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Student version lets you take your homework to where you want to work!
 
Student
HyperChem 7.5 is a special version of our sophisticated molecular modeling
environment that is known for its quality, flexibility, and ease of use. Uniting
3D visualization and animation with quantum chemical calculations, molecular
mechanics, and dynamics, HyperChem puts more molecular modeling tools at your
fingertips than any other Windows program.
Our
Student version, available only to registered university, college or junior
college students, has all the capabilities of our full version, with the
following atom limitations:
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Ab
Initio, DFT
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12
atoms
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Semi-Empirical
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36
atoms
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MM+
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100
atoms
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Amber,
Charmm, OPLS
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1000
atoms
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Student
HyperChem Release 7 is a full 32-bit application, developed for the Windows 95,
98, NT, ME, 2000 and XP operating systems, and incorporates even more powerful
computational chemistry tools than ever before, as well as newly incorporated
modules, additional basis sets, new drawing capabilities and more.
How
Do I Order Student HyperChem?
You need to
be a current student and complete this
form,
and fax with a copy of your student identification documentation to us at
800-787-5133. We accept Visa, MasterCard, Amex and Discover. HYPERCHEM 7.5
New Features
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Open GL Rendering
The basic rendering modeling in HyperChem has been
converted to a full new OpenGL model. This affects all the molecular
rendering, giving a generally higher quality of graphics throughout the
product. |
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Custom Color Support
It is now possible to color molecules, backgrounds,
etc. using any of 16 million available colors rather than the traditional 8
standard colors that HyperChem has used in the past. |
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Mixed Renderings
The rendering of molecules supports different
rendering for different parts of the same molecule. That is any atom can be
rendered using any of the rendering molecules -- stick, balls, ball and
stick, etc. |
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Tube Rendering of Atoms
A new "tube" rendering is now available for atoms. |
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Manipulate Protein Structures
Extensive additions have been made to HyperChem's
ability to deal with protein structures. HyperChem now supports four
secondary structure descriptions - helices, sheets, turns, and coils. The
secondary structures can be individual selected, colored, and rendered using
a new secondary structure rendering capability. |
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Support for Secondary Structure
Information in Protein Data Bank files
HyperChem recognizes and supports secondary
structure information in its molecule files. Information from protein
database (PDB) files is captured for and retained in HIN files. The
peptide builder supports this new capability and adds a secondary structure
description to all residues. |
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Protein Secondary Structure
Rendering
Secondary structure rendering now includes ribbon
lines, narrow ribbon sheets, thick ribbon sheets, encompassing helical
cylinders and a coil rendering. These new renderings can be selected for
any secondary structure or part of a secondary structure. They can be
colored globally or colored differently for specific residues. |
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Enhanced Protein Builder Capability
In addition to alpha helices and beta sheets, the
peptide builder now supports beta turns, parallel and anti-parallel beta
sheets, left-handed alpha helices, 310-helices, and pi-helices. |
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Large Molecule Electron Density
Approximation
A rapid new method is available for calculating and
displaying the electron density and electrostatic potential of molecules.
For example, the new method makes it practical to very quickly display the
electron density of large proteins. |
Feature Summary
Density
Functional Theory (DFT) has been added as a basic computational
engine to complement Molecular Mechanics, Semi-Empirical Quantum
Mechanics and Ab Initio
Quantum Mechanics. This
new computational method comes with full capabilities including
first and second derivatives so that all the capabilities of other
earlier engines are also available with DFT.
These include geometry optimization, infrared and optical
spectra, molecular dynamics, Monte Carlo, etc.
A full complement of
exchange and correlation functions is available, including eight
exchange functionals and eight correlation functionals that can be
combined in any fashion. Also
included are four combination or hybrid functions, such as the
popular B3-LYP or Becke-97 methods.
A choice of various integration grids, controlling the
method’s accuracy, is available to the user.
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The HyperNMR package has been integrated into
the core of HyperChem. This package allows for the simulation
of NMR spectra. An accurante semi-empirical tailored
specifically to NMR allows rapid interactive computation of NMR
shielding constants (chemical shifts) and coupling constants for
molecules as large as proteins. Basedon a solution of the
quantum mechanical coupled-Hartree-Fock equations rather than simple
database lookup, this package allows full exploration of NMR
parameters in any situation, such as a new or novel chemical
environment where simple database interpolation is impossible.
When appropriate, the NMR parameters can be
integrated into a spin Hamiltonian to predict and display the full
one-dimensional NMR spectra. The spectra can be manipulated to
add line widths so as to simulate experimental spectra.
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A full database
capability is integrated into HyperChem 7.
This includes database search and retrieval of molecules for
subsequent molecular modeling calculations as well as the storing of
computed properties and optimized structures of your molecules in a
new database. Included
with the product is a sample database of 10,000 molecules that have
previously been optimized with HyperChem.
The sample database that is included is representative of
common chemical compounds and can be used in a variety of ways
associated with research in computational chemistry.
Database
retrieval is simple and interactive and a variety of methods can be
used to search a database, including a search for 2D or 3D
structure. In
conjunction with HyperChem’s scripting capability, a generic
search based on appropriate computed properties is possible.
That is, a question such as, “Give me all molecules whose
stored or computed value of X is between x-d and x+d” is possible.
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Use HyperChem to explore quantum or classical
model potential energy surfaces with single point, geometry
optimization, or transition state search calculations. Include the
effects of thermal motion with molecular dynamics, Langevin dynamics
or Metropolis Monte Carlo simulations. User defined structural
restraints may be added.
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Types of Calculations
- Single point calculations determine the
molecular energy and properties for a given fixed geometry.
- Geometry optimization calculations employ
energy minimization algorithms to locate stable structures. Five
minimization algorithms are provided.
- Vibrational frequency calculations find the
normal vibrational modes of an optimized structure. The
vibrational spectrum can be displayed and the vibrational motions
associated with specific transitions can be animated.
- Transition state searching locates the
metastable structures corresponding to transition states using
either Eigenvector Following or Synchronous Transit methods.
Molecular properties are then calculated.
- Molecular dynamics simulations compute
classical trajectories for molecular systems. Quantum forces can
be used to model reactive collisions. Heating, equilibration, and
cooling periods can be employed for simulated annealing and for
studies of other temperature dependent processes. Both constant
energy and constant temperature simulations are available.
- Langevin dynamics simulations add frictional
and stochastic forces to conventional molecular dynamics to model
solvent collisional effects without inclusion of explicit solvent
molecules.
- Metropolis Monte Carlo simulations sample
configurations from a statistical ensemble at a given temperature
and are useful for exploring the possible configurations of a
system as well as for computing temperature dependent equilibrium
averages.
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HyperChem 7.01 Student Edition has every
feature available in HyperChem 7.01 Professional, apart from a
limitation on the number of atoms associated with energy
computations. The atom limitations in molecular mechanics and
quantum
mechanics calculations are as follows:
MM+ 100 atoms
Amber, Charmm, OPLS 1000 atoms
Semi-empirical 36 atoms
Ab initio, DFT 12 atoms
Molecular systems of any size may be opened, drawn, manipulated and
saved, but computations involving more than the above limits
are not permitted.
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You need to
be a current student and complete this
form,
and fax with a copy of your student identification documentation to us at
800-787-5133. We accept Visa, MasterCard, Amex and Discover.
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