Loading doc/fix_rigid.html +9 −8 Original line number Diff line number Diff line Loading @@ -62,13 +62,14 @@ single entity. portions of a large biomolecule such as a protein. </P> <P>Example of small rigid bodies are patchy nanoparticles, such as those modeled by the <A HREF = "Glotzer">Glotzer group</A>, clumps of granular particles, lipid molecules consiting of one or more point dipoles connected to other spheroids or ellipsoids, and coarse-grain models of nano or colloidal particles consisting of a small number of constituent particles. Note that the <A HREF = "fix_shake">fix shake</A> command can also be used to rigidify small molecules of 2, 3, or 4 atoms, e.g. water molecules. That fix treats the constituent atoms as point masses. modeled in <A HREF = "#Zhang">this paper</A> by Sharon Glotzer's group, clumps of granular particles, lipid molecules consiting of one or more point dipoles connected to other spheroids or ellipsoids, and coarse-grain models of nano or colloidal particles consisting of a small number of constituent particles. Note that the <A HREF = "fix_shake.html">fix shake</A> command can also be used to rigidify small molecules of 2, 3, or 4 atoms, e.g. water molecules. That fix treats the constituent atoms as point masses. </P> <P>The constituent particles within a rigid body can be point particles (the default in LAMMPS) or finite-size particles, such as spheroids Loading Loading @@ -249,7 +250,7 @@ all rigid bodies are acted on by center-of-mass force and torque. </P> <HR> <A NAME = "Glotzer_group"></A> <A NAME = "Zhang"></A> <P><B>(Zhang)</B> Zhang, Glotzer, Nanoletters, 4, 1407-1413 (2004). </P> Loading doc/fix_rigid.txt +9 −8 Original line number Diff line number Diff line Loading @@ -53,13 +53,14 @@ Examples of large rigid bodies are a large colloidal particle, or portions of a large biomolecule such as a protein. Example of small rigid bodies are patchy nanoparticles, such as those modeled by the "Glotzer group"_Glotzer, clumps of granular particles, lipid molecules consiting of one or more point dipoles connected to other spheroids or ellipsoids, and coarse-grain models of nano or colloidal particles consisting of a small number of constituent particles. Note that the "fix shake"_fix_shake command can also be used to rigidify small molecules of 2, 3, or 4 atoms, e.g. water molecules. That fix treats the constituent atoms as point masses. modeled in "this paper"_#Zhang by Sharon Glotzer's group, clumps of granular particles, lipid molecules consiting of one or more point dipoles connected to other spheroids or ellipsoids, and coarse-grain models of nano or colloidal particles consisting of a small number of constituent particles. Note that the "fix shake"_fix_shake.html command can also be used to rigidify small molecules of 2, 3, or 4 atoms, e.g. water molecules. That fix treats the constituent atoms as point masses. The constituent particles within a rigid body can be point particles (the default in LAMMPS) or finite-size particles, such as spheroids Loading Loading @@ -240,5 +241,5 @@ all rigid bodies are acted on by center-of-mass force and torque. :line :link(Glotzer_group) :link(Zhang) [(Zhang)] Zhang, Glotzer, Nanoletters, 4, 1407-1413 (2004). Loading
doc/fix_rigid.html +9 −8 Original line number Diff line number Diff line Loading @@ -62,13 +62,14 @@ single entity. portions of a large biomolecule such as a protein. </P> <P>Example of small rigid bodies are patchy nanoparticles, such as those modeled by the <A HREF = "Glotzer">Glotzer group</A>, clumps of granular particles, lipid molecules consiting of one or more point dipoles connected to other spheroids or ellipsoids, and coarse-grain models of nano or colloidal particles consisting of a small number of constituent particles. Note that the <A HREF = "fix_shake">fix shake</A> command can also be used to rigidify small molecules of 2, 3, or 4 atoms, e.g. water molecules. That fix treats the constituent atoms as point masses. modeled in <A HREF = "#Zhang">this paper</A> by Sharon Glotzer's group, clumps of granular particles, lipid molecules consiting of one or more point dipoles connected to other spheroids or ellipsoids, and coarse-grain models of nano or colloidal particles consisting of a small number of constituent particles. Note that the <A HREF = "fix_shake.html">fix shake</A> command can also be used to rigidify small molecules of 2, 3, or 4 atoms, e.g. water molecules. That fix treats the constituent atoms as point masses. </P> <P>The constituent particles within a rigid body can be point particles (the default in LAMMPS) or finite-size particles, such as spheroids Loading Loading @@ -249,7 +250,7 @@ all rigid bodies are acted on by center-of-mass force and torque. </P> <HR> <A NAME = "Glotzer_group"></A> <A NAME = "Zhang"></A> <P><B>(Zhang)</B> Zhang, Glotzer, Nanoletters, 4, 1407-1413 (2004). </P> Loading
doc/fix_rigid.txt +9 −8 Original line number Diff line number Diff line Loading @@ -53,13 +53,14 @@ Examples of large rigid bodies are a large colloidal particle, or portions of a large biomolecule such as a protein. Example of small rigid bodies are patchy nanoparticles, such as those modeled by the "Glotzer group"_Glotzer, clumps of granular particles, lipid molecules consiting of one or more point dipoles connected to other spheroids or ellipsoids, and coarse-grain models of nano or colloidal particles consisting of a small number of constituent particles. Note that the "fix shake"_fix_shake command can also be used to rigidify small molecules of 2, 3, or 4 atoms, e.g. water molecules. That fix treats the constituent atoms as point masses. modeled in "this paper"_#Zhang by Sharon Glotzer's group, clumps of granular particles, lipid molecules consiting of one or more point dipoles connected to other spheroids or ellipsoids, and coarse-grain models of nano or colloidal particles consisting of a small number of constituent particles. Note that the "fix shake"_fix_shake.html command can also be used to rigidify small molecules of 2, 3, or 4 atoms, e.g. water molecules. That fix treats the constituent atoms as point masses. The constituent particles within a rigid body can be point particles (the default in LAMMPS) or finite-size particles, such as spheroids Loading Loading @@ -240,5 +241,5 @@ all rigid bodies are acted on by center-of-mass force and torque. :line :link(Glotzer_group) :link(Zhang) [(Zhang)] Zhang, Glotzer, Nanoletters, 4, 1407-1413 (2004).
