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[lectures/latex.git] / posic / publications / sic_prec_reply01.txt

Re: BC11912
    Combined ab initio and classical potential simulation study on the
    silicon carbide precipitation in silicon
    by F. Zirkelbach, B. Stritzker, K. Nordlund, et al.

and related to

Re: BA11443
    First-principles study of defects in carbon-implanted silicon
    by F. Zirkelbach, B. Stritzker, J. K. N. Lindner, et al.


Dear Dr. Dahal,

Thank you very much for informing us about the status of our
manuscript.

The referee

  i) has reservations about the methodology used in the present work
 ii) requests a clarification of the relation of the present
     manuscript to a previous submission of ours (BA11443)
iii) suggests to possibly combine some account of the present
     work with the previous submission BA11443.

What concerns (i), the classical potential molecular dynamics used in
the present work certainly has limitations. Precisely in order to
quantify these limitations, a comparison is made with ab initio
calculations as well as earlier first-principles work (BA11443).
Despite the shortcomings of classical potential simulations, they
nevertheless provide valuable insight in the physical mechanism of
silicon carbide precipitation on length and time scales which are not
accessible to more accurate ab initio techniques. A detailed response
to the referee's concerns is given below.

Concerning (ii) and (iii), the ab initio work BA11443 is a
self-contained and comprehensive manuscript, which already now has an
appreciable length. It is a first-principles study on defects in
carbon-implanted silicon. In contrast, the present study mainly
applies classical potentials to model the SiC precipitation in Si on
large time and length scales. While the material is the same, the
methodologies applied and the questions addressed in the present work
and in BA11443 largely differ. For this reason, and because both
manuscripts already contain a substantial amount of information, we
believe it is not in the interest of the readers to combine the two
manuscripts. Perhaps it would be good idea to make BA11443 available
to the referee of the present work? 

Please find below a reply to the comments of the referee, which we
hope will satisfactorily answer his concerns on the suitability of our
work for publication in the Physical Review B.

Sincerely,

Frank Zirkelbach



Response to the comments of the referee
---------------------------------------

> It follows on naturally from a previous paper on the carbon
> interstitial in silicon (their ref 42), but does not appear to be a
> "serial publication". However, it also refers to an (as yet)
> unpublished study (ref 60) of the same topic as the present paper
> with almost the same authors, using ab initio MD. Perhaps the
> authors could comment on how these two papers differ, and whether
> ref 60 improves on the results of the present paper in such a way
> that makes present paper superfluous.

Manuscript BA11443 (Ref. 60) entitled 'First-principles study of
defects in carbon-implanted silicon' investigates single native and C
point defects as well as their combinations in Si exclusively by first
principles calculations. In that, it constitutes a self-contained,
rather substantial study.

The present work studies the limitations of classical potentials by
means of comparison with first-principles results (and has virtually
no overlap with the results of BA11443). Based on this comparison, an
approach is proposed that allows to overcome some of the limitations
of the classical potentials as well as the general problem inherent to
MD describing phase transitions made up of a multiple of infrequent
transition events. This enables us to simulate the phase transition of
the Si structure during C insertion.

Although conclusions on the SiC precipitation in Si were already
derived in the DFT study BA11443 based on calculatiuons for single
defects and some selected combinations, the classical potential MD
simulations allow the investigation of far larger and, thus, much more
complex systems on a larger time scale, reinforcing conclusions
concerning the SiC precipitation in Si. 

There are no contradictions or improvements to the present study in
BA11443 that would make either manuscript obsolete. 

> I have some serious reservations about the methodology employed in
> this paper, for reasons that are discussed at length in it. I am not
> convinced that the measures they take to circumvent the problems in
> the method do not introduce further uncertainties, and I would need
> a bit more convincing that the results are actually valid. Actually,
> the proof I would need is probably within the simulations of ref 60,
> hence my question above! The problems I refer to are the huge
> over-estimate of the C interstitial migration energy (a process
> which is at the heart of the simulations) using the potential used
> in the paper, probably due to the short cut-off of the interactions.
> The authors' circumvention of this is to do the simulations at much
> heightened temperatures. However, this only gives a good model of
> the system if all cohesive and migration energies are over-estimated
> by a similar factor, which is demonstrably untrue in this case,
> where the C_s formation energy is actually underestimated. There are
> long discussions of these points in the paper, which leads me to the
> conclusion that the EA potential used is unreliable in these
> simulations, possibly unless backed up by some ab initio work, which
> the authors have done in ref 60.

There is not necessarily a correlation of cohesive energies or defect
formation energies with activation energies for migration. Cohesive
energies are most often well described by the classical potentials
since these are most often used to fit the potential parameters. The
overestimated barriers, however, are due to the short range character
of these potentials, which drop the interaction to zero within the
first and next neighbor distance using a special cut-off function.
Since the total binding energy is 'accommodated' within this short
distance, which according to the universal energy relation would
usually correspond to a much larger distance, unphysical high forces
between two neighbored atoms arise. This is explained in detail in the
study of Mattoni et. al. (Phys. Rev. B 76, 224103 (2007)).

Since most of the defect structures show atomic distances below the
critical distance, for which the cut-off function is taking effect,
the respective formation energies are quite well described, too (at
least they are not necessarily overestimated in the same way).

While the properties of some structures near the equilibrium position
are well described, the above mentioned effects increase for
non-equilibrium structures and dynamics. Thus, for instance, it is not
surprising that short range potentials show overestimated melting
temperatures. This is not only true for the EA but also (to an even
larger extent) for Tersoff potentials, one of the most widely used
classical potentials for the Si/C system. The fact that the melting
temperature is drastically overestimated although the cohesive
energies are nicely reproduced indicates that there is no reason why
the cohesive and formational energies should be overestimated to the
same extent in order to legitimate the increase in temperature to
appropriately consider the overestimated barrier heights for
diffusion.

Indeed, a structural transformation with increasing temperature is
observed, which can be very well explained and correlated to
experimental findings.

The underestimated energy of formation of substitutional C for the EA
potential does not pose a problem in the present context. Since we
deal with a perfect Si crystal and the number of particles is
conserved, the creation of substitutional C is accompanied by the
creation of a Si interstitial.  The formation energies of the
different structures of an additional C atom incorporated into
otherwise perfect Si shows the same ground state, i.e. the C-Si 100 DB
structure, for classical potential as well as ab initio calculations.

The arguments discussed above are now explained in more detail in the
revised version of our work. (-> Change 1, Change 2)

> Therefore, I do not feel that this paper can stand alone - either
> its conclusions are contradicted by those of ref 60 (in which case
> there's no need to publish this paper), or supported by them (in
> which case ref 60 supercedes this paper, and some brief account of
> this work could be included in it).

As mentioned above, there are no conclusions in Ref. 60 that
contradict to the results of the present manuscript. Indeed, the
results of Ref. 60 are important for the present study and, therefore,
supporting this work. However, the different approaches, i.e. modeling
thousands of C atoms incorporated into a large Si host matrix by
molecular dynamics simulations on a large time scale vs accurate
investigations of the structure of single and double defects in Si and
some selected diffusion processes, suggests the separate publication
of the results.



Summary of changes
------------------

 - = line removed
 + = line added

Change 1
--------

+
+Thus, the underestimated energy of formation of C$_{\text{s}}$ within
 the EA calculation does not pose a serious limitation in the present
 context.

+Since C is introduced into a perfect Si crystal and the number of
 particles is conserved in simulation, the creation of C$_{\text{s}}$
 is accompanied by the creation of Si$_{\text{i}}$, which is
 energetically less favorable than the ground state, i.e. the
 C$_{\text{i}}$ \hkl<1 0 0> DB configuration, for both, the EA and ab
 initio treatment.

Change 2
--------

-The cut-off function of the short range potential limits the
 interaction to nearest neighbors, which results in overestimated and
 unphysical high forces between neighbored atoms.

+The cut-off function of the short range potential limits the
 interaction to nearest neighbors.

+Since the total binding energy is, thus, accommodated within this
 short distance, which according to the universal energy relation would
 usually correspond to a much larger distance, unphysical high forces
 between two neighbored atoms arise.

+While cohesive and formational energies are often well described,
 these effects increase for non-equilibrium structures and dynamics.