In the late 1980s, when setting up his first laboratory, an asst. prof. of chemistry at the Univ. of South Carolina had a conversation with a scientist at IBM Yorktown, Avi Aviram, who had recently authored a paper speculating on a new type of perpendicularly shaped molecule that, if artificially created and equipped with active sensing points, could be used as a molecular switch for computing.
The first LCD television was invented in 1972 at Westinghouse in Pennsylvania. Like many...
In early March, in a rural Mississippi hospital, an infant was born to an HIV-infected mother....
Fume hoods are a central component in most laboratories. Whether designing a new laboratory or...
As part of its R&D 100 Awards program, the editors of R&D Magazine hold an annual roundtable discussion that addresses outstanding trends and issues in research and development. This year, the Industry Executives’ Roundtable, held Nov. 7, 2013, in Orlando, Fla., focused on industrial research, featuring executives from several organizations that invest heavily in R&D efforts. These organizations all won 2013 R&D 100 Awards.
In January 2013, an assoc. prof of biomedical engineering at Columbia Univ., Samuel K. Sia, developed a lab-on-a-chip technology that not only checks a patient’s HIV status with a finger prick, it also synchronizes the results automatically and instantaneously with central health care records. The technology, developed in collaboration with OPKO Diagnostics and called mChip, performs all ELISA functions, and produces results within 15 min.
Virtually every laboratory has areas with elevated fire risks, with fume hoods being a primary concern. The presence of ignition sources, such as hot plates and Bunsen burners, the use of pyrophoric materials and the inherent volatility of the various chemicals and compounds that are commonly found in fume hoods all add up to a serious fire risk.
During the development of the transistor, which launched the computer age, oscilloscopes were a key tool for engineers and scientists who needed to understand the behavior of complex electronics. Now, computers are returning the favor by revolutionizing how test and measurement instrumentation, including oscilloscopes, is constructed and how it performs.
Multiphysics software simulations are used by biomedical equipment developers to reliably design complex mechanisms for enhancing the human physical condition. These medical devices can include tools for treating cancers, enhancing hearing and treating chronic back pain.
Many applications involve generating sinusoid voltage waveforms onto low-AC-impedance capacitive loads. For example, this capability is needed when emulating automotive alternator whine for testing a car stereo system’s ability to reject noise. Such applications may require generating waveforms up to 20 kHz with peak-to-peak amplitudes of 500 mV onto a capacitive load as high as 1 mF to 1 F.
Innovation is improbable without proper funding, which is why R&D Magazine and Battelle Memorial Institute annually project how political developments and economic conditions around the globe will affect R&D support in the coming year. Now available, the 2014 R&D Magazine/Battelle Global R&D Funding Forecast offers a comprehensive analysis of the state of industrial research worldwide.
“Somewhere, something incredible is waiting to be known,” said astronomer Carl Sagan, who succinctly captured the essence of what it means to be a researcher. That wide-eyed sense that anything is possible through research and development, that’s the essence of a researcher’s calling.
Growth in global research and development funding slowed in 2013 from the pace of growth seen in 2011-2012. The 2013 slowdown was due primarily to unsettled European and U.S. economies that, in turn, affected global performance. R&D investments often are closely linked to GDP and economic outlook.
In the United States, R&D spending is likely to increase in 2014, turning the corner from near-zero growth in 2013. Federal funding is difficult to forecast because of the breakdown of orderly budget processes, but there are indications of bipartisan political support for increases or reallocations that favor R&D.
Federal R&D policy and implications of budget sequestration are the largest factors in funding for U.S. academic research, which has dropped from a recent high of 6% annual funding increases in 2011 to a forecast of 2% in 2014. Long recognized as an essential scientific foundation of U.S. innovation, academic research programs have been under pressure as a result.
For the past six years, the top ten countries funding R&D have remained mostly the same. There has been dramatic change, however, in the extent of globalization involved in research, as well as shifts in the way funds are spent. Driven in part by China’s aggressive programs, Southeast Asia has become the world’s largest region for research investments.
China has increased its R&D investments by 12% to 20% annually for each of the past 20 years; while at the same time, U.S. R&D spending increased at less than half those rates. As a result, China’s investment is now about 61% that of the U.S., and continuing to close.
With the large number of European Union member states, Europe’s research community is diverse in its economic composition and national interests, while central funding and administrative mechanisms allow coordinated operation of public research at a scale that is comparable to that of the United States.
As a group, the “Rest of the World” (ROW) countries—those other than the U.S., those in Europe and China—are expected to see moderate growth in their R&D investments in 2014, with leadership from countries like South Korea, Russia and Taiwan. Most Asian countries are projected to experience significant economic growth in 2014.