It has always been important for authors and researchers to maintain and present accurate records of their work and experience. In this digital age, an author can achieve such record-keeping by using a persistent digital identifier, a number associated with a particular author that remains with him or her, regardless of changes in discipline, research project, organization, or position. ORCID, a not-for-profit-organization working to make it easier to connect research results to authors, has stepped in to provide just such a service. To date, they have registered over 2.5 million ORCID iDs for their users, and this number grows daily.
In April 2012, The Economist ran a biting editorial arguing that, “[w]hen research is funded by the taxpayer or by charities, the results should be available to all without charge.” Academic journals, the magazine contended, were raking in huge profits by selling content that was supplied to them largely for free and in the process restricting public access to valuable research to just those willing to pay for subscriptions. The answer to this “absurd and unjust” situation, The Economist wrote, is “simple”: governments and foundations that fund research “should require that the results be made available free to the public.”
We at the Department of Energy (DOE) Office of Scientific and Technical Information (OSTI) have found that providing full public access to the research DOE funds is simple in principle and complex in practice. And reflecting on this 2012 editorial, we can say that a great deal of progress has been made toward reaching the goal of free public access it sets out. And much of that progress is due to hard collaborative work by both the government and publishers.
Image credit: DOE Office of Energy Efficiency
and Renewable Energy, Photo by Dante Fratta
In the 1800s, the Brady Hot Springs geothermal fields were known as the “Springs of False Hope.” As pioneer wagon trains traveled across the northern Nevada desert on their way to California, their thirsty animals rushed to the springs only to find scalding 180° water and bare land. Additionally, the water was loaded with sodium chloride and boric acid.
Observatory (LIGO) in Livingston, LA.
Image credit: LIGO Laboratory
Interferometers are investigative tools used in many fields in science and engineering. They work by merging two or more sources of light or other waves to create an interference pattern, which can be precisely measured and analyzed. Interferometers are making possible significant advances in scientific research. One of these advances is in astronomy, where laser interferometers are opening a new era in the exploration of the universe.
In 1972, a young Massachusetts Institute of Technology physics professor, Rainer Weiss, drew up a teaching exercise using a basic concept for an interferometer to detect gravitational waves. This work later became the blueprint for the Laser Interferometer Gravitational-Wave Observatory (LIGO), a national facility for gravitational wave research. LIGO is funded by the National Science Foundation and other public and private institutions.
Image credit: Mathematics and
Statistics at ScholarWorks @UMass
Amherst (Open Access)
In 1834, naval engineer John Scott Russell was riding his horse along the Union Canal in the Scottish countryside when he made a mathematical discovery. As he subsequently described it in his “Report on Waves,” presented at a meeting of the British Association for the Advancement of Science in 1844, Russell noticed a boat had stopped abruptly in the canal leaving the water in a state of violent agitation. A large solitary wave emerged from the front of the boat and rolled forward at about eight miles per hour without changing its shape or speed. He continued on his horse to follow the wave down the canal for nearly two miles until the wave became lost in the winding channel. Russell called this beautiful phenomenon the “wave of translation,” and it has become known as a solitary wave, or soliton.