Part of NCSSM CORE collection: This animation shows the rotation of the linear molecule C2H2.
Part of NCSSM CORE collection: This animation shows the rotation shows the rotation of a linear molecule like CO2
Part of NCSSM CORE collection: This animation shows the rotation of a linear molecule like XeF2.
Part of NCSSM CORE collection: This animation shows the rotation of the octahedral molecule SF6.
Part of NCSSM CORE collection: This animation shows the rotation of an octahedral molecule like SF6
Part of NCSSM CORE collection: This animation shows the rotation of a see-saw molecule like SF4.
Part of NCSSM CORE collection: This animation shows the rotation of a square planar molecule like XeF4.
Part of NCSSM CORE collection: This animation shows the rotation of a square pyramidal molecule like BrF5
Part of NCSSM CORE collection: This animation shows the rotation of a tetrahedral molecule like CH4.
Part of NCSSM CORE collection: This animation shows the rotation of the tetrahedral molecule CH4
Part of NCSSM CORE collection: This animation shows the rotation of the trigonal bipyramidal molecule PCl5
Part of NCSSM CORE collection: This animation shows the rotation of a trigonal Trigonal Bipyramidal Molecule like PCl5.
Animation of a Trigonal Planar 3D Rotating Molecule, used in VSEPR Theory and other chemistry applications.
Part of NCSSM CORE collection: This animation shows the rotation of the trigonal planar molecule C2H4
Animation of a Trigonal Pyramidal 3D Rotating Molecule, used in VSEPR Theory and other chemistry applications.
Part of NCSSM CORE collection: This animation shows the rotation of the trigonal pyramidal molecule NH3
Part of NCSSM CORE collection: This animation shows the rotation of a T-shaped molecule like BrF3.
This resource is a video used to support the V-Scope Explorer application.
How variation can be introduced into a species.
Hank introduces us to one of the most diverse and important families in the tree of life - the vascular plants. These plants have found tremendous success and the their secret is also their defining trait: conductive tissues that can take food and water from one part of a plant to another part. Though it sounds simple, the ability to move nutrients and water from one part of an organism to another was a evolutionary breakthrough for vascular plants, allowing them to grow exponentially larger, store food for lean times, and develop features that allowed them to spread farther and faster. Plants dominated the earth long before animals even showed up, and even today hold the world records for the largest, most massive, and oldest organisms on the planet.