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The course will be for sustained work on an animation or projection design project, and should be a space for both experimentation, ambition and consistent endeavor. The first half of the semester will be concerned with conceptualizing and framing the world of the animations or projections, by research, drawings, investigation, imagining. The second half will be creating the animation or projections.

The class will be both looking at abstraction as well as more figurative based work. The class will include a mixture of creating assemblages in a variety of means and materials, and using both digital and analogue means from paint, to sand to animated forms. Objects will be cut out with scissors or the laser cutter, animated with pins or digital pins in software (After Effects), layers will be used to create depth in three dimensions, a multiplane or using the Z axis.

The class will be concerned with animating inanimate objects by primarily stop motion.  Locations will be constructed, objects to animated formed, and lighting explored in order to create the imaginary world. A variety of filmmakers and techniques will be looked at during the course of the semester, with individual research undertaken and presented.  Students will be expected to produce a variety of short projects over the first seven weeks based on current affairs and future worlds, followed by a longer more sustained project.

Since its inception, film has been used for propaganda - disseminating information with a particular slant, whether subtle or obvious - by regimes and independent players across the political spectrum. As the means of production and circuits of distribution become ever more accessible to individuals, we have moved from an era of focused agitprop into a new era of diffused disinformation.

This course offers an immersive experience into the world of DNA, genes, and genomes in eukaryotic organisms.  In addition to getting a grasp of the foundational biology, students will engage with various online databases and resources, becoming familiar with the computational algorithms and methodologies used to mine and analyze the ever-increasing data generated from whole-genome sequencing, and consider how that improves our understanding of evolutionary relationships amongst organisms based on their molecular fingerprints.  In the second half of the term, students

Research questions in cell biology and biochemistry often require the ability to study the proteins at the heart of the inquiry.  This course will give students hands-on experience quantifying proteins, detecting protein expression, measuring enzymatic activity, assessing protein-protein interactions, purifying proteins, and visualizing fluorescently-labeled proteins in vivo.

This rigorous course provides a comprehensive introduction of the nervous system, including its structure, function, and development. Students will explore the principles of the cellular and molecular mechanisms that allow neurons and other specialized nervous cells to detect, encode, and transmit information; including signaling, synaptic transmission, and neuroplasticity.

Scanning electron microscopes are a fundamental tool in the physical and life sciences. When equipped with an X-Ray spectrometer, a SEM can provide rapid physical and chemical data of specimens on extremely small scales. This class with cover the theory and practical applications of SEM imaging and analysis for advanced science students who have their own research interests. Students will be expected to develop and conduct an independent research project through this class.

Bennington’s campus supports beautiful examples of temperate deciduous mixed hardwood forests. This class is a deep dive into forest ecology, land use change, and forest succession at a local scale. Students will explore the local forest community composition, structure, and function over the last 15,000 years and discuss the environmental conditions, disturbance dynamics, and biotic interactions responsible for the forest we have today.

Evolution is the unifying theory of biology, explaining the diversity of life on Earth and the mechanisms that drive adaptation and speciation. This course will explore the core principles of evolutionary biology, including natural selection, genetic drift, gene flow, mutation, and the interplay between evolutionary processes and ecological contexts. We will examine key evolutionary events, from the origins of life to the development of complex traits, using case studies across diverse taxa.