Nanotechnology and preventive arms control

"Nanotechnology (NT) is about analysis and engineering of structures with size between 0.1 and 100 nanometres (1 nm = 10 -9 m). At this scale, new effects occur and the boundaries between physics, chemistry and biology vanish. NT is predicted to lead to stronger but lighter materials, markedly smaller computers with immensely increased power, large and small autonomous robots, tools for manipulation of single molecules, targeted intervention within cells, connections between electronics and neurones, and more. In recent years military research and development (R&D) of NT has been expanded markedly, with the USA far in the lead. US work spans the full range from electronics via materials to biology. While much of this is still at the fundamental level, efforts are being made to bring applications to the armed forces soon. One quarter to one third of the Federal funding for NT goes to military R&D, and the USA outspends the rest of the world by a factor 4 to 10. NT applications will likely pervade all areas of the military. Very small electronics and computers will be used everywhere, e.g. in glasses, uniforms, munitions. Large-scale battle-management and strategy-planning systems will apply human-like reasoning at increasing levels of autonomy, integrating sensors, communication devices and displays into an ubiquitous network. Stronger but light-weight materials, more efficient energy storage and propulsion will allow faster and more agile vehicles in all media. NT-based materials and explosives can bring faster and more precise projectiles. Small arms, munitions and anti-personnel missiles without any metal can become possible. Systems worn by soldiers could monitor the body status and react to injury. Systems implanted into the body could monitor the biochemistry and release drugs, or make contacts to nerves and the brain to reduce the reaction time, later possibly to communicate complex information. Autonomous land vehicles, ships and aircraft would become possible mainly through strongly increased computing power. By using NT to miniaturise sensors, actuators and propulsion, autonomous systems (robots) could also become very small, principally down to below a millimetre - fully artificial or hybrid on the basis of e.g. insects or rats. Satellites and their launchers could become small and cheap, to be used in swarms for earth surveillance, or for anti-satellite attack. Whereas no marked change is expected concerning nuclear weapons, NT may lead to various new types of chemical and biological weapons that target specific organs or act selectively on a certain genetic or protein pattern. On the other hand, NT will allow cheap sensors for chemical or biological warfare agents as well as materials for decontamination. Most of these applications are ten or more years away. Using criteria of preventive arms control, potential military NT applications are evaluated. New conventional, chemical and biological weapons would jeopardise existing arms-control treaties. Armed autonomous systems would endanger the law of warfare. Military stability could decrease with small distributed battlefield sensors and in particular with armed autonomous systems. Arms racing and proliferation have to be feared with all applications. Strong dangers to humans would ensue from armed mini-/ micro-robots and new chemical/ biological weapons used by terrorists. Negative effects on human integrity and human rights could follow indirectly if body manipulation were applied in the military before a thorough societal debate on benefits, risks and regulation." (excerpt)"Die Nanotechnologie (NT) befasst sich mit der Untersuchung und Gestaltung von Strukturen, die sich in Größen zwischen 0,1 and 100 Nanometer (1 nm = 10 -9 m) bewegen. Bei dieser Größenordnung treten neue Effekte auf, und die Grenzen zwischen Physik, Chemie und Biologie verschwinden. Die Experten sagen voraus, dass NT festere und gleichzeitig leichtere Materialien, erheblich kleinere Computer mit unermesslich gesteigerter Leistung, große und kleine autonome Roboter, Werkzeuge für die Handhabung einzelner Moleküle, gezielte Eingriffe in Zellen, Verbindungen zwischen Elektronik und Neuronen und anderes mehr hervorbringen wird. In den letzten Jahren ist die militärische Forschung und Entwicklung (FuE) im Bereich der NT erheblich ausgeweitet worden. Im weltweiten Vergleich liegen die USA deutlich in Führung. Dort wird die gesamte Bandbreite von Elektronik über Materialien bis hin zur Biologie bearbeitet. Auch wenn vieles davon noch Grundlagenforschung ist, gibt es dort doch heute schon Vorbereitungen, den Streitkräften bald Anwendungsmöglichkeiten zur Verfügung zu stellen. Ein Viertel bis ein Drittel der Regierungsausgaben für NT auf Bundesebene steht für militärische FuE zur Verfügung, und die USA geben 4 bis 10 mal so viel dafür aus wie der Rest der Welt. NT-Anwendungen werden alle Bereiche des Militärs durchdringen. Hierzu zählt der umfassende Einsatz sehr kleiner Elektronik und Computer, z.B. in Brillen, Uniformen, Munition. Komplexe Schlachtführungs- und Strategieplanungssysteme werden zunehmend autonom funktionieren und menschenähnliche Überlegungen anstellen, wobei sie Sensoren, Kommunikationsgeräte und Anzeigeeinheiten zu einem allgegenwärtigen Netzwerk verbinden. Festere und dabei leichtere Materialien, effizientere Energiespeicher und Antriebe ermöglichen den Bau schnellerer und beweglicherer Land-, Wasser-, Luft- und Raumfahrzeuge. Des weiteren können NT-basierte Materialien und Sprengstoffe zur Herstellung schnellerer und genauerer Geschosse verwendet werden. Denkbar sind metallfreie Kleinwaffen, Munition und Antipersonen-Flugkörper. Zwar ist bei Kernwaffen keine große Veränderung zu erwarten, NT kann aber zu verschiedenen neuen Arten von chemischen und biologischen Waffen führen, die auf spezifische Organe zielen oder selektiv auf eine bestimmte Eiweißstruktur oder auf ein genetisches Muster hin aktiv werden. Andererseits wird NT billige Sensoren für chemische oder biologische Waffen sowie Materialien zur Entgiftung zur Verfügung stellen. Mit den meisten dieser Anwendungen ist erst in einem Zeitraum von zehn oder mehr Jahren zu rechnen. Mögliche militärische NT-Anwendungen müssen unter den Kriterien der Präventiven Rüstungskontrolle bewertet werden." (Textauszug

Millimetre waves, lasers, acoustics for non-lethal weapons? Physics analyses and inferences

"New technologies of non-lethal weapons (NLW) are under military research and development, mainly in the USA. Due to incomplete information, judgement under criteria of the laws of warfare or of human rights is hampered. This study analyses four potential NLW technologies which are based on physics to provide reliable information for such assessment." (excerpt)"Neue Techniken nicht-tödlicher Waffen (ntW) sind in militärischer Forschung und Entwicklung, vor allem in den USA. Durch unvollständige Information wird die Beurteilung unter Kriterien des Humanitären Völkerrechts oder der Menschenrechte behindert. Diese Studie analysiert vier mögliche ntW-Techniken, die auf physikalischer Grundlage beruhen, um verlässliche Information für eine solche Beurteilung zur Verfügung zu stellen." (Textauszug

Toric rings, inseparability and rigidity

This article provides the basic algebraic background on infinitesimal deformations and presents the proof of the well-known fact that the non-trivial infinitesimal deformations of a $K$-algebra $R$ are parameterized by the elements of cotangent module $T^1(R)$ of $R$. In this article we focus on deformations of toric rings, and give an explicit description of $T^1(R)$ in the case that $R$ is a toric ring. In particular, we are interested in unobstructed deformations which preserve the toric structure. Such deformations we call separations. Toric rings which do not admit any separation are called inseparable. We apply the theory to the edge ring of a finite graph. The coordinate ring of a convex polyomino may be viewed as the edge ring of a special class of bipartite graphs. It is shown that the coordinate ring of any convex polyomino is inseparable. We introduce the concept of semi-rigidity, and give a combinatorial description of the graphs whose edge ring is semi-rigid. The results are applied to show that for $m-k=k=3$, $G_{k,m-k}$ is not rigid while for $m-k\geq k\geq 4$, $G_{k,m-k}$ is rigid. Here $G_{k,m-k}$ is the complete bipartite graph $K_{m-k,k}$ with one edge removed.Comment: 33 pages, chapter 2 of the Book << Multigraded Algebra and Applications>> 2018, Springer International Publishing AG, part of Springer Natur

Survey of the Status of Small and Very Small Missiles

The project ‘Preventive Arms Control for Small and Very Small Armed Aircraft and Missiles’ investigates the properties of ever smaller aircraft and missiles. This project report no. 2 covers the status of missiles worldwide. Small and very small missiles are defined by diameter: below 69 mm and up to 40 mm, respectively. After an explanation of missile classes and typical properties, a short introduction into rocket propulsion and aerodynamics is given. A technical overview describes the components of a missile. A few example types are shown and potential military uses are discussed. The worldwide survey has resulted in a database that contains 50 types from 17 countries. The publicly available properties are given in 24 categories. Statistical evaluations cover several key parameters

Small and Very Small Armed Aircraft and Missiles: Trends in Technology and Preventive Arms Control

The project ‘Preventive Arms Control for Small and Very Small Armed Aircraft and Missiles’ investigates the properties of ever smaller aircraft and missiles and explores possibilities for preventive arms control. The first part of this project report no. 3 covers the technological trends in both categories. (Further) miniaturisation is supported by civilian developments in mobile devices. Cheap production can allow swarms of very many uninhabited aerial vehicle (UAVs). Armed UAVs down to centimetre sizes and missiles down to 20 or 10 mm diameter are possible, with correspondingly very small destructive payloads. The second part assesses small and very small armed aircraft and missiles under criteria of preventive arms control. Both categories raise problems, mainly for international humanitarian law and military stability. Arms races have to be feared, increasing the threat of proliferation to non-state actors. Options for preventive limitations, confidence building and export control are presented. Recommended are prohibitions of autonomous attack and of swarms of autonomous armed systems, independent of size. If these are unattainable, limits should be established for quality and quantity of swarms; lower limits should be set for the size of armed UAVs and missiles; at a minimum numerical thresholds on the holdings of small and very small UAVs and missiles should be agreed on

Survey of the Status of Small Armed and Unarmed Uninhabited Aircraft

The project ‘Preventive Arms Control for Small and Very Small Armed Aircraft and Missiles’ investigates the properties of ever smaller aircraft and missiles. This project report no. 1 covers the status of aircraft worldwide, including relevant unarmed vehicles but excluding hobby aircraft. Small and very small aircraft are defined by size: below 2 m and below 0.2 m, respectively. After an elementary introduction into aerodynamics a technical overview is given, looking at airframe configurations, materials and manufacturing, power and propulsion, guidance, launch and recovery, and payloads. Future possibilities and trends are illustrated by presenting military research and development of the technological leader, the USA. Short chapters deal with swarms and with countermeasures. The worldwide survey has resulted in a database that contains 129 types from 27 countries. The publicly available properties are given in 26 categories. Statistical evaluations cover several key parameters

Improving printability of a thermoresponsive hydrogel biomaterial ink by nanoclay addition

As a promising biofabrication technology, extrusion-based bioprinting has gained significant attention in the last decade and major advances have been made in the development of bioinks. However, suitable synthetic and stimuli-responsive bioinks are underrepresented in this context. In this work, we described a hybrid system of nanoclay Laponite XLG and thermoresponsive block copolymer poly(2-methyl-2-oxazoline)-b-poly(2-n-propyl-2-oxazine) (PMeOx-b-PnPrOzi) as a novel biomaterial ink and discussed its critical properties relevant for extrusion-based bioprinting, including viscoelastic properties and printability. The hybrid hydrogel retains the thermogelling properties but is strengthened by the added clay (over 5 kPa of storage modulus and 240 Pa of yield stress). Importantly, the shear-thinning character is further enhanced, which, in combination with very rapid viscosity recovery (similar to 1 s) and structure recovery (similar to 10 s), is highly beneficial for extrusion-based 3D printing. Accordingly, various 3D patterns could be printed with markedly enhanced resolution and shape fidelity compared to the biomaterial ink without added clay. Graphic abstractPeer reviewe