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                     like an RFID system.

                   After September 11, 2001, the new Department of Homeland Security (DHS) activated Oak
               Ridge  National  Laboratory’s  SensorNet  program  to  begin  integrating  nano-  and  microsensors
               into real-time detection and surveillance.

                     It is [in transportation and commerce] that the full scope of surveillance integration can be seen as a management
                     strategy that merges legislation, federal inspection systems, international standards, security threat assessments, and
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                     the latest in nanotechnology.

                   At the close of 2003, Public Law 108-153, the “21st Century Nanotechnology Research and
               Development Act,” quietly made its way through Congress. “The President shall implement a
               National Nanotechnology Program. . .The activities of the Program shall include (1) developing
               a fundamental understanding of matter that enables control and manipulation at the nanoscale . .
               .” Congress was assured that nanotechnology was the “science of the future.”
                   In  2005,  the  Woodrow  Wilson  International  Center  for  Scholars  announced  the
               moneymaking “Internet of Things” (IoT) angle in its Project on Emerging Nanotechnologies:

                     To document the marketing and distribution of nano-enabled products into the commercial marketplace, the Woodrow
                     Wilson International Center for Scholars and the Project on Emerging Nanotechnologies created the Nanotechnology
                     Consumer Products Inventory (CPI) in 2005. . .The revised inventory was released in October 2013. It currently lists
                     1,814 consumer products from 622 companies in 32 countries. The Health and Fitness category contains the most
                     products (762, or 42% of the total). Silver is the most frequently used nanomaterial (435 products, or 24%); however,
                     49% of the products (889) included in the CPI do not provide the composition of the nanomaterial used in them.
                     About  29%  of  the  CPI  (528  products)  contain  nanomaterials  suspended  in  a  variety  of  liquid  media  and  dermal
                     contact is the most likely exposure scenario from their use. The majority (1,288 products, or 71%) of the products do
                     not present enough supporting information to corroborate the claim that nanomaterials are used . . . 15


                   Nano research boomed at Lawrence Berkeley National Laboratory (LBNL), the Department
               of  Energy  research  facility  run  by  University  of  California  Berkeley.  Once  the  National
               Nanotechnology  Program  was  in  place,  all  caution  was  consigned  to  the  outer  darkness  of
               “national  security.”  In  2007,  when  the  City  of  Berkeley  requested  that  the  LBNL  (and  UC
               Berkeley)  comply  with  a  city  ordinance  requiring  corporations  working  with  engineered
               nanoparticles to submit a toxicology report and “how the facility will safely handle, monitor,
               contain,  dispose,  track  inventory,  prevent  releases  and  mitigate  such  materials,”  neither
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               institution complied.  A month later, UC Regents approved major expansion of LBNL, virtually
               ignoring  city  and  community  outcries  about  toxic  compounds  in  the  soil  and  groundwater,
               including polynuclear aromatic hydrocarbons, hazardous metals, tritium, etc. 17
                   For the most part, critical warnings and second thoughts about nanotechnology withered on
               the  vine  of  scientific  journals,  though  the  Journal  of  Nanoparticle  Research  did  manage  to
               publish “Nanotechnology and the need for risk governance” about the “governance gap” between
               nano-  and  microtechnologies.  (1  nanometer  nm  =  0.001  micron  μm,  a  quantum  world  of
               difference.) From the Abstract:


                     . . .The novel attributes of nanotechnology demand different routes for risk-benefit assessment and risk management,
                     and at present, nanotechnology innovation proceeds ahead of the policy and regulatory environment. In the shorter
                     term, the governance gap is significant for those passive nanostructures that are currently in production and have high
                     exposure rates; and is especially significant for the several ‘active’ nanoscale structures and nanosystems that we can
                     expect to be on the market in the near future. Active nanoscale structures and nanosystems have the potential to affect
                     not only human health and the environment but also aspects of social lifestyle, human identity and cultural values . .