PLUMED-NEST by plumed-nest

Project ID: plumID:22.028
Source: plumed_A2G2S2.dat
Originally used with PLUMED version: 2.7
Stable: zipped raw stdout - zipped raw stderr - stderr
Master: zipped raw stdout - zipped raw stderr - stderr
Click on the labels of the actions for more information on what each action computes
######### PLUMED file for performing RECT simulations on N-glycans #########
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MOLINFOThis command is used to provide information on the molecules that are present in your system. More details STRUCTUREa file in pdb format containing a reference structure=reference_A2G2S2.pdb
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# Define torsion angles for A2G2S2
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The MOLINFO action with label  calculates somethingphi1_2The TORSION action with label phi1_2 calculates the following quantities: Quantity    Type    Description  
phi1_2 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O5-2the O5 atom in residue 2. Click here for more information. ,@C1-2the C1 atom in residue 2. Click here for more information. ,@O4-1the O4 atom in residue 1. Click here for more information. ,@C4-1the C4 atom in residue 1. Click here for more information. 
psi1_2The TORSION action with label psi1_2 calculates the following quantities: Quantity    Type    Description  
psi1_2 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@C1-2the C1 atom in residue 2. Click here for more information. ,@O4-1the O4 atom in residue 1. Click here for more information. ,@C4-1the C4 atom in residue 1. Click here for more information. ,@C3-1the C3 atom in residue 1. Click here for more information. 
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phi2_3The TORSION action with label phi2_3 calculates the following quantities: Quantity    Type    Description  
phi2_3 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O5-3the O5 atom in residue 3. Click here for more information. ,@C1-3the C1 atom in residue 3. Click here for more information. ,@O4-2the O4 atom in residue 2. Click here for more information. ,@C4-2the C4 atom in residue 2. Click here for more information. 
psi2_3The TORSION action with label psi2_3 calculates the following quantities: Quantity    Type    Description  
psi2_3 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@C1-3the C1 atom in residue 3. Click here for more information. ,@O4-2the O4 atom in residue 2. Click here for more information. ,@C4-2the C4 atom in residue 2. Click here for more information. ,@C3-2the C3 atom in residue 2. Click here for more information. 
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phi3_4The TORSION action with label phi3_4 calculates the following quantities: Quantity    Type    Description  
phi3_4 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O5-4the O5 atom in residue 4. Click here for more information. ,@C1-4the C1 atom in residue 4. Click here for more information. ,@O3-3the O3 atom in residue 3. Click here for more information. ,@C3-3the C3 atom in residue 3. Click here for more information. 
psi3_4The TORSION action with label psi3_4 calculates the following quantities: Quantity    Type    Description  
psi3_4 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@C1-4the C1 atom in residue 4. Click here for more information. ,@O3-3the O3 atom in residue 3. Click here for more information. ,@C3-3the C3 atom in residue 3. Click here for more information. ,@C2-3the C2 atom in residue 3. Click here for more information. 
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phi4_5The TORSION action with label phi4_5 calculates the following quantities: Quantity    Type    Description  
phi4_5 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O5-5the O5 atom in residue 5. Click here for more information. ,@C1-5the C1 atom in residue 5. Click here for more information. ,@O2-4the O2 atom in residue 4. Click here for more information. ,@C2-4the C2 atom in residue 4. Click here for more information. 
psi4_5The TORSION action with label psi4_5 calculates the following quantities: Quantity    Type    Description  
psi4_5 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@C1-5the C1 atom in residue 5. Click here for more information. ,@O2-4the O2 atom in residue 4. Click here for more information. ,@C2-4the C2 atom in residue 4. Click here for more information. ,@C1-4the C1 atom in residue 4. Click here for more information. 
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phi5_6The TORSION action with label phi5_6 calculates the following quantities: Quantity    Type    Description  
phi5_6 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O5-6the O5 atom in residue 6. Click here for more information. ,@C1-6the C1 atom in residue 6. Click here for more information. ,@O4-5the O4 atom in residue 5. Click here for more information. ,@C4-5the C4 atom in residue 5. Click here for more information. 
psi5_6The TORSION action with label psi5_6 calculates the following quantities: Quantity    Type    Description  
psi5_6 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@C1-6the C1 atom in residue 6. Click here for more information. ,@O4-5the O4 atom in residue 5. Click here for more information. ,@C4-5the C4 atom in residue 5. Click here for more information. ,@C3-5the C3 atom in residue 5. Click here for more information. 

phi6_7The TORSION action with label phi6_7 calculates the following quantities: Quantity    Type    Description  
phi6_7 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O6-7the O6 atom in residue 7. Click here for more information. ,@C2-7the C2 atom in residue 7. Click here for more information. ,@O6-6the O6 atom in residue 6. Click here for more information. ,@C6-6the C6 atom in residue 6. Click here for more information. 
psi6_7The TORSION action with label psi6_7 calculates the following quantities: Quantity    Type    Description  
psi6_7 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@C2-7the C2 atom in residue 7. Click here for more information. ,@O6-6the O6 atom in residue 6. Click here for more information. ,@C6-6the C6 atom in residue 6. Click here for more information. ,@C5-6the C5 atom in residue 6. Click here for more information. 
omega6_7The TORSION action with label omega6_7 calculates the following quantities: Quantity    Type    Description  
omega6_7 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O6-6the O6 atom in residue 6. Click here for more information. ,@C6-6the C6 atom in residue 6. Click here for more information. ,@C5-6the C5 atom in residue 6. Click here for more information. ,@O5-6the O5 atom in residue 6. Click here for more information. 

phi3_8The TORSION action with label phi3_8 calculates the following quantities: Quantity    Type    Description  
phi3_8 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O5-8the O5 atom in residue 8. Click here for more information. ,@C1-8the C1 atom in residue 8. Click here for more information. ,@O6-3the O6 atom in residue 3. Click here for more information. ,@C6-3the C6 atom in residue 3. Click here for more information. 
psi3_8The TORSION action with label psi3_8 calculates the following quantities: Quantity    Type    Description  
psi3_8 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@C1-8the C1 atom in residue 8. Click here for more information. ,@O6-3the O6 atom in residue 3. Click here for more information. ,@C6-3the C6 atom in residue 3. Click here for more information. ,@C5-3the C5 atom in residue 3. Click here for more information. 
omega3_8The TORSION action with label omega3_8 calculates the following quantities: Quantity    Type    Description  
omega3_8 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O6-3the O6 atom in residue 3. Click here for more information. ,@C6-3the C6 atom in residue 3. Click here for more information. ,@C5-3the C5 atom in residue 3. Click here for more information. ,@O5-3the O5 atom in residue 3. Click here for more information. 
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phi8_9The TORSION action with label phi8_9 calculates the following quantities: Quantity    Type    Description  
phi8_9 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O5-9the O5 atom in residue 9. Click here for more information. ,@C1-9the C1 atom in residue 9. Click here for more information. ,@O2-8the O2 atom in residue 8. Click here for more information. ,@C2-8the C2 atom in residue 8. Click here for more information. 
psi8_9The TORSION action with label psi8_9 calculates the following quantities: Quantity    Type    Description  
psi8_9 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@C1-9the C1 atom in residue 9. Click here for more information. ,@O2-8the O2 atom in residue 8. Click here for more information. ,@C2-8the C2 atom in residue 8. Click here for more information. ,@C1-8the C1 atom in residue 8. Click here for more information. 
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phi9_10The TORSION action with label phi9_10 calculates the following quantities: Quantity    Type    Description  
phi9_10 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O5-10the O5 atom in residue 10. Click here for more information. ,@C1-10the C1 atom in residue 10. Click here for more information. ,@O4-9the O4 atom in residue 9. Click here for more information. ,@C4-9the C4 atom in residue 9. Click here for more information. 
psi9_10The TORSION action with label psi9_10 calculates the following quantities: Quantity    Type    Description  
psi9_10 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@C1-10the C1 atom in residue 10. Click here for more information. ,@O4-9the O4 atom in residue 9. Click here for more information. ,@C4-9the C4 atom in residue 9. Click here for more information. ,@C3-9the C3 atom in residue 9. Click here for more information. 
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phi10_11The TORSION action with label phi10_11 calculates the following quantities: Quantity    Type    Description  
phi10_11 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O6-11the O6 atom in residue 11. Click here for more information. ,@C2-11the C2 atom in residue 11. Click here for more information. ,@O6-10the O6 atom in residue 10. Click here for more information. ,@C6-10the C6 atom in residue 10. Click here for more information. 
psi10_11The TORSION action with label psi10_11 calculates the following quantities: Quantity    Type    Description  
psi10_11 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@C2-11the C2 atom in residue 11. Click here for more information. ,@O6-10the O6 atom in residue 10. Click here for more information. ,@C6-10the C6 atom in residue 10. Click here for more information. ,@C5-10the C5 atom in residue 10. Click here for more information. 
omega10_11The TORSION action with label omega10_11 calculates the following quantities: Quantity    Type    Description  
omega10_11 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@O6-10the O6 atom in residue 10. Click here for more information. ,@C6-10the C6 atom in residue 10. Click here for more information. ,@C5-10the C5 atom in residue 10. Click here for more information. ,@O5-10the O5 atom in residue 10. Click here for more information. 
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# Define puckering for each monosaccharide only to print it to file
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puck1The PUCKERING action with label puck1 calculates the following quantities: Quantity    Type    Description  
puck1.qx scalar Cartesian component x (6 membered rings)
puck1.qy scalar Cartesian component y (6 membered rings)
puck1.qz scalar Cartesian component z (6 membered rings)
puck1.phi scalar Pseudorotation phase (6 membered rings)
puck1.theta scalar Theta angle (6 membered rings)
puck1.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O5-1the O5 atom in residue 1. Click here for more information. ,@C1-1the C1 atom in residue 1. Click here for more information. ,@C2-1the C2 atom in residue 1. Click here for more information. ,@C3-1the C3 atom in residue 1. Click here for more information. ,@C4-1the C4 atom in residue 1. Click here for more information. ,@C5-1the C5 atom in residue 1. Click here for more information. 
puck2The PUCKERING action with label puck2 calculates the following quantities: Quantity    Type    Description  
puck2.qx scalar Cartesian component x (6 membered rings)
puck2.qy scalar Cartesian component y (6 membered rings)
puck2.qz scalar Cartesian component z (6 membered rings)
puck2.phi scalar Pseudorotation phase (6 membered rings)
puck2.theta scalar Theta angle (6 membered rings)
puck2.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O5-2the O5 atom in residue 2. Click here for more information. ,@C1-2the C1 atom in residue 2. Click here for more information. ,@C2-2the C2 atom in residue 2. Click here for more information. ,@C3-2the C3 atom in residue 2. Click here for more information. ,@C4-2the C4 atom in residue 2. Click here for more information. ,@C5-2the C5 atom in residue 2. Click here for more information. 
puck3The PUCKERING action with label puck3 calculates the following quantities: Quantity    Type    Description  
puck3.qx scalar Cartesian component x (6 membered rings)
puck3.qy scalar Cartesian component y (6 membered rings)
puck3.qz scalar Cartesian component z (6 membered rings)
puck3.phi scalar Pseudorotation phase (6 membered rings)
puck3.theta scalar Theta angle (6 membered rings)
puck3.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O5-3the O5 atom in residue 3. Click here for more information. ,@C1-3the C1 atom in residue 3. Click here for more information. ,@C2-3the C2 atom in residue 3. Click here for more information. ,@C3-3the C3 atom in residue 3. Click here for more information. ,@C4-3the C4 atom in residue 3. Click here for more information. ,@C5-3the C5 atom in residue 3. Click here for more information. 
puck4The PUCKERING action with label puck4 calculates the following quantities: Quantity    Type    Description  
puck4.qx scalar Cartesian component x (6 membered rings)
puck4.qy scalar Cartesian component y (6 membered rings)
puck4.qz scalar Cartesian component z (6 membered rings)
puck4.phi scalar Pseudorotation phase (6 membered rings)
puck4.theta scalar Theta angle (6 membered rings)
puck4.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O5-4the O5 atom in residue 4. Click here for more information. ,@C1-4the C1 atom in residue 4. Click here for more information. ,@C2-4the C2 atom in residue 4. Click here for more information. ,@C3-4the C3 atom in residue 4. Click here for more information. ,@C4-4the C4 atom in residue 4. Click here for more information. ,@C5-4the C5 atom in residue 4. Click here for more information. 
puck5The PUCKERING action with label puck5 calculates the following quantities: Quantity    Type    Description  
puck5.qx scalar Cartesian component x (6 membered rings)
puck5.qy scalar Cartesian component y (6 membered rings)
puck5.qz scalar Cartesian component z (6 membered rings)
puck5.phi scalar Pseudorotation phase (6 membered rings)
puck5.theta scalar Theta angle (6 membered rings)
puck5.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O5-5the O5 atom in residue 5. Click here for more information. ,@C1-5the C1 atom in residue 5. Click here for more information. ,@C2-5the C2 atom in residue 5. Click here for more information. ,@C3-5the C3 atom in residue 5. Click here for more information. ,@C4-5the C4 atom in residue 5. Click here for more information. ,@C5-5the C5 atom in residue 5. Click here for more information. 
puck6The PUCKERING action with label puck6 calculates the following quantities: Quantity    Type    Description  
puck6.qx scalar Cartesian component x (6 membered rings)
puck6.qy scalar Cartesian component y (6 membered rings)
puck6.qz scalar Cartesian component z (6 membered rings)
puck6.phi scalar Pseudorotation phase (6 membered rings)
puck6.theta scalar Theta angle (6 membered rings)
puck6.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O5-6the O5 atom in residue 6. Click here for more information. ,@C1-6the C1 atom in residue 6. Click here for more information. ,@C2-6the C2 atom in residue 6. Click here for more information. ,@C3-6the C3 atom in residue 6. Click here for more information. ,@C4-6the C4 atom in residue 6. Click here for more information. ,@C5-6the C5 atom in residue 6. Click here for more information. 
puck7The PUCKERING action with label puck7 calculates the following quantities: Quantity    Type    Description  
puck7.qx scalar Cartesian component x (6 membered rings)
puck7.qy scalar Cartesian component y (6 membered rings)
puck7.qz scalar Cartesian component z (6 membered rings)
puck7.phi scalar Pseudorotation phase (6 membered rings)
puck7.theta scalar Theta angle (6 membered rings)
puck7.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O6-7the O6 atom in residue 7. Click here for more information. ,@C2-7the C2 atom in residue 7. Click here for more information. ,@C3-7the C3 atom in residue 7. Click here for more information. ,@C4-7the C4 atom in residue 7. Click here for more information. ,@C5-7the C5 atom in residue 7. Click here for more information. ,@C6-7the C6 atom in residue 7. Click here for more information. 
puck8The PUCKERING action with label puck8 calculates the following quantities: Quantity    Type    Description  
puck8.qx scalar Cartesian component x (6 membered rings)
puck8.qy scalar Cartesian component y (6 membered rings)
puck8.qz scalar Cartesian component z (6 membered rings)
puck8.phi scalar Pseudorotation phase (6 membered rings)
puck8.theta scalar Theta angle (6 membered rings)
puck8.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O5-8the O5 atom in residue 8. Click here for more information. ,@C1-8the C1 atom in residue 8. Click here for more information. ,@C2-8the C2 atom in residue 8. Click here for more information. ,@C3-8the C3 atom in residue 8. Click here for more information. ,@C4-8the C4 atom in residue 8. Click here for more information. ,@C5-8the C5 atom in residue 8. Click here for more information. 
puck9The PUCKERING action with label puck9 calculates the following quantities: Quantity    Type    Description  
puck9.qx scalar Cartesian component x (6 membered rings)
puck9.qy scalar Cartesian component y (6 membered rings)
puck9.qz scalar Cartesian component z (6 membered rings)
puck9.phi scalar Pseudorotation phase (6 membered rings)
puck9.theta scalar Theta angle (6 membered rings)
puck9.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O5-9the O5 atom in residue 9. Click here for more information. ,@C1-9the C1 atom in residue 9. Click here for more information. ,@C2-9the C2 atom in residue 9. Click here for more information. ,@C3-9the C3 atom in residue 9. Click here for more information. ,@C4-9the C4 atom in residue 9. Click here for more information. ,@C5-9the C5 atom in residue 9. Click here for more information. 
puck10The PUCKERING action with label puck10 calculates the following quantities: Quantity    Type    Description  
puck10.qx scalar Cartesian component x (6 membered rings)
puck10.qy scalar Cartesian component y (6 membered rings)
puck10.qz scalar Cartesian component z (6 membered rings)
puck10.phi scalar Pseudorotation phase (6 membered rings)
puck10.theta scalar Theta angle (6 membered rings)
puck10.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O5-10the O5 atom in residue 10. Click here for more information. ,@C1-10the C1 atom in residue 10. Click here for more information. ,@C2-10the C2 atom in residue 10. Click here for more information. ,@C3-10the C3 atom in residue 10. Click here for more information. ,@C4-10the C4 atom in residue 10. Click here for more information. ,@C5-10the C5 atom in residue 10. Click here for more information. 
puck11The PUCKERING action with label puck11 calculates the following quantities: Quantity    Type    Description  
puck11.qx scalar Cartesian component x (6 membered rings)
puck11.qy scalar Cartesian component y (6 membered rings)
puck11.qz scalar Cartesian component z (6 membered rings)
puck11.phi scalar Pseudorotation phase (6 membered rings)
puck11.theta scalar Theta angle (6 membered rings)
puck11.amplitude scalar Pseudorotation amplitude (6 membered rings): PUCKERINGCalculate sugar pseudorotation coordinates. More details ATOMSthe five or six atoms of the sugar ring in the proper order=@O6-11the O6 atom in residue 11. Click here for more information. ,@C2-11the C2 atom in residue 11. Click here for more information. ,@C3-11the C3 atom in residue 11. Click here for more information. ,@C4-11the C4 atom in residue 11. Click here for more information. ,@C5-11the C5 atom in residue 11. Click here for more information. ,@C6-11the C6 atom in residue 11. Click here for more information. 
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# Define torsion angles required for J-coupling calculations
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J3_8The TORSION action with label J3_8 calculates the following quantities: Quantity    Type    Description  
J3_8 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@H5-3the H5 atom in residue 3. Click here for more information. ,@C5-3the C5 atom in residue 3. Click here for more information. ,@C6-3the C6 atom in residue 3. Click here for more information. ,@H61-3the H61 atom in residue 3. Click here for more information. 
J3_8PThe TORSION action with label J3_8P calculates the following quantities: Quantity    Type    Description  
J3_8P scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@H5-3the H5 atom in residue 3. Click here for more information. ,@C5-3the C5 atom in residue 3. Click here for more information. ,@C6-3the C6 atom in residue 3. Click here for more information. ,@H62-3the H62 atom in residue 3. Click here for more information. 
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J6_7The TORSION action with label J6_7 calculates the following quantities: Quantity    Type    Description  
J6_7 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@H5-6the H5 atom in residue 6. Click here for more information. ,@C5-6the C5 atom in residue 6. Click here for more information. ,@C6-6the C6 atom in residue 6. Click here for more information. ,@H61-6the H61 atom in residue 6. Click here for more information. 
J6_7PThe TORSION action with label J6_7P calculates the following quantities: Quantity    Type    Description  
J6_7P scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@H5-6the H5 atom in residue 6. Click here for more information. ,@C5-6the C5 atom in residue 6. Click here for more information. ,@C6-6the C6 atom in residue 6. Click here for more information. ,@H62-6the H62 atom in residue 6. Click here for more information. 
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J10_11The TORSION action with label J10_11 calculates the following quantities: Quantity    Type    Description  
J10_11 scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@H5-10the H5 atom in residue 10. Click here for more information. ,@C5-10the C5 atom in residue 10. Click here for more information. ,@C6-10the C6 atom in residue 10. Click here for more information. ,@H61-10the H61 atom in residue 10. Click here for more information. 
J10_11PThe TORSION action with label J10_11P calculates the following quantities: Quantity    Type    Description  
J10_11P scalar the TORSION involving these atoms: TORSIONCalculate one or multiple torsional angles. More details ATOMSthe four atoms involved in the torsional angle=@H5-10the H5 atom in residue 10. Click here for more information. ,@C5-10the C5 atom in residue 10. Click here for more information. ,@C6-10the C6 atom in residue 10. Click here for more information. ,@H62-10the H62 atom in residue 10. Click here for more information. 
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# Apply 1D metadynamics on each torsion angle. Different bias potentials are applied in different replicas, according to the RECT keyword. 
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metaD_phi1_2The METAD action with label metaD_phi1_2 calculates the following quantities: Quantity    Type    Description  
metaD_phi1_2.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=phi1_2 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_phi1_2
metaD_psi1_2The METAD action with label metaD_psi1_2 calculates the following quantities: Quantity    Type    Description  
metaD_psi1_2.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=psi1_2 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_psi1_2
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metaD_phi2_3The METAD action with label metaD_phi2_3 calculates the following quantities: Quantity    Type    Description  
metaD_phi2_3.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=phi2_3 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_phi2_3
metaD_psi2_3The METAD action with label metaD_psi2_3 calculates the following quantities: Quantity    Type    Description  
metaD_psi2_3.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=psi2_3 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_psi2_3
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metaD_phi3_4The METAD action with label metaD_phi3_4 calculates the following quantities: Quantity    Type    Description  
metaD_phi3_4.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=phi3_4 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_phi3_4
metaD_psi3_4The METAD action with label metaD_psi3_4 calculates the following quantities: Quantity    Type    Description  
metaD_psi3_4.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=psi3_4 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_psi3_4
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metaD_phi4_5The METAD action with label metaD_phi4_5 calculates the following quantities: Quantity    Type    Description  
metaD_phi4_5.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=phi4_5 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_phi4_5
metaD_psi4_5The METAD action with label metaD_psi4_5 calculates the following quantities: Quantity    Type    Description  
metaD_psi4_5.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=psi4_5 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_psi4_5
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metaD_phi5_6The METAD action with label metaD_phi5_6 calculates the following quantities: Quantity    Type    Description  
metaD_phi5_6.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=phi5_6 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_phi5_6
metaD_psi5_6The METAD action with label metaD_psi5_6 calculates the following quantities: Quantity    Type    Description  
metaD_psi5_6.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=psi5_6 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_psi5_6
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metaD_phi6_7The METAD action with label metaD_phi6_7 calculates the following quantities: Quantity    Type    Description  
metaD_phi6_7.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=phi6_7 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_phi6_7
metaD_psi6_7The METAD action with label metaD_psi6_7 calculates the following quantities: Quantity    Type    Description  
metaD_psi6_7.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=psi6_7 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_psi6_7
metaD_omega6_7The METAD action with label metaD_omega6_7 calculates the following quantities: Quantity    Type    Description  
metaD_omega6_7.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=omega6_7 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_omega6_7
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metaD_phi3_8The METAD action with label metaD_phi3_8 calculates the following quantities: Quantity    Type    Description  
metaD_phi3_8.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=phi3_8 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_phi3_8
metaD_psi3_8The METAD action with label metaD_psi3_8 calculates the following quantities: Quantity    Type    Description  
metaD_psi3_8.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=psi3_8 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_psi3_8
metaD_omega3_8The METAD action with label metaD_omega3_8 calculates the following quantities: Quantity    Type    Description  
metaD_omega3_8.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=omega3_8 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_omega3_8
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metaD_phi8_9The METAD action with label metaD_phi8_9 calculates the following quantities: Quantity    Type    Description  
metaD_phi8_9.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=phi8_9 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_phi8_9
metaD_psi8_9The METAD action with label metaD_psi8_9 calculates the following quantities: Quantity    Type    Description  
metaD_psi8_9.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=psi8_9 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_psi8_9
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metaD_phi9_10The METAD action with label metaD_phi9_10 calculates the following quantities: Quantity    Type    Description  
metaD_phi9_10.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=phi9_10 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_phi9_10
metaD_psi9_10The METAD action with label metaD_psi9_10 calculates the following quantities: Quantity    Type    Description  
metaD_psi9_10.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=psi9_10 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_psi9_10
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metaD_phi10_11The METAD action with label metaD_phi10_11 calculates the following quantities: Quantity    Type    Description  
metaD_phi10_11.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=phi10_11 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_phi10_11
metaD_psi10_11The METAD action with label metaD_psi10_11 calculates the following quantities: Quantity    Type    Description  
metaD_psi10_11.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=psi10_11 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_psi10_11
metaD_omega10_11The METAD action with label metaD_omega10_11 calculates the following quantities: Quantity    Type    Description  
metaD_omega10_11.bias scalar the instantaneous value of the bias potential: METADUsed to performed metadynamics on one or more collective variables. More details ARGthe labels of the scalars on which the bias will act=omega10_11 TAUin well tempered metadynamics, sets height to (k_B Delta T*pace*timestep)/tau=4.0 PACEthe frequency for hill addition=500 SIGMAthe widths of the Gaussian hills=0.35 GRID_MINthe lower bounds for the grid=-pi GRID_MAXthe upper bounds for the grid=pi GRID_BINthe number of bins for the grid=200 TEMPthe system temperature - this is only needed if you are doing well-tempered metadynamics=310.15 RECTlist of bias factors for all the replicas=1,1.2,1.46,1.82,2.3,2.94,3.78,4.89,6.34,8.23,10.7,14 FILE a file in which the list of added hills is stored=HILLS_omega10_11
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# PRINT torsion angle values and puckering coordinates to separate files
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PRINTPrint quantities to a file. More details ARGthe labels of the values that you would like to print to the file=phi1_2,psi1_2,phi2_3,psi2_3,phi3_4,psi3_4,phi4_5,psi4_5,phi5_6,psi5_6,phi6_7,psi6_7,omega6_7,phi3_8,psi3_8,omega3_8,phi8_9,psi8_9,phi9_10,psi9_10,phi10_11,psi10_11,omega10_11 STRIDE the frequency with which the quantities of interest should be output=200 FILEthe name of the file on which to output these quantities=COLVAR
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PRINTPrint quantities to a file. More details ARGthe labels of the values that you would like to print to the file=puck1.theta,puck2.theta,puck3.theta,puck4.theta,puck5.theta,puck6.theta,puck7.theta,puck8.theta,puck9.theta,puck10.theta,puck11.theta,puck1.phi,puck2.phi,puck3.phi,puck4.phi,puck5.phi,puck6.phi,puck7.phi,puck8.phi,puck9.phi,puck10.phi,puck11.phi STRIDE the frequency with which the quantities of interest should be output=200 FILEthe name of the file on which to output these quantities=COLVAR_theta
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PRINTPrint quantities to a file. More details ARGthe labels of the values that you would like to print to the file=omega3_8,J3_8,J3_8P,omega6_7,J6_7,J6_7P,omega10_11,J10_11,J10_11P STRIDE the frequency with which the quantities of interest should be output=200 FILEthe name of the file on which to output these quantities=COLVAR_NMR
Quantity	Type	Description
phi1_2	scalar	the TORSION involving these atoms
PLUMED-NEST

The public repository of the PLUMED consortium
