Physics-based modeling of hypersonic flows is predicated on the availability of chemical reaction rate coefficients and cross sections for the collisional processes. This approach has been built around the use of quantum mechanical calculations to describe the interaction between the colliding particles. In this approach a potential energy surface (PES) is computed by solving the electronic Schrdinger equation and collision cross sections are determined for that PES using classical, semiclassical or quantum mechanical scattering methods. The rate coefficients are computed by integrating the thermally weighted cross sections. State-to-state rate coefficients are determined by only integrating over a thermal distribution of collisional energies. Finally, thermal rate coefficients are determined by summation of the state-to-state rate coefficients for reactions of molecules in all relevant ro-vibrational energy levels. If the flow is in thermal non-equilibrium, the translational, vibrational and rotational energy modes can be represented in different ways: three unique temperatures can be used to describe the distributions, the populations of individual ro-vibrational energy levels can be determined by solving the Master Equation, or through the use of direct simulation in particle-based Monte Carlo sampling. The PES-to-rate coefficient approach had been proposed and attempted in the early days of digital computing, but it is only in the last 15 years that computer hardware and software have been up to the task of calculating accurate interatomic and intermolecular potentials

Grover, Maninder

Jaffe, Richard L.

Panesi, Marco

Schwenke, David W.

Venturi, Simone

NASA Technical Reports Server

	   1	  
Comparison of quantum mechanical and empirical potential energy surfaces and 
computed rate coefficients for N2 dissociation 
 
Richard L. Jaffe1, David. W. Schwenke2, 
NASA Ames research Center, Mail Stop 230-3, Moffett Field, CA 94035-1000 
 
Simone Venturi3, Marco Panesi4, 
University of Illinois at Urbana-Champaign, Urbana, IL 61801 
and 
 
Maninder Grover5 and Thomas E. Schwartzentruber6 
University of Minnesota, Minneapolis, MN 55455 
 
 
Introduction 
 Physics-based modeling of hypersonic flows is predicated on the availability of 
chemical reaction rate coefficients and cross sections for the collisional processes. This 
approach has been built around the use of quantum mechanical calculations to describe 
the interaction between the colliding particles. In this approach a potential energy surface 
(PES) is computed by solving the electronic Schrödinger equation and collision cross 
sections are determined for that PES using classical, semiclassical or quantum 
mechanical scattering methods. The rate coefficients are computed by integrating the 
thermally weighted cross sections. State-to-state rate coefficients are determined by only 
integrating over a thermal distribution of collisional energies. Finally, thermal rate 	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  1	  Senior Research Scientist, Aerothermodynamics Branch, Mail Stop 230-3. Associate Fellow AIAA. 
richard.jaffe@nasa.gov 
2 Senior Research Scientist, NAS Applications Branch, Mail Stop 258-3 
3 Graduate Student, Department of Aerospace Engineering, University of Illinois at Urbana-Champaign, 
104 Wright St., Urbana, IL 61801. 
4 Assistant Professor, Department of Aerospace Engineering, University of Illinois at Urbana-Champaign, 
306 Talbot Lab, 104 Wright St., Urbana, IL 61801, Senior Member AIAA 
5 Graduate Student, Department of Aerospace Engineering and Mechanics, University of Minnesota, 
Minneapolis, MN 55455, Student Member AIAA 
6 Associate Professor, Department of Aerospace Engineering and Mechanics, University of Minnesota, 
Minneapolis, MN 55455 Senior Member AIAA 
https://ntrs.nasa.gov/search.jsp?R=20190027066 2019-09-26T19:08:34+00:00Z
	   2	  
coefficients are determined by summation of the state-to-state rate coefficients for 
reactions of molecules in all relevant ro-vibrational energy levels. If the flow is in 
thermal non-equilibrium, the translational, vibrational and rotational energy modes can be 
represented in different ways: three unique temperatures can be used to describe the 
distributions, the populations of individual ro-vibrational energy  levels can be 
determined by solving the Master Equation, or through the use of direct simulation in 
particle-based Monte Carlo sampling. The PES-to-rate coefficient approach had been 
proposed and attempted in the early days of digital computing, but it is only in the last 15 
years that computer hardware and software have been up to the task of calculating 
accurate interatomic and intermolecular potentials. 
 
 Recently several new “first principles” potential energy surfaces to describe ro-
vibrational energy transfer and dissociation in molecular nitrogen have become available. 
These have been computed by solving the quantum mechanical Schrödinger equation for 
the electronic energy of three or four nitrogen atoms at a large number of geometric 
arrangements. The resulting energies are fit to an analytical expression for rapid 
interpolation of the energy for any arbitrary geometry and have been used in 
quasiclassical trajectory (QCT) calculations to determine collision cross sections and 
reaction rate coefficients for inelastic and dissociative processes. Examples for N2 + N 
collisions are the PESs from NASA Ames Research Center[1-2] and from the 
Universidade de Coimbra in Portugal[3]. For N2 + N2 collisions there are PESs from 
NASA Ames[4], the University of Minnesota[5] and the University of Perugia[6].  
 
 Possibly the earliest example of a PES dates to 1931 with the empirical potential 
of Eyring and Polanyi[7] for the interaction of three hydrogen atoms, which was based on 
the theoretical Valence Bond theory treatment of London[8] for H3. This was later made 
more general by Sato’s[9,10] addition of an overlap parameter and used for QCT of 
atom-diatom exchange reactions involving hydrogen and halogen atoms. Hence the 
acronym LEPS. The H3 LEPS potential was used by Erying and others for Transition 
State Theory[11] calculations of rate coefficients and by Karplus et al. for QCT 
calculations of atom-diatom collisions[12]. Lagana et al.[13] generated a LEPS potential 
	   3	  
for N2 + N collisions that has been used by Esposito and coworkers[14] for QCT 
calculations of state-to-state N2 energy transfer and dissociation rate coefficients.  
 
 Each research group has their own recipe for devising the geometric grid, 
computing the electronic energy (i.e., the atomic orbital basis set expansion and treatment 
of electron correlation effects used in solving the electronic Schrödinger equation) and 
defining the analytic expression used to represent the PES. As a result, it is likely that 
there will be differences between the potentials and between QCT rate coefficients 
computed using each PES.  
 
 With all these potentials available for use, the obvious questions arise, such as: 
How do these PESs compare? How sensitive are QCT cross sections or rate coefficients 
to the accuracy of the PES? Most importantly, what cross sections or rate coefficients 
should be used for Discrete Simulation Monte Carlo (DSMC) and Computational Fluid 
Dynamics (CFD) flow field calculations? In this presentation comparisons will be made 
between the different PESs and between thermal and phenomenological rate coefficients 
computed using them. The most complete datasets of cross sections and rate coefficients 
have been obtained using the NASA Ames[4] and University of Minnesota[5] PESs for 
N2 + N2, so those comparisons will be the major emphasis of this proposed paper. Most 
of the rate coefficient comparisons will be made for thermal dissociation and 
rovibrational energy transfer (i.e., rovibrational relaxation)[4,15]. However, work at 
Ames[16] and Minnesota[17] have used 0-d Master Equation and Monte Carlo models to 
compute phenomenological dissociation rate coefficients, which take into account energy 
other collisional processes such as relaxation and recombination. For the proposed study, 
we will also compare these processes. As both the NASA Ames and U. Minnesota 
potentials are independent and free from empirical calibration, the results of these 
comparisons should provide validation of this aspect of the physics-based approach to 
hypersonic chemistry models. 
 
 
 
	   4	  
Results 
 
 As an example of PES comparisons, the Minnesota[5] and Ames[4] PES for 
rectangular N4 geometries are shown in Figure 1. In this arrangement, two N2 molecules 
(both with bond length r) are a distance R apart. R (in bohr) is plotted along the x-axis 
and r (in bohr) is plotted along the y-axis. Each contour line represents a constant value 
of the N4 potential energy relative to the energy of two N2 molecules at r = re and R = ∞. 
The red line represents zero energy and each successive blue line represents an increase 
in energy of 5 kcal/mol. The green line on the bottom plot is the locus of points with r = 
R (square geometries). One can see that for the two cases (NASA and Minnesota) the 
PESs are quite similar. For the low energy region around the r ≅ re and R ≥ 5 bohr, the 
channel in the NASA PES is narrower in r and shallower in R. Other small differences 
can be seen throughout the contour plots. The differences between these potentials will be 
analyzed in greater detail in the proposed paper. 
 
 Figure 2 shows a comparison of thermal rate coefficients for N2 + N → N + N + 
N. The  QCT rate coefficients from NASA[1,2] and Bari University[14] are compared 
with the experimental result of Appleton et al.[18] and the 2-temperature hypersonic 
chemistry model developed by Park[19,20] which is currently the de facto standard for 
aerothermodynamic modeling. Appleton’s shock-tube experiments were carried out for a 
temperature range of 8000 K to 15,000 K and have a published uncertainty of ± 37%. The 
NASA rate coefficients were computed for 7500 < T < 25,000 K. The Bari data were 
computed for 1000 < T < 10,000 K using the LEPS potential of Lagana et al.[13]. The 
overall agreement between Ames, Appleton and Park is quite good. The Bari data are in 
reasonable agreement with the other data sets for low temperatures, but extrapolation of 
their results to higher temperature leads to large differences. 
 
 Figure 3 shows a comparison of thermal rate coefficients for N2 + N2 → N + N + 
N2. The NASA[4] and Minnesota[15] values are compared with Appleton[18] and the 
Park 2-T model[19,20]. Again, the overall agreement between these data sets is good. We 
	   5	  
will include more detailed comparisons dissociation and energy transfer rate coefficients 
in the proposed paper. 
 
 The calculations of the potential energy surfaces and rate coefficients do not 
contain empirical parameters that can be adjusted to reproduce specific experimental 
data. The fact that there is generally good agreement between the experimental 
dissociation rate coefficients[18] and the computed QCT rate coefficients provides 
validation of the physics-based computational approach. 
  
References 
 
1. R. L. Jaffe, D. W. Schwenke, G. Chaban and W. M. Huo, “Vibrational and Rotational 
Excitation and Relaxation of Nitrogen from Accurate Theoretical Calculations,” AIAA 
2008-1208, presented at the 46th AIAA Aerospace Sciences Meeting and Exhibit, 
January 2008, Reno, Nevada. 
2. R. L. Jaffe, D. W. Schwenke, G. Chaban, “Theoretical analysis of N2 collisional 
dissociation and rotation-vibration energy transfer”, 47th AIAA Aerospace Sciences 
Meeting, Orlando, Florida, January 2009, AIAA 2009-1569. 
 
3. B. R. L. Galvao and A. J. C. Varandas, “Accurate Double Many-Body Expansion 
Potential Energy Surface for N3 (4A'') from Correlation Scaled ab Initio Energies with 
Extrapolation to the Complete Basis Set Limit”, J. Phys. Chem. A 113, 14424-14430, 
(2009). 
4. R. L. Jaffe, D. W. Schwenke, G. Chaban, “Vibrational and Rotational Excitation and 
Dissociation in N2-N2 Collisions from Accurate Theoretical Calculations”, AIAA 
Thermophysics and Heat Transfer Conference, 28 June-1 July 2010, Chicago, IL, AIAA 
2010-4517.  
5. Y. Paukku, K. R. Yang, Z. Varga, and D. G. Truhlar, “Global ab initio ground-state 
potential energy surface of N4”, J. Chem. Phys. 139, 044309 (2013); erratum ibid., 140, 
019903 (2014). 
6. L. Pacifici, M. Verdicchio, N. F. Lago, A. Lombardi and A. Costantini, “A High-Level 
Ab Initio Study of the N2 + N2 Reaction Channel”, J. Comp. Chem. 34, 266802676 
(2013). 
7. H. Eyring and M. Polanyi, Z. Phys. Chem. B. 12, 279 (1931). 
8. F. London, Z. Electrochem. 35, 552, (1929). 
9. S. Sato, “On a New Method of Drawing the Potential Energy Surface”, J. Chem. Phys. 
23, 592 (1955). 
10. S. Sato, “Potential Energy Surface of the System of Three Atoms”,	  J. Chem. Phys. 23, 
2465 (1955). 
	   6	  
11. H. Eyring, “The Activated Complex in Chemical Reactions”,J. Chem. Phys. 3, 107-
115 (1935). 
12. M. Karplus, R. N. Porter and R. D. Sharma, “Exchange reactions with activation 
energy. I. Simple barrier potential for (H, H2 )”, J. Chem. Phys. 43, 3259-3287. 
13. A. Lagana, E. Garcia, and L. Ciccarelli, “Deactivation of Vibrationally Excited 
Nitrogen Molecules by Collision with Nitrogen Atoms”, J. Phys. Chem. 91, 312-314 
(1987). 
14. F. Esposito, I. Armenise, and M. Capitelli, “N–N2 state to state vibrational-relaxation 
and dissociation rates based on quasiclassical calculations”, Chem. Phys., 331 (1), 1–8 
(2006).  
15. J. D. Bender, I.  Nompelis, P. Valentini, S. Doraiswamy, T. Schwartzentruber, and G. 
V. Candler, “Quasiclassical Trajectory Analysis of the N2 + N2 Reaction Using a New 
Ab Initio Potential Energy Surface”, 11th AIAA/ASME Joint thermophysics and heat 
Transfer Conference, Atlanta, GA, June 2014 AIAA-2014-2964.  
16. M. Panesi, R. L. Jaffe, D. W. Schwenke, and T. E. Magin, “Rovibrational internal 
energy transfer and dissociation of N2(
1Σg
+) − N(4Su) system in hypersonic flows”, J. 
Chem. Phys. 138, 044312 (2013). 
17. P. Valenti, T. E. Schwartzentruber, J. D. Bender, I.  Nompelis and  G. V. Candler, 
“Direct Simulation of rovibrational excitation and dissociation in molecular nitrogen 
using an ab initio potential energy surface”, AIAA Sci-Tech Conference, Kissimmee, FL, 
January 2015 AIAA-2015-0474. 
18. J. P. Appleton, M. Steinberg and D. J. Liquornik, “Shock-Tube Study of Nitrogen 
Dissociation using Vacuum-Ultraviolet Light Absorption”, J. Chem. Phys. 48 (2), 599-
608 (1968). 
19. C. Park, "Assessment of Two-Temperature Kinetic Model for Dissociating Weakly-
Ionizing Nitrogen," J. Thermophysics and Heat Transfer, 2 (1), 8-16 (1988). 
20. C. Park, J. T. Howe, R. L. Jaffe and G. V. Candler, Review of Chemical-Kinetic 
Problems of Future NASA Missions, II: Mars Entries”, J.Thermophysics and Heat 
Transfer, 8 (1), 9-23 (1988). 
 
 
  
	   7	  
Figures 
 
 
 
Figure 1. Comparison of the U. Minnesota[5] (top) and NASA[4] Ames (bottom) PESs 
for rectangular geometries of N4. N atoms are at the corners of a rectangle. The potential 
energies are relative to two N2 molecules with bond lengths at r = re and R = ∞. Blue and 
red lines represent constant energy contours. The red contour has zero energy and each 
successive blue line represents a 5 kcal/mol increase in energy.  
 
 
  
 1.5
 2
 2.5
 3
 3.5
 4
 2  3  4  5  6  7  8  9  10
 1.5
 2
 2.5
 3
 3.5
 4
 2  3  4  5  6  7  8  9  10
r  i
n  
b o
h r
R in bohr
arcpes from subn4dd.mod1
	   8	  
 
 
 
 
Figure 2. Thermal rate coefficients for N2 + N → N + N + N. Computed rate coefficients 
using the QCT method from NASA Ames[1,2] and Bari University[14] are compared, 
along with values from Appleton’s shock-tube experiment[18] and Park’s 2-T 
model[19,20]. The Appleton experimental data was obtained for 8000 < T < 15,000 K 
(solid line) and extrapolated to lower and higher temperatures (dashed line). 
 
 
 
1.E+08	  
1.E+10	  
1.E+12	  
1.E+14	  
1.E+16	  
0	   0.5	   1	   1.5	   2	  
Ra
te
	  C
oe
ff,
	  c
m
3/
s	  
10,000/T,	  1/K	  
QCT	  (NASA)	  Appleton	  Park	  QCT	  (Bari)	  extrap.	  
	   9	  
 
 
Figure 3. Thermal rate coefficients for N2 + N2 → N + N + N2. Computed rate 
coefficients using the QCT method from NASA Ames[4] and University of Minesota[15] 
are compared, along with values from Appleton’s shock-tube experiment[18] and Park’s 
2-T model[19,20].  
 
 
1.E+05	  
1.E+07	  
1.E+09	  
1.E+11	  
1.E+13	  
0	   0.5	   1	   1.5	   2	  
Ra
te
	  C
oe
ff,
	  c
m
3/
s	  
10,000/T,	  1/K	  
k(QCT-­‐NASA)	  k(QCT-­‐UMinn)	  k(Appleton)	  k(Park	  2-­‐T)	  


Comparison of Quantum Mechanical and Empirical Potential Energy Surfaces and Computed Rate Coefficients for N2 Dissociation

Abstract

Similar works

Full text

Available Versions

NASA Technical Reports Server