Science has given us nearly infinite possibilities for controlling life. Scientists probe the origins of life through research with stem cells and embryos. To unlock the secrets of disease, biomedicine conducts cruel experiments on animals. GM crops are presented as the answer to hunger. Organ transplantation is almost routine. The international traffic in human body parts and tissues is thriving. The concept of brain death makes harvesting organs ethically more acceptable. It may also result in fundamental changes in our ideas about life. Science has provided new ways of controlling and manipulating life and death. As a consequence, difficult ethical questions are raised in increasingly complex cultural and social environments. This course will discuss major issues in the ethics of biology and medicine, from gene modification to Dolly the sheep. This unit will be introductory, but a small number of topical issues will be studied in depth. No scientific background beyond Year 10 level will be assumed.

The topics covered by HPSC1000 - Bioethics will be treated in more depth, in a special tutorial set aside for Advanced students.

This Unit of Study explores the very nature of science and how it is practised. Using contemporary and historical scientific examples, the unit looks into whether a sharp line can be drawn between science and non-science, and what criteria can be used to distinguish science from pseudoscience. Various tools of science will be examined philosophically and historically, including theories, models, explanations, data analysis and concepts. The unit also looks into the ways in which science is a social process, with an emphasis on values, biases, and the institutionalized organization of science. To complete this broad overview, topics such as science denialism (not accepting various bodies of scientific knowledge) and scientism (valuing science above all other knowledge systems) will also be addressed.

This Unit of Study explores the very nature of science and how it is practised. Using contemporary and historical scientific examples, the unit looks into whether a sharp line can be drawn between science and non-science, and what criteria can be used to distinguish science from pseudoscience. Various tools of science will be examined philosophically and historically, including theories, models, explanations, data analysis and concepts. The unit also looks into the ways in which science is a social process, with an emphasis on values, biases, and the institutionalized organization of science. To complete this broad overview, topics such as science denialism (not accepting various bodies of scientific knowledge) and scientism (valuing science above all other knowledge systems) will also be addressed.

What is the role of science in society? What should it be? Scientific knowledge is often difficult to understand without years of training, and yet this knowledge is crucial to social welfare, and to our political and environmental futures. In this Unit of Study, we look at the practical realities of living in a society of which science is an integral part. Our examples come from across the sciences, with an emphasis on the health sciences, and on biodiversity, climate change, and environmental challenges. Major themes are:
1. Science in Society: how can publics relate to scientific knowledge? What is the importance of trust in science? What is the role of experts? What does it mean to say that science and society are co-constructed?
2. The West and the Rest: what are the relations between so-called "Western science" and other knowledge systems? What role has science played in colonial legacies? Our focus is on relations with Aboriginal Australian knowledges and cultures.
3. Facts and Norms: how does science relate to social and political values? Can scientific facts be independent of these values? We look at the historical origins of important concepts of science and ethics in response to the Second World War, and at present-day examples e.g. in biomedical research.

Modern culture is a culture of science and modern science is the outcome of a historical process of 2,500 years. In this course we investigate how traditional knowledge gradually acquired the characteristics of 'science': the social structure, contents, values and procedures we are familiar with. We will look at some primary chapters of this process, from antiquity to the end of the seventeenth century, and try to understand their implications to understanding contemporary science in its culture.

The topics covered in 'The Birth of Modern Science' will be covered in more depth, in a special tutorial set aside for advanced students.

Modern Western science has a number of characteristics that distinguish it from other scientific cultures. It ascribes its tremendous success to sophisticated experiments and meticulous observation. It understands the universe in terms of tiny particles in motion and the forces between them. It is characterised by high- powered mathematical theorising and the rejection of any intention, value or purpose in Nature. Many of these characteristics were shaped in the 17th century, during the so-called scientific revolution. We will consider them from an integrated historical- philosophical perspective, paying special attention to the intellectual motivations of the canonical figures of this revolution and the cultural context in which they operated. Topics will include: experimentation and instrumentation, clocks, mechanistic philosophy, and the changing role of mathematics.

Our ever-changing world requires knowledge that extends across multiple disciplines. The ability to identify and explore interdisciplinary links is a crucial skill for emerging professionals and researchers alike. This unit presents the opportunity to bring together the concepts and skills you have learnt in your discipline and apply them to a real-world problem. You will work on a project which involves evaluating theories in HPS based on knowledge drawn from collaborators in another discipline, for instance by taking a recent scientific controversy or theoretical innovation as a case study. For example, you might test a proposal about the theoretical basis of neuroscience by comparing it to a predictive coding model of brain function, or test assumptions about how scientific models work by studying specific models in climatology or ecology. In this unit, you will continue to understand and explore disciplinary knowledge, while also meeting and collaborating with students from across the University through project-based learning; identifying and solving problems, collecting and analysing data and communicating your findings to a diverse audience. All of these skills are highly valued by employers. This unit will foster the ability to work in interdisciplinary teams, and this is essential for both professional and research pathways in the future.

This interdisciplinary unit provides students with the opportunity to address complex problems identified by industry, community, and government organisations, and gain valuable experience in working across disciplinary boundaries. In collaboration with a major industry partner and an academic lead, students integrate their academic skills and knowledge by working in teams with students from a range of disciplinary backgrounds. This experience allows students to research, analyse and present solutions to a real-world problem, and to build on their interpersonal and transferable skills by engaging with and learning from industry experts and presenting their ideas and solutions to the industry partner.

This Unit of Study is dedicated to the science of life, and focuses on the history and philosophy of biology and medicine. Findings about phenomena such as the origins of life, evolution, and the relative contributions of DNA and various environmental factors to living processes have been debated not only by scientists but also the public. New accounts of the nature of disease and novel treatment strategies call for critical reflection on their implications. In this Unit of Study, we will take a closer look at a wide range of research concerned with life, disease, and death. We will focus in particular on the contributions historians and philosophers of science can make to discussions in the life sciences.

Across the unit we examine one of the most interesting aspects of the history and philosophy of science. viz., the scientific practices and assumptions involved in making human beings an object of study. We will examine the ways in which psychologists and psychiatrists have investigated human nature, the kinds of experimental approaches they have developed to that end, the major controversies in this field, and the basic philosophical assumptions that have been made in the sciences of human nature. We investigate the developments of psychological theories and investigative methods as well as the development of psychiatric theory, treatment methods, and institutions.

This unit of study deals with some central problems in the history and philosophy of the natural sciences. It covers two areas in detail, and several others in less depth. The two main topics are (1) evidence in science, especially how evidence is understood within a Bayesian model, and (2) the representation of nature with scientific models and other theoretical tools. We will also look at the role of truth as a scientific goal, links between scientific theories and policy decisions, and the formation and role of consensus within science. Upon completion of the unit, students will have developed a range of skills that will allow them to explore the natural sciences with a more critical attitude.