Pyrolysis tar conversion

The invention claimed is: 1. A hydrocarbon process, comprising: (a) providing a first pyrolysis tar having a temperature T 1 ≤350° C., the pyrolysis tar being a hydrocarbon-containing mixture which includes free radicals and is derived from hydrocarbon pyrolysis, wherein at least 70 wt. % of the mixture has a normal boiling point of at least 290° C.; (b) isolating a sample from the first pyrolysis tar and producing additional free radicals in the sample by exposing the sample to a predetermined second temperature T 2 for a predetermined time t h , wherein T 2 ≥T 1 +10° C.; (c) cooling the sample to a temperature T 3 , T 3 being ≤T 1 , the cooled sample having a total free radical content R T ; (d) (i) when R T does not exceed a predetermined reference free radical content Rref, conducting the first pyrolysis tar to step (e); (ii) when R T exceeds R ref , (A) providing a second pyrolysis tar at a temperature ≤T 1 , the second pyrolysis tar being a hydrocarbon-containing mixture derived from hydrocarbon pyrolysis, wherein at least 70 wt. % of the mixture has a normal boiling point of at least 290° C., and combining the first pyrolysis tar with a predetermined amount of the second pyrolysis tar to produce a pyrolysis tar composition, (B) (I) isolating a sample from the pyrolysis tar composition, (II) producing additional free radicals in the pyrolysis tar composition sample by exposing the pyrolysis tar composition sample to a temperature of at least T 2 for time of at least t h , and (III) cooling the pyrolysis tar composition sample to a temperature ≤T 3 , the cooled pyrolysis tar composition sample having a total free radical content R T , and (C) when R T does not exceed R ref , either (I) conducting the pyrolysis tar composition to step (e) or (II) further increasing the amount of second pyrolysis tar in the pyrolysis tar composition and then repeating steps (d)(ii)(B) and (C); and when R T exceeds R ref , increasing the amount of the second pyrolysis tar in the pyrolysis tar composition and then repeating steps (d)(ii)(B) and (C); and (e) hydroprocessing at least a portion of the pyrolysis tar of step (d)(i) and/or the pyrolysis tar composition of step d (ii) to produce a hydroprocessed pyrolysis tar. 2. A hydrocarbon conversion process using at least first and second pyrolysis tars, each pyrolysis tar being a hydrocarbon-containing mixture derived from hydrocarbon pyrolysis, wherein at least 70 wt. % of the mixture has a normal boiling point of at least 290° C. and the mixture includes free radicals, the process comprising: (a) providing a pyrolysis tar composition at a temperature T 1 ≤350° C., the pyrolysis tar composition having an initial blend ratio (wt. % second pyrolysis tar in blend):(wt. % first pyrolysis tar in blend) equal to zero; (b) isolating a sample from the pyrolysis tar composition and producing additional free radicals in the sample by exposing the sample to a predetermined second temperature T 2 for a predetermined time t h , wherein T 2 ≥T 1 +10° C.; (c) cooling the sample to a temperature T 3 , T 3 being ≤T 1 , the cooled sample having a total free radical content R T ; (d) (i) when R T does not exceed a predetermined reference free radical content R ref , conducting the pyrolysis tar composition to step (e), and (ii) when R T exceeds R ref , (A) increasing the blend ratio of the pyrolysis tar composition and repeating steps (a), (b) and (c) until at least achieving a second blend ratio wherein R T does not exceed R ref , and (B) conducting the pyrolysis tar composition to step (e); and (e) hydroprocessing at least a portion of the pyrolysis tar composition of step (d)(i) and/or step d(ii) to produce a hydroprocessed pyrolysis tar. 3. The process of claim 1 , wherein R T , and R ref are determined by electron spin resonance, R ref =2×10 18 spins per gram, T 2 ≥440° C., t h ≥120 seconds, ≥90 wt. % of the first pyrolysis tar has a normal boiling point ≥290° C., the first pyrolysis tar has a viscosity at 15° C.≥1×10 4 cSt, and the first pyrolysis tar has a density ≥1.1 g/cm 3 . 4. The process of claim 1 , wherein ≥90 wt. % of the second pyrolysis tar has a normal boiling point ≥290° C., the second pyrolysis tar having a viscosity at 15° C.≥1×10 4 cSt and a density ≥1.1 g/cm 3 . 5. The process of claim 1 , wherein (i) the first pyrolysis tar has an S BN >135 and an I N >80, and (ii) the pyrolysis tar composition has an S BN that is at least 20 solvency units greater than the I N of the pyrolysis tar composition. 6. The process of claim 1 , wherein the hydroprocessed tar has a density measured at 15° C. that is at least 0.12 g/cm 3 less than smaller of (i) the density measured at 15° C. of the first pyrolysis tar and (ii) the density measured at 15° C. of the second pyrolysis tar. 7. The process of claim 1 , further comprising carrying out the hydroprocessing in the presence of a utility fluid having an ASTM D86 10% distillation point ≥60° C. and a 90% distillation point ≤425° C., wherein the utility fluid comprises aromatic hydrocarbon. 8. The process of claim 7 , wherein the utility fluid has a S BN ≥100. 9. The process of claim 1 , wherein the hydroprocessing is carried out in at least one hydroprocessing zone operating under hydroprocessing conditions in the presence of at least one catalyst and a treatment gas comprising molecular hydrogen to produce a hydroprocessor effluent comprising the hydroprocessed pyrolysis tar, wherein the hydroprocessing conditions include a temperature ≥200° C., a pressure ≥8 MPa and a weight hourly space velocity of the feed mixture that is ≥0.3 hr 1 . 10. The process of claim 1 , wherein the hydroprocessing conditions include a molecular hydrogen consumption rate in the range of 270 standard cubic meters of molecular hydrogen per cubic meter of (the first pyrolysis tar+the second pyrolysis tar) in the feed (S m 3 /m 3 ) to 534 S m 3 /m 3 . 11. The process of claim 1 , further comprising: (f) separating from the hydroprocessed effluent (i) a primarily vapor-phase first stream comprising at least a portion of any unreacted molecular hydrogen, (ii) a primarily liquid-phase second stream comprising at least a portion of the hydroprocessed tar, and (iii) a primarily liquid-phase third stream comprising at least a portion of any unreacted utility fluid; and (g) recycling to the hydroprocessing of step (e) at least a portion of the first stream and/or at least a portion of the third stream. 12. The process of claim 1 , wherein the hydroprocessing of step (e) exhibits a 566° C.+ conversion of at least 20 wt. % substantially continuously for at least ten days. 13. A pyrolysis tar upgrading process, comprising: (a) providing a pyrolysis tar having a temperature T 1 ≤350° C., the pyrolysis tar being a hydrocarbon-containing mixture containing free radicals and being derived from hydrocarbon pyrolysis, wherein at least 70 wt. % of the mixture has a normal boiling point of at least 290° C.; (b) isolating a sample from the pyrolysis tar product and producing additional free radicals in the sample by exposing the sample to a predetermined second temperature T 2 for a predetermined time t h , wherein T 2 ≥T 1 +10° C.; (c) cooling the sample to a temperature T 3 , T 3 being ≤T 1 , the cooled sample having a total free radical content R T ; (d) producing a feed by combining at least a portion of the pyrolysis tar with a utility fluid having an ASTM D86 10% distillation point ≥60° C. and a 90% distillation point ≤425° C., wherein the utility fluid comprises aromatic hydrocarbon; and (e) hydroprocessing the feed in at least one hydroprocessing zone under hydroprocessing conditions