society, the Institute of Nuclear Materials Management, and the International Radiation Physics Society. Membership offers opportunities to stay abreast in the field, to engage with other nuclear engineers, and to share experiences through conferences and publications.

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Discover the World of Nanoengineering

Nanoengineering encompasses the practice of the profession on a nanoscale, which stems from the nanometer unit of measure, equivalent to one billionth of a meter. Within the industry, nanoengineering is synonymous with practices of nanotechnology, whereby it focuses on the engineering component of a given technology rather than the scientific side. Nanotechnology professionals have become prized professionals in the current marketplace for their skills and training dealing with microscopic applications.

From the automobile and energy industry to healthcare and technology firms, companies around the world eagerly seek to attract and develop these professionals. Within these realms, scanning tunneling microscopy (STM) and atomic force microscopy (AFM) are the dominant techniques of the field used to solve problems and originate new technologies. Both techniques pivot on generating microscopic probes to manipulate and track the movement of atoms with the idea of capturing something significant to translate into real world applications such as revolutionary manufacturing materials or new pharmaceutical products.

To learn more about becoming a nanoengineer, contact the schools below to request more information. We recommend contacting multiple schools to compare programs.

Professionals in this field often perform a medley of duties depending on the industry they work in and/or their educational backgrounds. In biosciences, nanoengineers dedicate their time to developing new medical device products and ways to enhance existing ones. From a construction viewpoint, these experts investigate and evaluate the development of new materials to develop more sustainable and durable building products and materials. Automotive companies employ these engineers to develop more efficient processes within an engine system and materials to build and pad vehicle systems and interiors. Regardless of the field, these engineers choose to employ their skills and talents, the field requires immense patience and attention to detail. Refining the effective use of STMs and AFMs, critical to the development of new technologies and breakthroughs, often proves to be challenging for most practitioners in the field. Powerful microscopes with exceptionally fine silicon tips are employed to monitor the nano activity harnessed to develop new applications. Establishing a suitable tip, though, can sometimes take seven days alone. Nevertheless, global firms like Abbott Laboratories, Tesla, Exxon-Mobil, and Sony are a few of the global firms capitalizing on the potential of nanotechnology.

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Real Example of Molecular Engineering

As it is an emerging field with seemingly unlimited potential, the field of molecular engineering has stirred some controversy regarding its implications ethically, environmentally and socially. At the same time, the science promises to exert its influence in all spheres of human life around the world. In the medical devices industry, a recent case study of Ortho Molecular illuminated the powerful potential of this form of engineering. The firm employs a ProScan metal detection system, rooted in molecular engineering, which was developed by Advanced Detection Systems (ADS). This ensures the quality of all of the products in its manufacturing system. The device memorizes the product sensory impulse, and then recalls it as it travels through the scanner, thereby ensuring the finished product meets all Food and Drug Administration health and safety codes. The ProScan application evaluates the entire device to identify the presence of any metal. If it is detected, a signal occurs compelling a check of the entire batch of deliverables. The system enables quality control staff to quickly identify integrity breaches and remedy them seamlessly. Molecular engineering was critical in developing this acute detection system application. Ortho Molecular purchased several of the ADS systems for its medical device product manufacturing processes because of its sensitivity and efficiency.

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Mining and Geological Engineering

 

Mining and geological engineering focuses primarily on the study and design of creating safe and effective means to extract metals and minerals for industrial, commercial and scientific purposes. Requiring education and understanding not only of mining principles and practices, engineers in this field are also expected to have an advanced and dynamic understanding of geological sciences, such as soil and mineral composition, surveying, prospecting and exploratory geological research. In addition to extracting the more conventional materials such as oil, precious and industrial metals and rarer gems and materials, many new advancements in information technology have expanded the role of geological engineering to search and mine for other materials, such as the dozens of special minerals and materials used in computer, tablet and smart phone construction.

At EducatingEngineers, we want you to understand the complexities of engineering careers and what it takes to succeed in your education. Please read the information below to learn more. And contact the schools in our directory to get started!

Employed by governments, major corporations, non-profit organizations and scientific/academic research institutions, geological engineers play pivotal roles in everything from industrial production of materials and energy, to advancing scientific understanding of the material composition of the Earth. Because of the numerous and varied functions for geological engineering and the substantial technological advancements made in the field itself, the role of the engineer in respect to mining and geological research continues to evolve, finding new and interesting applications for the science with each passing year.

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Mechatronics Engineering Work Nature

Though the US Bureau of Labor Statistics (BLS) does not maintain employment or salary data on mechatronics engineers, it does have statistics for the related industries of mechanical and electrical engineer. According to research at the BLS, demand for these types of professionals should likely experience five percent growth until at least 2022. Moreover, the bureau foresees electrical and electronics engineers to experience four percent growth in their career prospects. In contrast, electrical and electronic engineering technicians will likely see little or no growth over the time period. Based on O*Net salary data, mechatronic engineers earned a median salary of $92,680. In a state comparison for earning potential, the BLS found that mechanical engineering professionals in California earned the highest salary at $112,100. Professionals in Texas received $98,030 in yearly salary compensation. Engineers in New York and Illinois earned approximately $95,020 in pay annually.

Companies like Harris & Bruno have formed partnerships with schools like Sierra College in California to seamlessly integrate students from the classroom to applying their knowledge to real world mechatronics applications. Markus Fredrickson, a Sierra College student, works part-time in manufacturing at Harris & Bruno. When he first began his education, he did not have a clear direction for his career. However, the collaborative approach of his university and the private enterprise has provided him with direction and the practical outlet for his skills. He described his work with the firm as a seamless experience bridging his classroom education with real world scenarios. Many of the parts and systems he encountered in his classroom work echoed the very same components and problems he was asked to solve on the job. Ultimately, he found his theoretical and practical education as invaluable in facilitating his career advancement. These types of programs reflect the potential for students and companies as they integrate their resources and expertise in growing the industry. This boasts well for both current and prospective professionals in the field and the industry as a whole as more evolutions occur in terms of technology and human resources.
If you would like to learn more about mechatronics or other areas of engineering, contact the schools in our directory to receive more helpful information. We recommend contacting multiple schools to be sure you choose the best one for you!

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Mechanical Engineering Degrees

Mechanical engineering is the broadest of the engineering disciplines. This field focuses on two major topics: thermal systems and mechanical systems.

As a result, the mechanical engineering curriculum overlaps many other engineering fields, including aerospace, biomedical, chemical, civil, electrical, industrial, materials and metallurgical and petroleum.

Any prospective engineering student should have a strong high school background in elementary, intermediate and advanced algebra, trigonometry, geometry, pre-calculus, chemistry and physics.

Additionally, the pre-engineering student should have solid reading comprehension skills and the ability to write logically, clearly, concisely and with correct grammar.

The core curriculum of mechanical engineering at any engineering school accredited by the Accreditation Board of Engineering and Technology (ABET) consists of.

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Real Life Stories of Materials Science Engineering

 

Real Life Stories of Engineers

Beyond these statistical realities and potential however, many within the fields of Materials Science and Engineering express substantial personal and professional satisfaction with their work and career. Bringing together the applicable skills of dynamic critical thinking and problems solving with those of analytical research and scientific endeavor, the challenges posed to the working professional often result in an enhanced satisfaction with successful end results in respect to projects and ventures undertaken. In seeing the final real world applications to their research, development and testing of new and existing materials, Material Engineers often find themselves on the cutting edge of scientific discovery and advancement.

Taking for example, the case of NASA engineer Clara Wright, the pliable skills learned while studying Material Science and Engineering have given Ms. Wright substantial personal fulfillment, in addition to her remarkable career. Being possessed since her youth with an interest in puzzles and problem solving, Wright gravitated naturally towards the field of material science and engineering. Upon completing her degree, Wright first entered the field of bio-medical research, assisting with the design and development of prosthetic limbs for amputees. Later, Wright took a position at NASA working as a materials engineer, studying materials in use by the space program. In July of 2014, Wright was profiled for NASA’s website, in an effort to highlight both her contributions to the space program, while also the interest and dedication to Material Science and Engineering which brought her to work there.

"I'm very passionate about being a materials engineer," Wright said. "It’s a very fulfilling career particularly at Kennedy because every investigation is unique. It is greatly gratifying to say that I am one of a handful of people in the world who get to work on hardware that is going to the International Space Station, has been in the vacuum of space or is part of the launch structures."    

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