Abstract 
There will be a discussion of two different examples of liberation technology, one used to collect and protect human rights data, and the other used to analyze it. Martus is a software program that encrypts and remotely backs up data, designed for and used widely by human rights monitors and advocates to protect witness reports and other sensitive human rights data. the focus will be on the security design of Martus and how we addressed the inevitable tradeoffs with usability, as well as the reasons for and consequences of our choice to make Martus free and open source. The legitimacy of human rights advocates is based on their claim to speak truth about a human rights situation, but our ability to know the truth of what is happening on the ground is often severely limited. Founding conclusions on anecdotes or observable events alone can misinterpret both trends over time and the relative distribution of violence with respect to regions, ethnicity or perpetrators. Through the careful application of rigorous statistical methods, the limitations of incomplete data can sometimes be overcome, enabling scientifically-based claims about the total extent and patterns of human rights violations. Also discussed will be how this kind of analysis is enabled by technology, including computational statistical methods, and tools like R and version control to make the analysis auditable and replicable.

Jeff Klingner is a computer scientist with the Human Rights Data Analysis Group at Benetech, where he codes and runs data analysis addressing a variety of human rights questions, including command responsibility of high-level officials in Chad and Guatemala, and mortality estimation in several countries, including India, Sierra Leone, and Guatemala. His technical focus is on data deduplication, machine learning, data visualization, and analysis auditability and replicability. He earned a Ph.D. in Computer Science from Stanford University.

A police “encounter killing,” or simply “encounter,” is a term with no legal validity but which has seeped via the media into Indian English so surely that it has acquired a life of its own. It refers to a face-to-face interaction between the police and suspects leading to the killing of the suspects. While intended to convey serendipity, encounter killings in reality are often pre-planned executions by police or security agencies. First used against Maoists in the 1970s, and counterinsurgents in the Northeast and Kashmir, executions as unstated state policy were perfected in dealing with Sikh militant groups in the 80s and 90s. The ‘Punjab solution’, as it came to be known, became the model for the internal security establishment. Mumbai’s underworld was reined in through a series of high profile encounter killings—much celebrated in the popular media for imposing order into the urban anarchy that the gang-wars were breeding. Indeed, this became the preferred quick-fix method of dealing with a range of ‘undesirables’, from petty criminals to gangsters, to alleged terrorists and separatists. But more often than not, those lumped together as ‘encounterables’ were simultaneously marked out through their caste, ethnic and religious affiliations. The talk will discuss the history of fake encounters in India and the role of the media and judiciary in dealing with them.

Manisha Sethi is Assistant Professor at the Centre for the Study of Comparative Religions and Civilizations, Jamia Millia Islamia, New Delhi. Her research interests are in the area of gender and religion, communalism, and law and terrorism. She has published extensively on these themes in academic as well as popular publications. She is currently Associate Editor, Biblio: A Review of Books, India’s premier book review journal, with which she has been associated for over a decade. Sethi is the President of the Jamia Teachers' Solidarity Association, which has been closely involved in a campaign against extra judicial killings. Her book, Escaping the World: Chastity, Power and Women’s Renunciation among Jains, Routledge India, is due later this year.

This event is co-sponsored with the Stanford Center for South Asia and

The Indian American Muslim Council

The events of this year alone have highlighted the impact that natural phenomena (so called external events) can have on critical infrastructure and commercial nuclear power plants in particular. The design of commercial nuclear power plant structures, systems and components has taken into account the effect of loads due to external events such as earthquakes, floods, high winds and tornados. However, the original approach for establishing design levels was based on deterministic methods that today would be viewed as short-sighted and scientifically inadequate. This talk will offer perspectives and insights on NPP design and performance, evaluation of so-called extreme events, and how evaluations of potential core damage accidents are performed. The approach and process of evaluating plant integrity and safety continues to evolve; in part this is attributable to a degree to the vigilance that is maintained by the industry, but is also due to ‘current events’ that demand attention (new science, Fukashima experience, Fort Calhoun flood experience, Virginia earthquake, etc.).

About the speaker: Dr. McCann is currently the President of Jack R. Benjamin & Associates, Inc., a Consulting professor of Civil and Environmental Engineering at Stanford University and Director of the National Performance of Dams Program (NPDP). He received his B.S. in civil engineering from Villanova University in 1975, an M.S. in civil engineering in 1976 from Stanford University and his Ph.D. in 1980, also from Stanford University.

His areas of expertise and professional experience includes probabilistic risk analysis for civil infrastructure facilities and, probabilistic hazards analysis, including seismic and hydrologic events, reliability assessment, risk-based decision analysis, systems analysis, and seismic engineering. He currently teaches a class on critical infrastructure management in the civil and environmental engineering department.

He has been involved in probabilistic risk studies for nuclear power plants since the early 1980’s and is now participating in a new round of risk studies for plants in the U.S. Recently, Dr. McCann led the Delta Risk Management Strategy project that is conducting a risk analysis for over 1100 miles of levee in the Sacramento and San Joaquin Delta. He was also a member of the U.S. Army Corps of Engineers’ IPETRisk and Reliability team evaluating the risk associated with the New Orleans levee protection system following Hurricane Katrina.

He is currently serving on 2 National Academy of Sciences panels addressing issues associated with levees and community resilience and the National Flood Insurance Program.

Russia has had a long history of opposing US missile defense activities. Most recently, Russian concern focused on the alleged capability of the "third site" to intercept Russian ICBMs. The "third site" was a plan to place 10 ground-based interceptors in Poland and a large X-band radar in the Czech Republic proposed by the Bush Administration prior to its cancellation in 2009 by the Obama Administration. Now this same Russian concern has arisen regarding phases III and IV of the Phased Adaptive Approach to European missile defense proposed by the Obama Administration. This talk will assess the extent to which Russian concerns are valid in military/technical terms.

Speaker Biography:

Dean Wilkening is a Senior Research Scientist at the Center for International Security and Cooperation at Stanford University. He holds a Ph.D. in physics from Harvard University and worked at the RAND Corporation prior to coming to Stanford. His major research interests include nuclear strategy and policy, arms control, the proliferation of nuclear and biological weapons, bioterrorism, ballistic missile defense, and energy and security. His most recent research focuses on the broad strategic and political implications of ballistic missile defense deployments in Northeast Asia, South Asia and Europe. Prior work focused on the technical feasibility of boost-phase ballistic missile defense interceptors. His recent work on bioterrorism focuses on understanding the scientific and technical uncertainties associated with predicting the outcome of hypothetical airborne biological attacks and the human effects of inhalation anthrax, with the aim of devising more effective civil defenses. He has participated in, and briefed, several US National Academy of Science committees on biological terrorism and consults for several US national laboratories and government agencies.

Antibiotics have represented the primary line of defense for treating bacterial infections since 1935 when the first sulfur-containing compounds were introduced. Many antibiotic compounds are produced naturally by microorganisms while some more recently developed antibiotics are chemically designed based on a knowledge of susceptible biochemical pathways or physiological processes in pathogenic bacteria. Ciprofloxacin (“cipro”), a synthetic broad-spectrum antibiotic, functions by interfering with DNA replication.

Increased use and mis-use of antibiotics has led to increased numbers of pathogenic bacteria that are resistant to one or more antibiotics. Some resistant microbes possess mechanisms that allow continued growth in the presence of multiple antibiotics. These multiply drug-resistant pathogenic bacteria may also possess pathogenic properties that result in significantly more severe disease than their drug-sensitive cousins. Medical misuse of antibiotics – prescribing antibiotics for viral infections, failure of patients to complete treatment with the full regiment of antibiotics, or application of antibiotics based on inaccurate or incomplete tests can lead to selection of antibiotic resistant bacteria that can then cause infections that cannot be treated with the antibiotic(s) to which they are resistant. Multiple drug resistance can quickly reduce or eliminate all antibiotic-based treatment options. Infections caused by antibiotic resistant bacteria are very difficult to treat and can sometimes lead to death of the patient.

Antibiotic resistance can also result from selection based on exposure to antibiotics present in the environment. More than 70% of the antibiotics sold in the U.S. are used as supplements to animal feed. The intestinal bacteria in the animals provided with such feed often show resistance to the antibiotics in the feed and, in some documented cases, have transferred this resistance to pathogenic microbes with which they share the environment.

A brief of history of antibiotic use and the medical and public policy factors that are, in part, responsible for increased antibiotic resistance in pathogenic microbes and for a decrease in the development of new antibiotics will be presented. An introduction to new directions that are being taken to develop a next generation of antibiotic compounds will also be provided.

Speaker Biography:

Paul Jackson received his Bachelor's of Science degree from the University of Washington in Cellular Biology and his Ph.D. from the University of Utah in Molecular Biology. He became a CISAC Visiting Scholar in September 2011. He was previously a CISAC affiliate.

For the past 18 years he has been studying bacterial pathogens, first working to develop DNA-based methods of detecting these microbes and their remnants in environmental and laboratory samples, then developing methods to differentiate among different strains of the same pathogenic species. Research interests include the study of different methods of interrogating biological samples for detection and characterization of content, and development of bioforensic tools that provide detailed information about biothreat isolates including full interrogation of samples for strain content and other genetic traits.

Methods he developed have been applied to forensic analysis of samples and aid in identifying the source of disease outbreaks. He contributed to analysis of the Bacillus anthracis present in the 2001 Amerithrax letters and conducted detailed analyses of human tissue samples preserved from the 1979 Sverdlovsk anthrax outbreak, providing evidence that was inconsistent with Soviet government claims of a natural anthrax outbreak.

His current work continues to focus on development of assays that rapidly detect specific signatures including antibiotic resistance in threat agents and other pathogens. More recent activities include identification and characterization of new antimicrobial compounds that are based on the pathogens' own genes and the products they encode. These include development of such materials as therapeutic antimicrobials, their application to remediate high value contaminated sites and materials, and their use to destroy large cultures and preparations of different bacterial threat agents. Efforts to address issues of antibiotic resistance and treatment of resistant organisms have recently been expanded to look at non-threat agent pathogens that cause problematic nosocomial or community-acquired infections of particular interest to the military.

Paul spent 24 years as a Technical Staff Member at Los Alamos National Laboratory where he was heavily involved in development of the biological threat reduction efforts there. He was appointed a Laboratory Fellow at Los Alamos in recognition of his efforts. He moved to Lawrence Livermore National Laboratory in 2005 where he is presently Senior Scientist in the Global Security and Physical and Life Sciences Directorates. In addition to his work at the National Laboratories, he has served on the FBI's Scientific Working Group for Microbial Forensics, on NIH study sections and review panels, and continues to serve on steering and oversight committees for other federal agencies.

Much study has been put into the concept of a multinational or international “nuclear fuel bank,” and in 2010 two such banks became a reality according to the Nuclear Threat Initiative. However, all of the conceptual studies along with the two IAEA-approved banks are not really “fuel” banks; rather they are low-enriched uranium (LEU) reserves. While uranium is a commodity, fuel for a nuclear reactor is a highly-engineered product of which uranium is a component.

It has been argued that because there are more fuel fabricators than enrichers, the enrichment step is the crux of a supply assurance mechanism. This is a gross oversimplification. If one cannot get from LEU to a fabricated fuel assembly, then the fuel supply assurance is not available. There are issues of fuel design, core physics, regulation, intellectual property, and liabilities that could preclude fuel fabrication and delivery in a timely manner. These issues and obstacles will be discussed along with some suggestions about how they might be overcome to provide real fuel assurances.

Speaker Biography:

Dr. Alan Hanson was appointed as Executive Vice President, Technologies and Used Fuel Management of AREVA NC Inc. in 2005. In this position he was responsible for all of AREVA’s activities in the backend of the nuclear fuel cycle in the U.S. Prior to that he served as President and CEO of Transnuclear, Inc., also an AREVA company, which he joined in 1985. Transnuclear designs, licenses and supplies dry storage casks; more than half of the casks in the U.S. have been supplied by Transnuclear.

In January of 2011, Dr. Hanson started a year-long assignment as a Visiting Scholar at the Center for International Security and Cooperation (CISAC) at Stanford University on loan from AREVA. At CISAC he conducts research on the worldwide nuclear supply chain and international fuel assurance mechanisms. 

Dr. Hanson began his career in 1975 with the Nuclear Services Division of Yankee Atomic Electric Company. In 1979, he joined the International Atomic Energy Agency (IAEA) in Vienna, Austria. At the IAEA, he served first as Coordinator of the International Spent Fuel Management Program and later as Policy Analyst with responsibilities in the areas of safeguards and non-proliferation policies.

Alan Hanson received a B.S. degree in mechanical engineering from Stanford University in 1969 and earned his Ph.D. in nuclear engineering from Massachusetts Institute of Technology (MIT) in 1977. He also is a recipient of a Master of Arts in Liberal Studies (MALS) degree from Georgetown University in 2009.  He is a member of the American Nuclear Society and the American Society of Mechanical Engineers.