In the early 2000s, Nakamura had a falling out with his employer and, it seemed, all of Japan. Relying on a clause in Japan's patent law, article 35, that assigns patents to individual inventors, he took the unprecedented step of suing his former employer for a share of the profits his invention was generating. He eventually agreed to a court-mediated $8 million settlement, moved to the University of California, Santa Barbara (UCSB) and became an American citizen. During this period he bitterly complained about Japan's treatment of inventors, the country's educational system and its legal procedures.
..."Before my lawsuit, [Nakamura said] the typical compensation fee [to inventors for assigning patents rights] was a special bonus of about $10,000. But after my litigation, all companies changed [their approach]. The best companies pay a few percent of the royalties or licensing fee [to the inventors]. One big pharmaceutical company pays $10 million or $20 million. The problem is now the Japanese government wants to eliminate patent law article 35 and give all patent rights to the company. If the Japanese government changes the patent law it means basically there would no compensation [for inventors]. In that case I recommend that Japanese employees go abroad."
There is a similar problem with copyright law in the U.S., where changes in the law in the 1970s and 1990s has made it almost impossible for copyrights to ever expire. The changes favor the corporations rather than the individual who might actually create the work.
So what's the deal? I'm not up for searching the various
The defining feature of a technological civilization is the capacity to intensively “harvest” energy. But the basic physics of energy, heat and work known as thermodynamics tell us that waste, or what we physicists call entropy, must be generated and dumped back into the environment in the process. Human civilization currently harvests around 100 billion megawatt hours of energy each year and dumps 36 billion tons of carbon dioxide into the planetary system, which is why the atmosphere is holding more heat and the oceans are acidifying.
All forms of intensive energy-harvesting will have feedbacks, even if some are more powerful than others. A study by scientists at the Max Planck Institute in Jena, Germany, found that extracting energy from wind power on a huge scale can cause its own global climate consequences. When it comes to building world-girdling civilizations, there are no planetary free lunches.
By studying these nearby planets, we’ve discovered general rules for both climate and climate change (PDF). These rules, based in physics and chemistry, must apply to any species, anywhere, taking up energy-harvesting and civilization-building in a big way. For example, any species climbing up the technological ladder by harvesting energy through combustion must alter the chemical makeup of its atmosphere to some degree. Combustion always produces chemical byproducts, and those byproducts can’t just disappear.
As we describe in a recent paper, using what’s already known about planets and life, it is now possible to create a broad program for modeling co-evolving “trajectories” for technological species and their planets. Depending on initial conditions and choices made by the species (such as the mode of energy harvesting), some trajectories will lead to an unrecoverable sustainability crisis and eventual population collapse. Others, however, may lead to long-lived, sustainable civilizations.
"More software projects have gone awry for lack of calendar time than for all other causes combined." -- Fred Brooks, Jr., _The Mythical Man Month_