According to Andrew Chen, ethical concerns about nanotechnologies should include the possibility of their military applications, the dangers posed by self-replicant nanomachines, and their use for surveillance monitoring and tracking.[1] Risks to environment to public health are treated in a report from the Dutch National Institute for Public Health and the Environment[2] as well as is a report of the European Environment Agency.[3] Academic works on ethics of nanotechnology can be found in the journal Nanoethics.
Ethical concern about nanotechnology include the opposition to their use to fabricate Lethal autonomous weapon, and the fear that they may self replicate ad infinitum in a so-called gray goo scenario, first imagined by K. Eric Drexler.[4] For the EEA [3] the challenge posed by nano-materials are due to their properties of being novel, biopersistent, readily dispersed, and bioaccumulative; by analogy, thousands cases of mesothelioma were caused by the inhalation of asbestos dust. See nanotoxicology. Nanotechnology belongs to the class of emerging technology known as GRIN: geno-, robo-, info- nano-technologies.
Another common acronym is NBIC (Nanotechnology, Biotechnology, Information Technology, and Cognitive Science). These technologies are hoped[5] - or feared,[6] depending on the viewpoint, to be leading to improving human bodies and functionalities, see transhumanism. The possible application of nanotechnology in human genome sequencing (eg. Nanopores based sequencing) raises further ethical and societal concerns.[7]
European Environment Agency, 2013, Late lessons from early warning II Chapter 22 - Nanotechnology - early lessons from early warnings.[3] See also Steffen et al., 2008.[8]
Jaco Westra (editor), 2014, Assessing health and environmental risks of nanoparticles. An overview, RIVM Rapport.[2]
Rene von Schomberg (2011), Introduction: Towards Responsible Research and Innovation in the Information and Communication Technologies and Security Technologies Fields.[9]
European Commission, 2009, Commission recommendation on A code of conduct for responsible nanosciences and nanotechnologies research & Council conclusions on Responsible nanosciences and nanotechnologies research.[12]
C. Marris, Final Report of the PABE research project, 2001.[13]
E.A.J. Bleeker, S. Evertz, R.E. Geertsma, W.J.G.M. Peijnenburg, J. Westra, S.W.P. Wijnhoven, Assessing health & environmental risks of nanoparticles Current state of affairs in policy, science and areas of application, RIVM Report.[2]
Roger Strand, 2011, Nano Ethics, In: Nanotechnology in the Agri‐Food Sector: Implications for the Future.[14]
Job Timmermans; Zhao Yinghuan; and Jeroen van den Hoven, 2011. Ethics and nanopharmacy: Value sensitive design of new drugs. Nanoethics 5(3): 269-283.[16]
Steven Umbrello and Seth D. Baum, 2018. Evaluating future nanotechnology: The net societal impacts of atomically precise manufacturing. Futures 100(June): 63-73.[17]
K. Eric Drexler, 2013. Radical abundance: How a revolution in nanotechnology will change civilization. Public Affairs: New York.[18]
^Chapter 16, Nano Ethics, In: Nanotechnology in the Agri‐Food Sector: Implications for the Future, Editors:Lynn J. Frewer, Willem Norde, Arnout Fischer, Frans Kampers, Wiley.
^There's Plenty of Room at the Bottom, a lecture given by physicist Richard Feynman at the annual American Physical Society meeting at Caltech on December 29, 1959.