There existed a tradition of mimetic experimentation in the late nineteenth century, whereby morphologists sought to scale down sublime natural phenomena to tabletop devices in the laboratory. Experimenters constructed analogs of the aurora, attempting to replicate the colors and forms of the phenomenon with discharge tube experiments and electrical displays, which became popular spectacles at London’s public galleries. This paper analyses a closely allied but different kind of imitation. Between 1872 and 1884, Professor Karl Selim Lemström (1838–1904) attempted to (...) reproduce the aurora borealis in all of its complexity atop four mountains in northern Finland. Crucially, his “artificial aurora” was to materialize at the same scale as the original phenomenon and in its natural habitat in the polar atmosphere. With his experiment Lemström hoped to uncover the workings of the aurora and the electrical currents that he believed were always present within the atmosphere; his epistemological framework was one of learning by making. This paper sheds light on the broader problem of what it meant to authentically replicate a phenomenon that remained largely enigmatic, and, most importantly, how this replication could be verified. This prompts a discussion as to whether model experiments needed only to appear visually similar to the objects they purported to imitate, were required to preserve their form, or needed to be materially identical in order to the original to be identified as legitimate “reproductions” in the late nineteenth century. (shrink)

Newton's bucket, Einstein's elevator, Schrödinger's cat – these are some of the best-known examples of thought experiments in the natural sciences. But what function do these experiments perform? Are they really experiments at all? Can they help us gain a greater understanding of the natural world? How is it possible that we can learn new things just by thinking? In this revised and updated new edition of his classic text _The Laboratory of the Mind_, James Robert Brown continues to (...) defend apriorism in the physical world. This edition features two new chapters, one on “counter thought experiments” and another on the development of inertial motion. With plenty of illustrations and updated coverage of the debate between Platonic rationalism and classic empiricism, this is a lively and engaging contribution to the field of philosophy of science. (shrink)

Chapter 1 FROM ORDER TO DISORDER 5 mins. John enters and goes into his office. He says something very quickly about having made a bad mistake. He had sent the review of a paper. . . . The rest of the sentence is inaudible. 5 mins.

In lieu of an abstract, here is a brief excerpt of the content:Adjusting Laboratory Practices to the Challenges of WartimeOksana Sulaieva, Anna Shcherbakova, and Oleksandr DudinFunding. Oksana Sulaieva, MD, PhD is supported by the Loyola University Chicago–Ukrainian Catholic University Bioethics Fellowship Program, funded by the National Institutes of Health Fogarty International Center (D43TW011506).After 500 days of the unjust war initiated by the Russians, we look back to reflect on the challenges our medical laboratory faced during these early days. (...) On the morning of February 24th, we were awakened by the dreadful roar of sirens, the sound of which filled us with adrenaline and anxiety. Although our team had considered the risks of Russian military aggression and thus updated our emergency plan at the beginning of 2022, the first day of the war revealed that nobody was truly ready for the bombing, air alarms, tanks on the streets of towns and cities, violence and murders of civilians. That morning the city’s transportation system collapsed, and the flow of cars cluttered all the roads as people were trying to leave the city and escape the upcoming atrocities and death. Serious and disquieted people hurried along the streets—some people rushed to shelters, and others went to the military registration and enlistment offices to fight against Russian aggressors for the life, independence, and sovereignty of Ukraine.We hurried to work, committed to performing our duties. Our medical laboratory serves more than 750 hospitals in Ukraine. Despite fear and uncertainty, we walked to the lab, taking our children and alarm case1 with documents and essential things. Months later, people asked us why we went to the laboratory instead of leaving the city or even the country. At that moment, our [End Page 155] professional duties were an anchor linking us to each other against fear and panic. Our responsibility to provide patients and physicians with the results of blood testing, pathology, and molecular reports outweighed our fears of the war. We had to complete the testing of all the samples delivered to the laboratory to provide our customers—who include children, pregnant women, diabetic and cancer patients—with data essential for identifying accurate diagnoses and effective treatments. So we spent the first days of the war in the laboratory. At the same time, we had obligations and responsibilities to our staff as well. We had to consider how to manage our employees’ protection along with continuous laboratory services provided under endless air alarms and bombings. Many healthcare facilities in eastern regions and around Kyiv were affected by missiles or completely destroyed. Of our sixty laboratory offices around Ukraine, ten were damaged or abandoned due to occupation. Several of our fleet cars were also damaged and riddled with bullets. Many employees in the regional offices in Melitopol, Kherson, Mariupol, Chernihiv, and in suburbs of Kyiv such as Bucha and Irpin lost their homes as a result of massive military operations or occupation. Dozens of our employees joined the Ukrainian armed forces to defend civilians and fight against aggressors. Many others became volunteers, involved in blood donation, medical care for the wounded, cooking, and serving the troops. And still, we had to continue our work and protect our staff at the same time. We also helped each other by sharing our goods, medication, homes, cars, warmth, and support. Some pathologists stayed at the workplace for several days moving between pathology stations, microscopes and shelters, and sleeping on the floor but continuing to work.Our main challenge was the regular terroristic attacks on healthcare facilities situated far away from the front line, which in fact, violated international humanitarian law regarding respect for human rights during armed conflicts. During the first weeks of the war, the magnitude of military aggression, massive bombing, and air attacks undermined the healthcare system and endangered laboratory staff and patients. We prioritized protective measures. Some of our laboratory staff and facilities were evacuated from Kyiv to Lviv in western Ukraine. The partial relocation of our laboratory to Lviv was also driven by the displacement of several million Ukrainians to the western part of the country.We were able to arrange relatively safe accommodations for our laboratory employees and their families in Lviv. Under strikes and alarms, our... (shrink)

We develop an account of laboratory models, which have been central to the group selection controversy. We compare arguments for group selection in nature with Darwin's arguments for natural selection to argue that laboratory models provide important grounds for causal claims about selection. Biologists get information about causes and cause-effect relationships in the laboratory because of the special role their own causal agency plays there. They can also get information about patterns of effects and antecedent conditions in (...) nature. But to argue that some cause is actually responsible in nature, they require an inference from knowledge of causes in the laboratory context and of effects in the natural context. This process, cause detection, forms the core of an analogical argument for group selection. We discuss the differing roles of mathematical and laboratory models in constructing selective explanations at the group level and apply our discussion to the units of selection controversy to distinguish between the related problems of cause determination and evaluation of evidence. Because laboratory models are at the intersection of the two problems, their study is crucial for framing a coherent theory of explanation for evolutionary biology. (shrink)

The laboratory animal environment: room for concern.

Fourteen subjects were tape‐recorded while they undertook to find a law to summarize numerical data they were given. The source of the data was not identified, nor were the variables labeled semantically. Unknown to the subjects, the data were measurements of the distances of the planets from the sun and the periods of their revolutions about it—equivalent to the data used by Johannes Kepler to discover his third law of planetary motion.Four of the 14 subjects discovered the same law as (...) Kepler did (the period varies as the 3/2 power of the distance), and a fifth came very close to the answer. The subiects' protocols provide a detailed picture of the problem‐solving searches they engaged in, which were mainly, but not exclusively, in the space of possible functions for fitting the data, and provide explanations as to why some succeeded and the others failed.The search heuristics used by the subjects are similar to those embodied in the BACON program, computer simulation of certain scientific discovery processes. The experiment demonstrates the feasibility of examining some of the processes of scientific discovery by recreating, in the laboratory, discovery situations of substantial historical relevance. It demonstrates also, that under conditions rather similar to those of the original discoverer, a law can be rediscovered by persons of ordinary intelligence (i.e., the intelligence needed for academic success in a good university). The data for the successful subjects reveal no “creative” processes in this kind of a discovery situation different from those that are regularly observed in all kinds of problem‐solving settings. (shrink)

Preparative and analytical methods developed by separation scientists have played an important role in the history of molecular biology. One such early method is gel electrophoresis, a technique that uses various types of gel as its supporting medium to separate charged molecules based on size and other properties. Historians of science, however, have only recently begun to pay closer attention to this material epistemological dimension of biomolecular science. This paper substantiates the historiographical thread that explores the relationship between modern (...) class='Hi'>laboratory practice and the production of scientific knowledge. It traces the historical development of gel electrophoresis from the mid-1940s to the mid-1960s, with careful attention to the interplay between technical developments and disciplinary shifts, especially the rise of molecular biology in this time-frame. Claiming that the early 1950s marked a decisive shift in the evolution of electrophoretic methods from moving boundary to zone electrophoresis, I reconstruct various trajectories in which scientists such as Oliver Smithies sought out the most desirable solid supporting medium for electrophoretic instrumentation. Biomolecular knowledge, I argue, emerged in part from this process of seeking the most appropriate supporting medium that allowed for discrete molecular separation and visualization. The early 1950s, therefore, marked not only an important turning point in the history of separation science, but also a transformative moment in the history of the life sciences as the growth of molecular biology depended in part on the epistemological access to the molecular realm available through these evolving technologies. (shrink)

The ArgumentThere can be no doubt about the moral and epistemological significance of what Shapin calls the “physical place” of the scientific laboratory. The physical place is defined by the locales, barriers, ports of entry, and lines of sight that bound the laboratory and separate it from other urban and architectural environments. Shapin's discussion of the emergence of the scientific laboratory in seventeenth-century England provides a convincing demonstration that credible knowledge is situated at an intersection between physical (...) locales and social distinctions. In this paper I take up Shapin's theme of the “siting of knowledge production,” but I give it a different treatment – one based on ethnomethodological studies of work. Without denying all that can be witnessed in the spectacle of the scientist at the bench and of the architectural habitat of the bench, I argue that the “place” of scientific work is defined by locally organizedtopical contextures. The paper describes two examples of such spatial orders – “opticism” and “digitality” – associated with distinct complexes of equipment and practice. These topical spaces might initially be viewed as “ideal” or “symbolic” spaces, but I argue that they are no less material than the “physical setting” of the laboratory; indeed, they are the physical setting. (shrink)

Preparative and analytical methods developed by separation scientists have played an important role in the history of molecular biology. One such early method is gel electrophoresis, a technique that uses various types of gel as its supporting medium to separate charged molecules based on size and other properties. Historians of science, however, have only recently begun to pay closer attention to this material epistemological dimension of biomolecular science. This paper substantiates the historiographical thread that explores the relationship between modern (...) class='Hi'>laboratory practice and the production of scientific knowledge. It traces the historical development of gel electrophoresis from the mid-1940s to the mid-1960s, with careful attention to the interplay between technical developments and disciplinary shifts, especially the rise of molecular biology in this time-frame. Claiming that the early 1950s marked a decisive shift in the evolution of electrophoretic methods from moving boundary to zone electrophoresis, I reconstruct various trajectories in which scientists such as Oliver Smithies sought out the most desirable solid supporting medium for electrophoretic instrumentation. Biomolecular knowledge, I argue, emerged in part from this process of seeking the most appropriate supporting medium that allowed for discrete molecular separation and visualization. The early 1950s, therefore, marked not only an important turning point in the history of separation science, but also a transformative moment in the history of the life sciences as the growth of molecular biology depended in part on the epistemological access to the molecular realm available through these evolving technologies. (shrink)

Technical achievement in laboratories requires millennia–old ritual formulations; the methodological expectations and presuppositions of scientists stem not only from investigations of the last three centuries but also from the ritual knowledge making that has governed human religion. Laboratory research is a form of human ritual open to interpretation in the manner of religious ritual. The experiments of the laboratory are fact–gathering ventures, but the integration of that knowledge into our general understanding of a universe of information networks is (...) the process of knowledge making, and it is the highest achievement of all rituals, be they religious or scientific. Ritual theory offers insight into the nature of scientific experimentation. (shrink)

Thought-intrusions, automatic inferences, and other unintended thought are beginning to play an important role in the study of psychiatric disease as well as normal thought processes. We examine one method for study of task-unrelated imagery and thought . TUIT likelihood was shown to be reliably measured over a wide range of vigilance tasks, to have high short-term and long-term test-retest reliability, and to be sensitive to information processing demands. Likelihood of TUITs was shown to be different as a function of (...) aging, hyperactivity, time of day, and level of depression. Thus, we now can reliably measure the influence of endogenous and exogenous influences on TUITs. In addition, TUIT measurement was proposed as a minimally interfering and natural second task for determining resource utilization in a primary task. Finally, this method was offered as a reliable approach to quantification of such mental states as obsessions and drug craving and addiction. (shrink)

This article analyzes the results of a teaching innovation project developed during the academic year 2021-2022, whose main objective was to assess the need to in- clude a compulsory subject of mediation and collaborative conflict resolution in the degree in Social Work at UCM. To this end, an international working group has been formed in the form of an Ideas Lab that has developed a research combining quan- titative (questionnaire) and qualitative (Design Thinking) tools, whose results have allowed to develop (...) a proposal that has been submitted to the dean's office for consideration in the future modification of the degree. But undoubtedly, the most remarkable thing is that through the laboratory it has been possible to guaran-tee essential elements for the quality of the training of our university community: transversality, transdisciplinarity, internationalization and transfer of knowledge. (shrink)

UK science policy now includes ‘upstream public engagement’ as an element in the responsible development of nanotechnology. This paper explores different understandings of the term upstream engagement before discussing in more detail a laboratory-based collaboration between social science and nanoscience aimed at exploring the social dimensions of nanotechnology. The paper concludes that concern with defining what counts as ‘upstream’ can obscure more critical questions about how to make public, and therefore accountable, deliberations about the interrelated social and technical aspects (...) of nanoscience. (shrink)

Although some regulatory frameworks for the occupational health and safety of nanotechnology workers have been developed, worker safety and health issues in these laboratory environments have received less attention than many other areas of nanotechnology regulation. In addition, workers in nanotechnology labs are likely to face unknown risks and hazards because few of the guidelines and rules for worker safety are mandatory. In this article, we provide an overview of the current health and safety guidelines for nanotechnology laboratory (...) workers by exploring guidelines from different organizations, including the Department of Energy Nanoscale Science Research Centers, Massachusetts Institute of Technology, the National Institutes of Health, the National Institute for Occupational Safety and Health, the Occupational Safety and Health Administration, Texas A&M University, and University of Massachusetts-Lowell. After discussing these current guidelines, we apply an ethical framework to each set of guidelines to explore any gaps that might exist in them. By conducting this gap analysis, we are able to highlight some of the weaknesses that might be important for future policy development in this area. We conclude by outlining how future guidelines might address some of these gaps, specifically the issue of workers’ participation in the process of establishing safety measures and the development and enforcement of more unified guidelines. (shrink)

Surprisingly little attention has been given hitherto to the definition of the laboratory. A space has to be specially adapted to deserve that title. It would be easy to assume that the two leading experimental sciences, physics and chemistry, have historically depended in a similar way on access to a laboratory. But while chemistry, through its alchemical ancestry with batteries of stills, had many fully fledged laboratories by the seventeenth century, physics was discovering the value of mathematics. Even (...) experimental physics was content to make use of almost any indoor space, if not outdoors, ignoring the possible value of a laboratory. The development of the physics laboratory had to wait until the nineteenth century. (shrink)

During the early twentieth century, the Bermuda Biological Station for Research functioned as a multipurpose scientific site. Jointly founded by New York University, Harvard University, and the Bermuda Natural History Society, the BBSR created opportunities for a mostly US-based set of practitioners to study animal biology in the field. I argue that mixed gender field stations like the BBSR supported professional advancement in science, while also operating as important places for women and men to experiment with the social and cultural (...) work of identity formation, courtship and marriage, and social critique. Between 1903 and 1930, the BBSR functioned as a laboratory of domesticity, a temporary scientific household in British Bermuda where women and men interacted with established colonial ideologies about science, sex difference, and racial hierarchy in their public and private accounts of doing biology and socializing in the field. Viewing field stations as generative of multiple forms of labor offers a corrective to narratives within the history of biology, in which scientific practices are considered to be the principal forms of output produced by practitioners in the field. Understanding how women and men at the BBSR engaged with the politics of gender and race from the periphery of U.S. networks of biology suggests that we might view field stations as shaping not only academic science but also domestic life and fields as disparate as fiction and the law. (shrink)

Moral philosophers in the laboratory -- Case studies -- Critical perspectives.

Chemistry laboratories, as buildings, have been surprisingly little studied by historians of science; interest has been focused on them more as sites of specific scientific activity, with particular emphasis on the personalities who worked within them. This has overshadowed aspects of laboratories such as their specification, design, construction, fitting-out, adaptation, replacement, status as civic and academic structures, and so on. Systematic study of them would be aided by an agreed taxonomy of laboratory types, according to their purpose, and a (...) scheme is proposed here. Practically no pre-1800 chemical laboratories survive, and there are very few dating from earlier than 1900, at least in their original state. Encouragingly, there have been several recent archaeological excavations which have turned up interesting evidence of early examples from various cultures. Little interest has been shown in the preservation of laboratories as significant architectural or historical structures, certainly when compared with other building types. The paper closes by considering those English laboratories which enjoy some level of legal protection but questioning the criteria adopted in deciding the programme of preservation. (shrink)

Georg Simon Ohm's work in the field of electricity led to what is now considered to be the most fundamental law of electrical circuits, Ohm's Law. Much less known is that only months earlier, Ohm had published another law—one that differed significantly from the now accepted one. The latter entailed a logarithmic relation between the length of the conductor and a parameter that Ohm called “loss of force.” This paper discusses how Ohm came up with an initial law that he (...) felt compelled to correct a few months later. We analyze Ohm's publication as well as his laboratory notes, relating them to our own laboratory experiences while using the replication method to study his work. We also discuss the conceptual background of Ohm's work. We conclude that he was significantly influenced by French studies in the field of electricity, most notably the ones by Charles Augustin Coulomb. (shrink)

The increasing use of virtual laboratories in education raises new philosophical—and perhaps especially phenomenological—questions related to how this type of technological mediation affects the user’s sense of situated embodied being: sensory perception. The empirical basis of this phenomenological inquiry is a case study conducted in a Danish school setting. This allows us to compare analog laboratory work with virtual. Inspired by Maurice Merleau-Ponty, we describe how pupils’ bodily and multisensory interactions with laboratory tools differ across physical and virtual (...) settings. Virtual laboratories are complex, sociotechnical, often opaque practices that affect the pupils’ sense of embodiment, thus prompting the need for in situ development of hermeneutical strategies for bridging the gap between the simulated laboratory and the physical world. In the final section, we discuss how these strategies can be considered posthuman learning processes. (shrink)

ABSTRACT An examination of the use of the word “laboratory” before the nineteenth century yields two striking results. First, “laboratory” referred almost exclusively to a room or house where chemical operations such as distillation, combustion, and dissolution were performed. Second, a “laboratory” was not exclusively a scientific institution but also an artisanal workplace. Drawing on the historical actors' use of “laboratory,” the essay first presents (some necessarily scattered) evidence for the actual correspondence between artisanal and scientific (...) laboratories in the eighteenth century. A particularly instructive case is the way the equipment of the laboratory of the Prussian Academy of Sciences was acquired. There was, in this case, a direct transfer of instruments, vessels, and materials from a pharmaceutical to an academic laboratory. The essay then argues that we ought to distinguish between two different experimental traditions in the early modern period: experimental philosophy and the laboratory tradition that meshed studies of nature with technological innovation. (shrink)

Phenologists track the seasonal behavior of plants and animals in response to climatic change. During the second half of the twentieth century, phenologists developed a large-scale project to monitor the flowering time of the common lilac across the United States. By the 1960s, this approach offered a potential plant-based indicator of anthropogenic climate change, a biological signal amidst the emerging narrative of increasing levels of atmospheric carbon dioxide. As a tangible representation of changes in climate—warmer temperatures lead to earlier blooming—phenology (...) proved highly legible to scientists, politicians, and laypeople. Yet, as phenology gained broader repute in the 1960s, both in agricultural stations and as a component program of the International Biological Program, it struggled to align itself epistemically with the regnant disciplinary assumptions of mid-century ecology. Operating in the hinterlands between laboratory and field, biology and meteorology, ecological theory and agronomy practice, phenologists challenged prevailing notions of the model organism and what it meant to study biology in the field. Rebranding the discipline as a component of ecosystem modeling, scientists successfully brought phenology within the purview of mainstream ecology. In so doing, however, they obscured its climate-relevant meteorological character and stymied the development of a biological narrative of climate change. (shrink)

Laboratory of Synthesis is a publishing project edited by Robert Garnett and Andrew Hunt that will bring together philosophers, artists, theorists and critics in order to discuss new approaches to art writing. It intends to operate in the widening gap between the mainstream art magazine and the academic journal in order to create new conjunctions and productive disjunctions between theory and practice out of which new voices and new modes of art writing might emerge.

A caring approach to knowledge production has been portrayed as epistemologically radical, ethically vital and as fostering continuous responsibility between researchers and research-subjects. This article examines these arguments through focusing on the ambivalent role of care within the first large-scale experimental beagle colony, a self-professed ‘beagle utopia’ at the University of California, Davis. We argue that care was at the core of the beagle colony; the lived environment was re-shaped in response to animals ‘speaking back’ to researchers, and ‘love’ and (...) ‘kindness’ were important considerations during staff recruitment. Ultimately, however, we show that care relations were used to manufacture compliancy, preventing the predetermined ends of the experiment from being troubled. Rather than suggesting Davis would have been less ethically troubling, or more epistemologically radical, with ‘better’ care, however, we suggest the case troubles existing care theory and argue that greater attention needs to be paid to histories, contexts, and exclusions. (shrink)

Human biological tissue samples are an invaluable resource for biomedical research designed to find causes of diseases and their treatments. Controversy has arisen, however, when research has been conducted with laboratory specimens either without the consent of the source of the specimen or when the research conducted with the specimen has expanded beyond the scope of the original consent agreement. Moreover, disputes have arisen regarding which party, the researcher or the source of the specimen, has control over who may (...) use the specimens and for what purposes. The purposes of this article are: to summarize the most important litigation regarding the use of laboratory specimens, and to demonstrate how legal theory regarding control of laboratory specimens has evolved from arguments based upon property interests in biological samples to claims that the origins of laboratory specimens have privacy interests in their genetic information that should be protected. (shrink)

The global distribution of laboratory mouse strains is valued for ensuring the continuity, validity and accessibility of model organisms. Mouse strains are therefore assumed mobile and able to travel. We draw on the concept of ‘animal mobilities’ to explain how attending to laboratory mice as living animal, commodity and scientific tool is shaping how they are transported through contemporary scientific infrastructures and communities. Our paper is framed around exploring how animal strains travel, rather than animals, as we show (...) that it is only through understanding strain mobility that we can explain how and why live animal movement can be replaced by germinal products. The research is based on qualitative fieldwork in 2018 and 2019 that included 2 weeks ethnography and interviews with key informants involved in the movement of laboratory animals. The empirical analysis discusses practices that relate to managing biosecurity and animal welfare concerns when moving laboratory animal strains. In closing we reflect more broadly on the contemporary ‘ethico-onto-epistemological’ entanglement that shapes who or what travels to support laboratory science data-making practices, and the intensity of care ‘tinkering’ practices that facilitate the movement. We explain how a laboratory animal strain exceeds its value solely as a mobile and thus exchangeable commodity, illustrated in how values that relate to animal sentience and infection-risk supports its material transformation. Consequently, it is becoming increasingly common for non-sentient germinal products – embryos and gametes - to replace live sentient animals when being moved. (shrink)

Testing economic propositions in laboratory experiments has proven a very fruitful research endeavor in recent years. This volume brings together the major contributors to experimental economics. The papers present their views on the way experiments should be done, on the power and limitations of the techniques, and on the areas in which experimentation could contribute substantially to our understanding of economic behavior. This book distills the main lessons from great experience in experimental work. It will be essential reading for (...) all who wish to follow experimental work or who wish to do such work themselves. (shrink)

This article discusses the conditions under which dialogical learner-researchers can move out of the philosophical laboratory of a community of philosophical inquiry into the field of social activism, engaging in a critical and creative examination of society and seeking to change it. Based on Matthew Lipman’s proposal that communities of philosophical inquiry can serve as a model of social activism in the present, it presents the community of philosophical inquiry as a model for social activism in the future. In (...) other words, Lipman’s central ideas in his earlier and later thought—including meaning as a mode of action, relevance as a way of examining life and stimulating influence for change as a form of creating a democratic society—establish two parallel circle of influence: the present time, in the shape of the philosophical community of inquiry that allows activist skills to be honed, and a social space that extends into the future as a forum for applying principles and bettering society. Finally, this paper adduces several forms of social activism that may be anchored in philosophical awareness of real conditions and their contexts. Through them, the community of philosophical inquiry not only constitutes a place in which young people’s thought processes can be developed but also one in which they can aspire to become activists in various areas. (shrink)

In her influential article published in 2016, Alexandra Walsham, Professor of Modern History at the University of Cambridge, coined the metaphor that ‘Archives are the factories and laboratories of the historian’. Traditionally viewed as neutral storehouses of official records passively awaiting historians’ scrutiny, conceptions of archives have expanded in recent decades. Archives are now understood as complex social and cultural entities that actively participate in shaping understandings of the past. This paper examines shifting perspectives on the nature and functions of (...) archives through a critical analysis of key debates. Specifically, this paper adopts a hermeneutic lens to critically engage Walsham’s metaphor and move beyond its potential limitations through situated analysis and interpretation. This paper explores how archives are actively implicated in knowledge construction through their contents, organisational frameworks, and interactions with historians. Recognising archives as fragmented, culturally contingent remnants that mediate engagement with the past, the paper calls for collaborative, reflective approaches between archivists and historians. The paper also acknowledges historians’ subjective interpretive roles while advocating consultation of archivists’ contextual expertise. Ultimately, it advances methodological discussions on writing history through a nuanced appreciation of archives as dynamic mediators within historical research, not transparent conduits neutrally supplying facts. (shrink)

The conduct of most of social science occurs outside the laboratory. Such studies in field science explore phenomena that cannot for practical, technical, or ethical reasons be explored under controlled conditions. These phenomena cannot be fully isolated from their environment or investigated by manipulation or intervention. Yet measurement, including rigorous or clinical measurement, does provide analysts with a sound basis for discerning what occurs under field conditions, and why. In Science Outside the Laboratory, Marcel Boumans explores the state (...) of measurement theory, its reliability, and the role expert judgment plays in field investigations from the perspective of the philosophy of science. Its discussion of the problems of passive observation, the calculus of observation, the two-model problem, and model-based consensus uses illustrations drawn primarily from economics. Rich in research and discussion, the volume clarifies the extent to which measurement provides valid information about objects and events in field sciences, but also has implications for measurement in the laboratory. Scholars in the fields of philosophy of science, social science, and economics will find Science Outside the Laboratory a compelling and informative read. (shrink)

Mirrored-self misidentification is the delusional belief that one's own reflection in the mirror is a stranger. In two experiments, we tested the ability of hypnotic suggestion to model this condition. In Experiment 1, we compared two suggestions based on either the delusion's surface features (seeing a stranger in the mirror) or underlying processes (impaired face processing). Fifty-two high hypnotisable participants received one of these suggestions either with hypnosis or without in a wake control. In Experiment 2, we examined the extent (...) to which social cues and role-playing could account for participants' behaviour by comparing the responses of 14 hypnotised participants to the suggestion for impaired face processing (reals) with those of 14 nonhypnotised participants instructed to fake their responses (simulators). Overall, results from both experiments confirm that we can use hypnotic suggestion to produce a compelling analogue of mirrored-self misidentification that cannot simply be attributed to social cues or role-playing. (shrink)

Since we cannot put stars in a laboratory, astrophysicists had to wait till the invention of computers before becoming laboratory scientists. For half a century now, we have been conducting experiments in our virtual laboratories. However, we ourselves have remained behind the keyboard, with the screen of the monitor separating us from the world we are simulating. Recently, 3D on-line technology, developed first for games but now deployed in virtual worlds like Second Life, is beginning to make it (...) possible for astrophysicists to enter their virtual labs themselves, in virtual form as avatars. This has several advantages, from new possibilities to explore the results of the simulations to a shared presence in a virtual lab with remote collaborators on different continents. I will report my experiences with the use of Qwaq Forums, a virtual world developed by a new company. (shrink)

Philosophical concepts are easier to teach and to learn if students can directly manually and visually manipulate the objects instantiating them. What is needed is a philosophy laboratory in which students learn by experimenting. Games are highly idealized yet concrete structures able to instantiate abstract concepts. I show how to use the Game of Life (a computerized cellular automaton "game") to teach concepts like: individuation; supervenience; the phenomena / noumena distinction; the physical / design / and intentional stances; the (...) argument from design; and models for Leibnizian monads. Such formal games are good ways to use computers to teach philosophy. (shrink)

Astrophysics is often cast as an observational science, devoid of traditional experiments, along with astronomy and cosmology. Yet, a thriving field of experimental research exists called laboratory astrophysics. How should we make sense of this apparent tension? I argue that approaching the epistemology of astrophysics by attending to the production of empirical data and the aims of the research better illuminates both the successes and challenges of empirical research in astrophysics than evaluating the epistemology of astrophysics according to the (...) presence or absence of experiments. (shrink)

The Plymouth Laboratory of the Marine Biological Association of the United Kingdom (1884) was founded in 1888. In addition to conducting morphological and other biological research, the founders of the laboratory aimed at promoting research in experimental zoology which will be used in this paper as a synonym for e. g. experimental embryology, comparative physiology or general physiology. This dream was not fully realized until 1920. The Great War and its immediate aftermath had a positive impact on the (...) development of the Plymouth Laboratory. The war greatly upset the operation of the Zoological Station in Naples and the ensuing crisis in its operations was closely related to the establishment of the physiological department in Plymouth in 1920. Two other key factors in the Plymouth story were the establishment of the Development Fund in 1909, which began contributing funds to the Plymouth Laboratory in 1912, and the patronage of the Cambridge zoologist George P. Bidder (1863-1954). This paper will focus on the combined influence of the Development Fund and Bidder on the development of the Plymouth Laboratory from around 1902 through the early 1920s, and the important role the laboratory played in promoting experimental zoology in Britain in the 1920s. (shrink)

The mechanisms for cultural transmission remain disputable and difficult to validate through observational field studies alone. If controlled experimental laboratory investigation reveals that a putative mechanism is demonstrable in the species under study, then inferences that the same mechanism is operating in the field observation are strengthened.

We apply the author's computational approach to groups to our empirical work studying and modelling riots. We suggest that assigning roles in particular gives insight, and measuring the frequency of bystander behaviour provides a method to understand the dynamic nature of intergroup conflict, allowing social identity to be incorporated into models of riots.