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	<CENTER><A HREF = "http://lammps.sandia.gov">LAMMPS WWW Site</A> - <A HREF = "Manual.html">LAMMPS Documentation</A> - <A HREF = "Section_commands.html#comm">LAMMPS Commands</A>
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	<HR>

	<H3>thermo_style command
	</H3>
	<P><B>Syntax:</B>
	</P>
	<PRE>thermo_style style args
	</PRE>
	<UL><LI>style = <I>one</I> or <I>multi</I> or <I>custom</I>

	<LI>args = list of arguments for a particular style

	<PRE> <I>one</I> args = none
	<I>multi</I> args = none
	<I>custom</I> args = list of attributes
	possible attributes = step, atoms, cpu, temp, press,
	pe, ke, etotal, enthalpy,
	evdwl, ecoul, epair, ebond, eangle, edihed, eimp,
	emol, elong, etail,
	vol, lx, ly, lz, xlo, xhi, ylo, yhi, zlo, zhi,
	pxx, pyy, pzz, pxy, pxz, pyz
	c_ID, c_ID[n], f_ID, f_ID[n], v_name
	step = timestep
	atoms = # of atoms
	cpu = elapsed CPU time
	temp = temperature
	press = pressure
	pe = total potential energy
	ke = kinetic energy
	etotal = total energy (pe + ke)
	enthalpy = enthalpy (pe + press*vol)
	evdwl = VanderWaal pairwise energy
	ecoul = Coulombic pairwise energy
	epair = pairwise energy (evdwl + ecoul + elong + etail)
	ebond = bond energy
	eangle = angle energy
	edihed = dihedral energy
	eimp = improper energy
	emol = molecular energy (ebond + eangle + edihed + eimp)
	elong = long-range kspace energy
	etail = VanderWaal energy long-range tail correction
	vol = volume
	lx,ly,lz = box lengths in x,y,z
	xlo,xhi,ylo,yhi,zlo,zhi = box boundaries
	pxx,pyy,pzz,pxy,pxz,pyz = 6 components of pressure tensor
	c_ID = global scalar value calculated by a compute with ID
	c_ID[N] = Nth component of global vector calculated by a compute with ID
	f_ID = global scalar value calculated by a fix with ID
	f_ID[N] = Nth component of global vector calculated by a fix with ID
	v_name = global value calculated by an equal-style variable with name
	</PRE>

	</UL>
	<P><B>Examples:</B>
	</P>
	<PRE>thermo_style multi
	thermo_style custom step temp pe etotal press vol
	thermo_style custom step temp etotal c_myTemp v_abc
	</PRE>
	<P><B>Description:</B>
	</P>
	<P>Set the style and content for printing thermodynamic data to the
	screen and log file.
	</P>
	<P>Style <I>one</I> prints a one-line summary of thermodynamic info that is
	the equivalent of "thermo_style custom step temp epair emol etotal
	press". The line contains only numeric values.
	</P>
	<P>Style <I>multi</I> prints a multiple-line listing of thermodynamic info
	that is the equivalent of "thermo_style custom etotal ke temp pe ebond
	eangle edihed eimp evdwl ecoul elong press". The listing contains
	numeric values and a string ID for each quantity.
	</P>
	<P>Style <I>custom</I> is the most general setting and allows you to specify
	which of the keywords listed above you want printed on each
	thermodynamic timestep. Note that the keywords c_ID, f_ID, v_name are
	references to <A HREF = "compute.html">computes</A>, <A HREF = "fix.html">fixes</A>, and
	equal-style <A HREF = "variable.html"">variables</A> that have been defined
	elsewhere in the input script or can even be new styles which users
	have added to LAMMPS (see the <A HREF = "Section_modify.html">Section_modify</A>
	section of the documentation). Thus the <I>custom</I> style provides a
	flexible means of outputting essentially any desired quantity as a
	simulation proceeds.
	</P>
	<P>All styles except <I>custom</I> have <I>vol</I> appended to their list of
	outputs if the simulation box volume changes during the simulation.
	</P>
	<P>The values printed by the various keywords are instantaneous values,
	calculated on the current timestep. Time-averaged quantities, which
	include values from previous timesteps, can be output by using the
	f_ID keyword and accessing a fix that does time-averaging such as the
	<A HREF = "fix_ave_time.html">fix ave/time</A> command.
	</P>
	<P>Options invoked by the <A HREF = "thermo_modify.html">thermo_modify</A> command can
	be used to set the one- or multi-line format of the print-out, the
	normalization of thermodynamic output (total values versus per-atom
	values for "extensive quantities, meaning ones which scale with the
	number of atoms in the system), and the numeric precision of each
	printed value.
	</P>
	<P>IMPORTANT NOTE: When you use a "thermo_style" command, all
	thermodynamic settings are restored to their default values, including
	those previously set by a <A HREF = "thermo_modify.html">thermo_modify</A> command.
	Thus if your input script specifies a thermo_style command, you should
	use the thermo_modify command after it.
	</P>
	<HR>

	<P>Several of the thermodynamic quantities require a temperature to be
	computed: "temp", "press", "ke", "etotal", "enthalpy", "pxx etc". By
	default this is done by using the "thermo_temp" compute which is
	created when LAMMPS starts up, as if this command had been issued:
	</P>
	<PRE>compute thermo_temp all temp
	</PRE>
	<P>See the <A HREF = "compute_temp.html">compute temp</A> command for details. Note
	that the ID of this compute is <I>thermo_temp</I> and the group is <I>all</I>.
	You can change the attributes of this temperature (e.g. its
	degrees-of-freedom) via the <A HREF = "compute_modify.html">compute_modify</A>
	command. Alternatively, you can directly assign a new compute (that
	calculates temperature) which you have defined, to be used for
	calculating any thermodynamic quantity that requires a temperature.
	This is done via the <A HREF = "thermo_modify.html">thermo_modify</A> command.
	</P>
	<P>Several of the thermodynamic quantities require a pressure to be
	computed: "press", "enthalpy", "pxx", etc. By default this is done by
	using the pressure compute which is created when LAMMPS starts up, as
	if this command had been issued:
	</P>
	<PRE>compute thermo_press all pressure thermo_temp
	</PRE>
	<P>See the <A HREF = "compute_pressure.html">compute pressure</A> command for details.
	Note that the ID of this compute is <I>thermo_press</I> and the group is
	<I>all</I>. You can change the attributes of this pressure via the
	<A HREF = "compute_modify.html">compute_modify</A> command. Alternatively, you can
	directly assign a new compute (that calculates pressure) which you
	have defined, to be used for calculating any thermodynamic quantity
	that requires a pressure. This is done via the
	<A HREF = "thermo_modify.html">thermo_modify</A> command.
	</P>
	<P>Several of the thermodynamic quantities require a potential energy to
	be computed: "pe", "etotal", "ebond", etc. This is done by using the
	"thermo_pe" compute which is created when LAMMPS starts up, as if this
	command had been issued:
	</P>
	<PRE>compute thermo_pe all pe
	</PRE>
	<P>See the <A HREF = "compute_pe.html">compute pe</A> command for details. Note that
	the ID of this compute is <I>thermo_pe</I> and the group is <I>all</I>. You can
	change the attributes of this potential energy via the
	<A HREF = "compute_modify.html">compute_modify</A> command.
	</P>
	<HR>

	<P>The kinetic energy of the system <I>ke</I> is inferred from the temperature
	of the system with 1/2 Kb T of energy for each degree of freedom.
	Thus, using different <A HREF = "compute.html">compute commands</A> for calculating
	temperature, via the <A HREF = "thermo_modify.html">thermo_modify temp</A> command,
	may yield different kinetic energies, since different computes that
	calculate temperature can subtract out different non-thermal
	components of velocity and/or include different degrees of freedom
	(translational, rotational, etc).
	</P>
	<P>The potential energy of the system <I>pe</I> will include contributions
	from fixes if the <A HREF = "fix_modify.html">fix_modify thermo</A> option is set
	for a fix that calculates such a contribution. For example, the <A HREF = "fix_wall_lj93">fix
	wall/lj93</A> fix calculates the energy of atoms
	interacting with the wall. See the doc pages for "individual fixes"
	to see which ones contribute.
	</P>
	<P>A long-range tail correction <I>etail</I> for the VanderWaal pairwise
	energy will be non-zero only if the <A HREF = "pair_modify.html">pair_modify
	tail</A> option is turned on. The <I>etail</I> contribution
	is included in <I>evdwl</I>, <I>pe</I>, and <I>etotal</I>, and the corresponding tail
	correction to the pressure is included in <I>press</I> and <I>pxx</I>, <I>pyy</I>,
	etc.
	</P>
	<HR>

	<P>The <I>c_ID</I> and <I>c_ID[N]</I> keywords allow global scalar or vector
	quantities calculated by a compute to be output. The ID in the
	keyword should be replaced by the actual ID of the compute that has
	been defined elsewhere in the input script. See the
	<A HREF = "compute.html">compute</A> command for details. Note that only global
	scalar or vector quantities calculated by a compute can be output as
	thermodynamic data; per-atom quantities calculated by a compute can be
	output by the <A HREF = "dump.html">dump custom</A> command. There is a <A HREF = "compute_reduce.html">compute
	reduce</A> command which can sum per-atom quantities
	into a global scalar or vector which can be output by thermo_style
	custom.
	</P>
	<P>Note that some computes calculate "intensive" global quantities like
	temperature; others calculate "extensive" global quantities like
	kinetic energy that are summed over all atoms in the compute group.
	Intensive quantities are printed directly as is by thermo_style
	custom. Extensive quantities may be normalized when output by the
	total number of atoms in the simulation (NOT the number of atoms in
	the compute group) depending on the <A HREF = "thermo_modify.html">thermo_modify
	norm</A> option being used.
	</P>
	<P>If <I>c_ID</I> is used as a keyword, then the scalar quantity calculated by
	the compute is printed. If <I>c_ID[N]</I> is used, then N must be an
	index from 1-M where M is the length of the vector calculated by the
	compute. See the doc pages for individual compute styles for info on
	what these quantities are.
	</P>
	<P>The <I>f_ID</I> and <I>f_ID[N]</I> keywords allow global scalar or vector
	quantities calculated by a fix to be output. The ID in the keyword
	should be replaced by the actual ID of the fix that has been defined
	elsewhere in the input script. See the doc pages for individual <A HREF = "fix.html">fix
	commands</A> for details of which fixes generate global values.
	One particularly useful fix to use in this context is the <A HREF = "fix_ave_time.html">fix
	ave/time</A> command, which calculates time-averages of
	global scalar and vector quantities calculated by other
	<A HREF = "compute.html">computes</A>, <A HREF = "fix.html">fixes</A>, or
	<A HREF = "variable.html">variables</A>.
	</P>
	<P>Note that some fixes calculate "intensive" global quantities like
	timestep size; others calculate "extensive" global quantities like
	energy that are summed over all atoms in the fix group. Intensive
	quantities are printed directly as is by thermo_style custom.
	Extensive quantities may be normalized when output by the total number
	of atoms in the simulation (NOT the number of atoms in the fix group)
	depending on the <A HREF = "thermo_modify.html">thermo_modify norm</A> option being
	used.
	</P>
	<P>If <I>f_ID</I> is used as a keyword, then the scalar quantity calculated by
	the fix is printed. If <I>f_ID[N]</I> is used, then N must be an index
	from 1-M where M is the length of the vector calculated by the fix.
	See the doc pages for individual fix styles for info on which fixes
	calculate these global quantities and what they are. For fixes that
	compute a contribution to the potential energy of the system, the
	scalar quantity referenced by f_ID is typically that quantity.
	</P>
	<P>The <I>v_name</I> keyword allow the current value of a variable to be
	output. The name in the keyword should be replaced by the actual name
	of the variable that has been defined elsewhere in the input script.
	Only equal-style variables can be referenced. See the
	<A HREF = "variable.html">variable</A> command for details. Variables of style
	<I>equal</I> can reference individual atom properties or thermodynamic
	keywords, or they can invoke other computes, fixes, or variables when
	evaluated, so this is a very general means of creating thermodynamic
	output.
	</P>
	<P>See <A HREF = "Section_modify.html">this section</A> for information on how to add
	new compute and fix styles to LAMMPS to calculate quantities that
	could then be output with these keywords as part of thermodynamic
	information.
	</P>
	<HR>

	<P><B>Restrictions:</B>
	</P>
	<P>This command must come after the simulation box is defined by a
	<A HREF = "read_data.html">read_data</A>, <A HREF = "read_restart.html">read_restart</A>, or
	<A HREF = "create_box.html">create_box</A> command.
	</P>
	<P><B>Related commands:</B>
	</P>
	<P><A HREF = "thermo.html">thermo</A>, <A HREF = "thermo_modify.html">thermo_modify</A>,
	<A HREF = "fix_modify.html">fix_modify</A>, <A HREF = "compute_temp.html">compute temp</A>,
	<A HREF = "compute_pressure.html">compute pressure</A>
	</P>
	<P><B>Default:</B>
	</P>
	<PRE>thermo_style one
	</PRE>
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