NEUTRON LIFE CYCLE DOE-HDBK-1019/2-93 Reactor Theory (Nuclear Parameters) Six  Factor  Formula With the inclusion of these last two factors it is possible to determine the fraction of neutrons that remain after every possible process in a nuclear reactor.  The effective multiplication factor (k_eff) can then be determined by the product of six terms. k_eff   =      _f p _t f h (3-3) Equation (3-3) is called the six  factor  formula.   Using this six factor formula, it is possible to trace  the  entire  neutron  life  cycle  from  production  by  fission  to  the  initiation  of  subsequent fissions.   Figure 1 illustrates a neutron life cycle with nominal values provided for each of the six factors.   Refer to Figure 1 for the remainder of the discussion on the neutron life cycle and sample  calculations.     The  generation  begins  with  1000  neutrons.     This  initial  number  is represented by N_o.  The first process is fast fission and the population has been increased by the neutrons   from   this   fast   fission   process.   From   the  definition  of  the  fast  fission  factor   it   is possible  to  calculate  its  value  based  on  the  number  of  neutrons  before  and  after  fast  fission occur. number  of  fast  neutrons  produced  by  all  fissions number  of  fast  neutrons  produced  by  thermal  fissions          1040 1000 1.04 The  total  number of  fast  neutrons  produced  by thermal  and  fast  fission  is  represented  by  the quantity N_o  . Next, it can be seen that 140 neutrons  leak from the core before reaching the thermal  energy range.   The fast non-leakage probability is calculated from its definition, as shown below. f    number  of  fast  neutrons  that  do  not  leak  from  reactor number  of  fast  neutrons  produced  by  all  fissions                   1040      140 1040 0.865 The number of neutrons that remain in the core during the slowing down process is represented by the quantity N_{o   f}. NP-03 Rev. 0 Page 10