Manoharan Lab

Manoharan Lab Github We use optical techniques that we develop in our lab to observe both natural systems (such as viruses) and synthetic ones (such as colloidal particles, perhaps dressed up with some interesting biomolecules) in three dimensions and on short time scales. Vinothan n. manoharan wagner family professor of chemical engineering and professor of physics, harvard university verified email at seas.harvard.edu homepage soft condensed matter physics.

Manoharan Lab Manoharan Lab Discover physics research opportunities at harvard. browse labs, explore research areas, and find your path to joining cutting edge research projects. In particular, we develop this software for cameras attached to microscopes. code to run simulations described in "disassembly of virus like particles " journal article. a conda smithy repository for holopy. manoharan lab has 22 repositories available. follow their code on github. We are a research group in the school of engineering and applied sciences and the department of physics at harvard university. we do experiments to understand how complex systems such as interacting nanoparticles or proteins spontaneously order themselves. the spontaneous emergence of an ordered structure from disorder is called "self assembly.". In my lab we use light scattering, optical microscopy, spectroscopy, synthesis and other experimental techniques to understand the physics of self organization. for most of these experiments we use colloids, suspensions of particles typically about a micrometer in size.

Manoharan Lab We are a research group in the school of engineering and applied sciences and the department of physics at harvard university. we do experiments to understand how complex systems such as interacting nanoparticles or proteins spontaneously order themselves. the spontaneous emergence of an ordered structure from disorder is called "self assembly.". In my lab we use light scattering, optical microscopy, spectroscopy, synthesis and other experimental techniques to understand the physics of self organization. for most of these experiments we use colloids, suspensions of particles typically about a micrometer in size. Our focus is on understanding and mimicking intracellular transport. Ben is an incoming phd student in applied physics, currently working on in line holographic microscopy of cyanobacteria. he loves rabbit holes, mechanical clocks, and outdoorsy stuff. kai is a phd student in physics studying short range interactions in colloidal and biological systems. Achieving precise control over the diverse equilibrium configurations and corresponding optical textures of motile liquid crystals (lcs) in response to a wide range of external stimuli is a formidable challenge. this complexity becomes even more. Show abstract download pdf access full text go to publisher's version.

Manoharan Lab Our focus is on understanding and mimicking intracellular transport. Ben is an incoming phd student in applied physics, currently working on in line holographic microscopy of cyanobacteria. he loves rabbit holes, mechanical clocks, and outdoorsy stuff. kai is a phd student in physics studying short range interactions in colloidal and biological systems. Achieving precise control over the diverse equilibrium configurations and corresponding optical textures of motile liquid crystals (lcs) in response to a wide range of external stimuli is a formidable challenge. this complexity becomes even more. Show abstract download pdf access full text go to publisher's version.

Manoharan Lab Achieving precise control over the diverse equilibrium configurations and corresponding optical textures of motile liquid crystals (lcs) in response to a wide range of external stimuli is a formidable challenge. this complexity becomes even more. Show abstract download pdf access full text go to publisher's version.

Manoharan Lab