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 WWW TUNL    ## 11C (2012KE01)

(See 2 [Electromagnetic Transitions in A = 11] (in PDF or PS), 11.38 (in PDF or PS), 11.39 (in PDF or PS) and Energy Level Diagram for 11C and Isobar Diagram)

μ = -0.964 ± 0.001 nm (1969WO03)

Q = 34.26 mb (1969SC34: calculated)

 1. 11C(β+)11B Qm = 1.9824

The half-life of 11C is 20.364 ± 0.014 min. The most significant measured values are 20.382 ± 0.020 (1975AZ01), 20.334 ± 0.024 (2002WO02), 20.40 ± 0.04 (1969AW02), 20.34 ± 0.04 (1964KA31) and 20.35 ± 0.08 min (1941SM11); the later value is omitted from the weighted average. Other measurements are tabulated in (1968AJ02). The decay populates the 11B ground state; log ft = 3.5921 ± 0.0019. The ratio of K-capture to positron emission is (0.230+0.014-0.011)%. See (1998BA57) for comments on Pauli principle violating anomalous atoms. See also (1995GO34, 2002WO02, 2003SU04) and (1985AJ01).

Elastic and inelastic scattering of 11C + p was measured at θcm = 20 to 50 degrees using E(11C) = 40.6 and 45.3 MeV/A beams (2003JO09). The ground state and excited states at 2.03, 4.37 and 6.47 MeV were observed. The angular distributions for 11C*(0, 4.37) were analyzed in AMD and QRPA models.

At E(11C) = 40.6 MeV/A elastic and inelastic proton scattering on 11C were measured in inverse kinematics (2005JO12). States at 11C*(0, 2.02, 4.33, 6.48) were resolved. The elastic scattering data are consistent with Rrmsmatter = 2.33 ± 0.10 fm, and a Jeukenne-Lejeune-Mahaux (JLM) microscopic potential analysis of the Ex = 4.33 MeV (5/2-) and 6.48 MeV (7/2-) state angular distributions are consistent with E2 transition multipolarities.

Also see (2003TE12, 2006PE21, 2009UM05) and 12N.

 3. 6Li(6Li, n)11C Qm = 9.4521

At E(6Li) = 4.1 MeV angular distributions have been obtained for the neutrons to 11C*(2.00, 4.32, 4.80, 6.34 + 6.48, 6.90, 7.50). In addition, nγ-coincidences via 11C*(8.42) [and an 8.42 MeV γ-ray] are reported. 11C*(8.10) was not observed. The mean lifetimes, τm, for 11C*(4.32, 6.90, 7.50) are < 140,< 69 and < 91 fs, respectively. See (1980AJ01) for references. For yields see 12C and (1987DO05).

 4. 6Li(10B, 7Be + α) Qm = -3.2875

Particle decay spectroscopy was used to study 11C*(8.10, 8.42, 8.65) which were observed in the coincident 7Be + α particle relative energy spectra (1998LE17). Upper limits for the Γα1α0 decay branching ratios for these states were found to be ≤ 0.03, ≤ 0.01 and ≤ 0.01. A comparison with Γγ values given in (1990AJ01) indicates Γα0/Γ = 0.97 ± 0.03, 0.80 ± 0.10 and ≈ 1.0 for these states, respectively. Excited states above 8.65 MeV are not observed, indicating small α decay branches.

 5. 7Li(7Li, 3n)11C Qm = -5.0501

At E(7Li) = 82 MeV no states of 11C are populated (1987AL10).

 6. 7Be(α, γ)11C Qm = 7.5436

The resonances at Eα = 0.884 ± 0.008 and 1.376 ± 0.003 MeV [11C*(8.106, 8.419)] have ωγ = 0.331 ± 0.041 and 3.80 ± 0.57 eV, Γγ = 0.350 ± 0.056 and 3.1 ± 1.3 eV, and Γα = 6+12-2 and 12.6 ± 3.8 eV, respectively (1984HA13). See also (1995DE05) for a 3-cluster-model analysis and discussion of the astrophysical importance of this reaction. Also see (1996RE16).

 7. 9Be(3He, n)11C Qm = 7.5580

Reported neutron groups are listed in 11.16 (in PDF or PS) of (1968AJ02). Angular distributions have been studied in the range E(3He) = 1.3 to 13 MeV: see (1980AJ01). The dominant L-values are 0 for 11C*(0, 8.10), 1 for 11C*(6.34, 7.50), 2 for 11C*(2.00, 4.32, 4.80, 6.48, 8.42) and 3 for 11C*(6.90). Neutron groups to T = 3/2 states have been reported at Ex = 12.17 ± 0.05 [see however reaction 38], 12.55 ± 0.05 MeV and 14.7 ± 0.1 MeV: see 11.40 (in PDF or PS).

Gamma-ray branching ratios and multipolarities for 11C levels up to Ex = 7.5 MeV have been studied by (1965OL03): see 11.39 (in PDF or PS). Together with results from reactions 16 and 28 they lead to assignments of Jπ = 1/2-, 5/2-, 3/2-, 1/2+, 7/2-, 5/2+, 3/2+ for 11C*(2.00, 4.32, 4.80, 6.34, 6.48, 6.90, 7.50): see (1965OL03) and reaction 3 in (1968AJ02) for a summary of the evidence concerning these assignments. See (1980AJ01) for references. See also 12C.

 8. (a) 9Be(11C, 11C) (b) C(11C, 11C) (c) Al(11C, 11C)

The 11C interaction cross sections on Be, C and Al targets were measured at 730 MeV/A (1995OZZZ). Also see (1996KN05).

 9. 9Be(14N, 12B) Qm = -9.8074

At E(14N) = 39.3 and 68.3 MeV/A, angular distributions and cross sections were measured and evaluated in a DWIA analysis (1997MIZO).

 10. 10B(p, γ)11C Qm = 8.6894

This reaction has been investigated for Ep = 0.07 to 17.0 MeV. Reported resonances are displayed in 11.41 (in PDF or PS). Observed capture γ-rays are displayed in 11.39 (in PDF or PS) [see also for τm measurements]. Capture measurements for Ep = 0.07 to 2.20 MeV are consistent with five resonances (see 11.39 (in PDF or PS) and 11.41 (in PDF or PS)), the lowest two (at Ep = 10 and 560 keV) of which are s-wave resonances. Thermonuclear reaction rates for T = (0.01 → 5) × 109 K are deduced from the results (1983WI09; see also for spectroscopic factors). At Ep = 100, 130 and 160 keV analyzing powers of γ0, γ2 and γ5 were measured (capture to 11C*(0, 4.319, 6.417)) (2003TO21); a TME analysis indicates that the 11C*(8.420) sub-threshold resonance influences the near threshold reaction cross sections.

The 90° yield of γ0 has been measured for Ep = 2.6 to 17 MeV and angular distributions have been obtained for Ep = 2.8 to 14 MeV. The excitation function is consistent with the giant resonance centered at Ex ≈ 16 MeV. In addition to weak structures at Ep = 4.75 MeV and 10.5 MeV, there are three major peaks at Ep = 4.1, 7.0 and 8.8 MeV (Γ = 1 to 2 MeV) [Ex = 12.4, 15.0, 16.7 MeV]. At 11C*(12.4), the γ0 angular distribution is essentially isotropic: ΓpΓγ/Γ ≈ 200 eV, Γγ ≈ 5 keV (assuming Γp ≈ 10 keV). The Ep = 4.1 MeV resonance is probably part of the E1 giant resonance and is formed by s-wave capture. At the two higher resonances the angular distributions are characteristic of E1 giant resonances in light nuclei. The 10B(p, γ1) cross section is small for Ep = 2.6 to 17 MeV: see (1980AJ01).

 11. 10B(p, n)10C Qm = -4.4303 Eb = 8.6894

The total (p, n) cross section has been measured to Ep = 10.6 MeV: broad maxima are observed at Ep = 5.92 ± 0.02, 6.68 ± 0.04, 7.33 ± 0.05 and 7.60 ± 0.05 MeV (see 11.41 (in PDF or PS)). The cross section for formation of 10Cg.s. shows a relatively smooth behavior rising up to Ep ≈ 8 MeV where a sharp maximum is observed. The cross section for production of 3.35 MeV γ-rays (from 10C*) does not appear to show structure for Ep = 8.5 to 12 MeV (1966SE03). For references see (1980AJ01). For n0 and n1 excitation curves from Ep = 13.7 to 14.7 MeV see (1985SC08). See also (1995YA12) for measurements at Ep = 186 MeV.

 12. 10B(p, p)10B Eb = 8.6894

Below Ep = 0.7 MeV the scattering can be explained in terms of pure s-wave potential scattering but the possibility of a state near Ep = 0.27 MeV (Ex = 8.95 MeV) cannot be excluded. The elastic scattering then shows two conspicuous anomalies at Ep = 1.50 ± 0.02 MeV and at 2.18 MeV [Ex = 10.05 and 10.67 MeV] with Jπ = 7/2+ and 9/2+: see 11.41 (in PDF or PS). At higher energies (to Ep = 10.5 MeV) a single broad resonance is reported at Ep ≈ 5 MeV. Polarization measurements are reported at 30.3 MeV: optical model parameters have been derived. The depolarization parameter D has been measured for polarized protons at 26 and 50 MeV. For references see (1980AJ01, 1985AJ01).

 13. 10B(p, p')10B Eb = 8.6894

The yield of γ1 [from 10B*(0.72)] rises monotonically from Ep = 1.5 to 4.1 MeV and then shows resonance behavior at Ep = 4.36 and 5.73 MeV: see 11.41 (in PDF or PS). For Ep = 6 to 12 MeV, the cross section for γ1 shows several sharp maxima superposed on a broad maximum (Γ ≈ 2.5 MeV) at Ep ≈ 7.2 MeV. See however (1975AJ02). Yields of five other γ-rays involved in the decay of 10B*(1.74, 2.16, 3.59, 5.18) have also been measured in the range Ep = 4 to 12 MeV [see (1975AJ02)].

Excitation curves for the p1, p2 and p3 groups have been measured for Ep = 3.5 to 5.0 MeV. Possible resonances are observed in the p2 yield [to the T = 1 state 10B*(1.74)] corresponding to the first T = 3/2 states at Ex = 12.16 [see however reaction 38] and 12.50 MeV [see 11.40 (in PDF or PS)]: these do not occur in the yield of p1 and p3. Yield curves for inelastically scattered protons have also been measured at Ep = 5.0 to 16.4 MeV (p1, p2, p3), 6.6 to 16.4 MeV (p4), 8.9 to 16.4 MeV (p5) and 10.9 to 16.4 MeV (p to 10B*(6.03)): the principal feature for all groups, except that to 10B*(6.03), is a structure at Ep ≈ 7.5 MeV, Γ ≈ 4 MeV. In addition narrower structures are observed, including three at Ep = 5.75, 6.90 and 7.80 MeV (± 0.2 MeV) and widths of ≈ 500 keV. For references see (1980AJ01, 1985AJ01).

 14. (a) 10B(p, d)9B Qm = -6.2125 Eb = 8.6894 (b) 10B(p, 3He)8Be Qm = -0.5332

Polarization measurements (reaction (a)) have been carried out at Ep = 49.6 MeV for the deuterons to 9B*(0, 2.36): see (1975AJ02). In reaction (b) two strong maxima are observed in the cross section at Ep ≈ 4.5 and 6.5 MeV: see 11.41 (in PDF or PS). See also (1975AJ02).

 15. 10B(p, α)7Be Qm = 1.1458 Eb = 8.6894

The total cross section for this reaction has been measured for Ep = 60 to 180 keV: the extrapolated cross section at the Gamow energy, taken to be 19.1 keV, is ≈ 10-12 b. The thick target yield for Ep = 75 keV to 3 MeV shows that the 7Be yield constitutes a potential problem if natural boron is used as fuel in CTR devices (1975PE1A).

The parameters of observed resonances are displayed in 11.41 (in PDF or PS). The ground state (α0) α-particles exhibit broad resonances at Ep = 1.17, 1.53, 2.18, 3.0, 4.4, 5.1 and 6.3 MeV. Alpha particles to 7Be*(0.43)[α1] and 0.43-MeV γ-rays exhibit all but the 1.2 MeV resonance: see (1975AJ02). A broad maximum dominates the region from Ep = 4 MeV to about 7.5 MeV. A study of the yield of 0.43 MeV γ-rays for Ep = 2.0 to 4.1 MeV suggests that the 3.0 MeV resonance, where angular distribution is asymmetric, is due to two broad states. A weak structure at Ep = 2.5 MeV is also reported. For references see (1980AJ01, 1985AJ01). See also 7Be in (2002TI10), and (1995SA52) for PIGE applications.

 16. 10B(d, n)11C Qm = 6.4648

11.42 (in PDF or PS) presents the results obtained in this reaction and in the (3He, d) reaction. Information on τm and on the γ-decay of 11C states is displayed in 11.39 (in PDF or PS): see (1968AJ02, 1975AJ02) for references. The thick target yields for 10B(d, n0) were measured for Ed = 140, 160 keV (2008ST10); cross sections were deduced and the practicality of developing a 6.3 MeV neutron source based on the 10B(d, n) reaction is discussed. In (1990MI11) cross sections were measured for Ed = 0.5 to 0.6 MeV. Production of 11C for PET is discussed in (2005VO15, 2011KI04). See also (2001HO23) and 12C.

 17. 10B(3He, d)11C Qm = 3.1959

11.42 (in PDF or PS) displays the information derived from this reaction and from the (d, n) reaction. The study of the angular distributions of the deuterons to 11C*(8.66, 8.70) shows that these levels are the analogs, respectively, of 11B*(9.19, 9.27) whose Jπ are 7/2+ and 5/2+ [the 11B states were studied in the (d, p) reaction]: Γcm are ≪ 9 keV and 15 ± 1 keV, respectively, for 11C*(8.66, 8.70): see (1975AJ02) for references.

Angular distributions of cross section were measured at E(3He) = 34 MeV, and an optical model analysis was used to extract the ANCs for 11C*(0, 4.319, 6.478) (2010AR03). The astrophysically relevant cross sections and S-factors were deduced from the ANCs. Also see (2010TI04) for a shell model analysis of ANCs for this reaction.

 18. 10B(α, t)11C Qm = -11.1245

Angular distributions have been measured at Eα = 25.1 and 56 MeV [see (1980AJ01)] and at 24.8 and 30.1 MeV (1983VA28; t0, t1).

 19. 10B(7Li, 6He)11C Qm = -1.2853

Angular distributions of 6He ions have been measured at E(7Li) = 3.0 to 3.8 MeV and at 24 MeV [to 11C*(0, 4.32, 6.48)]. 11C*(2.0, 4.80, 8.42, 8.66 + 8.70) are also populated: see (1980AJ01) for references.

 20. 11B(γ, π-) Qm = -141.5526

Pion production yields were measured at Ebrem = 0.03 to 1.2 GeV (1994OUZZ).

 21. 11B(p, n)11C Qm = -2.7648

Angular distributions for transitions including n0, n1, n2, n3, n4+5, n6, n7 have been measured up to 49.5 MeV [see (1980AJ01, 1985AJ01, 1990AJ01)]. Also see (1986MU08) Epol. p = 13 to 17 MeV, (1990SAZL) Ep = 50, 80 MeV and (1994GA49) Ep = 1 GeV. At Ep = 186 MeV, angular dependent cross sections (θ = 0 to 50 degrees) and polarization transfer coefficients, analyzing powers and induced polarization (θ = 0 to 20 degrees) were measured (1994WA22, 1994RA23, 1995YA12). The quasi-free scattering data are found to agree with a simple Fermi gas model (1994WA22). A multipole decomposition analysis of the data enabled a DWBA investigation of the ΔL = 1 transitions; peaks at Ex = 13 and 16 MeV are found to have Δ L = 0, 1 and 2 components, while a broad peak around Ex = 18 to 23 MeV is dominated by ΔL = 1 components (1995YA12).

The G-T matrix elements, which are related to the zero-degree cross sections, are discussed in (1985GR09, 1990TA15) for Ep = 16 to 26 MeV and 160 to 795 MeV, respectively. Polarization transfer coefficients are measured at Ep = 160 MeV (1990TA15) and Ep = 295 MeV (1994WAZW, 1995WA16). See also (1994SH21, 1995SH44, 2009EL09) and 12C.

 22. 11B(3He, t)11C Qm = -2.0010

Angular distributions of t0 and t1 have been measured at E(3He) = 10, 14, and 217 MeV [the latter also for the triton groups to 11C*(4.3, 4.8, 6.48, 8.10) and at E(pol. 3He) = 33 MeV; for references see (1980AJ01, 1985AJ01). At E(3He) = 26 MeV, the Ex = 6.9 to 8.7, (9.78), 10.08 to 12.15, 12.57, 12.65, 13.92 and 14.15 MeV states of 11C are populated including the possible T = 3/2 states displayed in 11.40 (in PDF or PS) (1971WA21). At E(3He) = 420 MeV (2004FU16) and 450 MeV (2004KA53, 2004KA56) the 0° cross sections for populating 11C states are related to the G-T transition strengths; see 11.43 (in PDF or PS). In (2004KA53) peaks corresponding to 11C*(11.0, 12.6, 14.7) are also observed. An AMD analysis of the Jπ = 3/23- and 5/22- states near 8 MeV deduced that the 3/2- state has a well developed cluster character with dilute density (2007KA07, 2008KA46).

 23. (a) 12C(γ, n)11C Qm = -18.7217 (b) 12C(e, e'n)11C Qm = -18.7217

For reaction (a) the fraction of transitions to the ground and to excited states of 11C [and to 11B states reached in the (γ, p) reaction] has been measured at Ebrem = 24.5, 27, 33 and 42 MeV: the ground state is predominantly populated. The population of analog states in the (γ, n) and (γ, p) reactions are similar. A significant decay strength is found to the positive-parity states with 6 < Ex < 8 MeV. In general the main contribution to the strength of the transitions to the various excited states of 11C (and 11B) lies in rather localized energy bands in 12C which are a few MeV wide (1970ME17). Measurements are reported at Ebrem = 20 MeV (1999AB39, 1999AB40, 2000AB35) and Ebrem = 58 MeV (1993AN17); see (1994RY03, 1994VAZX, 1994ZO01, 2000LE38) for comments on knockout reactions above the GDR, also see (1980AJ01, 1985AJ01) and 12C.

For reaction (b), the excitation function for n0 emission from the GDR region in 12C was measured at Ee = 126 MeV (2000OI01) and Ee = 129 MeV (1992SU12, 1997SA17, 2002TA19). See also (1991SA14, 1992DR02, 2005SA37).

For reactions producing pions see (1990AN26, 1990AR14, 1993LI21, 1994JO05, 1998GL14, 1999BA31, 1999LE35, 2000GL08, 2000SO19, 2003GL03, 2004BO47, 2005GL05, 2006CO19, 2008GL05).

 24. 12C(ν, ν'n) Qm = -18.7217

Polarization effects in neutrino-nucleus scattering reactions are discussed in (2008ME03). An analysis of superscaling applied to quasi-elastic neutrino scattering is given in (2008MA21). Discussion of the impact of (ν, ν'n) reactions on 7Li and 11B production in supernovae explosions is given in (2006SU15, 2007SU08). Influence of the nuclear strong quark component on quasi-elastic neutrino scattering is discussed in (1992GA14). Also see (2004ME18, 2004VA09, 2006ME17, 2006ME24).

 25. 12C(μ, X)11C Qm = -18.7217

A study of muon induced backgrounds in large volume scintillators measured σ(100 MeV) = 576 ± 45 μb and σ(190 MeV) = 905 ± 58 μb for production of 11C, and σ(100 MeV) < 1.22 μb and σ(190 MeV) < 2.34 μb for production of 11Be (2000HA33). See (2006BA66) for analysis of 11C production rates in Borexino and (2010AB05) for analysis of production rates in KamLAND.

 26. (a) 12C(π+, p)11C Qm = 121.6309 (b) 12C(π±, π±n)11C Qm = -18.7217

Angular distributions at Eπ+ = 49.3, 90 and 180 MeV have been obtained to 11C*(0, 2.0, 4.3 + 4.8, 6.5, 8.5). At the same momentum transfer, this reaction and the (p, d) reaction give similar intensities to the low lying states of 11C. T = 3/2 states have been suggested at Ex = 12.5 ± 0.3 and 13.3 MeV: see (1985AJ01). See also (1991KI02, 1992BA57, 1997BO15, 1999KE04). For reaction (b) 11C*(4.32)[5/2-] (and the analog state in 11B) is surprisingly strongly populated for Eπ+ = 60 to 300 MeV: see (1980AJ01, 1985AJ01).

 27. 12C(n, 2n) Qm = -18.7217

The total cross sections for (n, 2n) reactions on 12C were measured at En = 15 to 40 MeV (1996UN01), En = 20 to 50 MeV (1998KI21), and En = 22.8 to 33.6 MeV (1981AN16). Also see (1997HA21) and references in 13C (1981AJ01, 1986AJ01).

 28. 12C(p, d)11C Qm = -16.4971

Angular distributions have been measured for Ep = 19 to 800 MeV [see (1968AJ02, 1975AJ02, 1980AJ01, 1985AJ01) for references], at Ep = 45 MeV (2005KI09; to 11C*(0, 2.0, 4.3, 4.8)), at Epol. p = 497 MeV (1984OH06; d0; also Ay) and at Ep = 800 MeV (1984SM04; to 11C* (0, 2.0, 4.3, 4.8, 6.5, 8.1, 8.66 + 8.70, 9.98 ± 0.20, 10.56 ± 0.20, 13.22 ± 0.25)). In the latter experiment 11C*(8.4) and a state at 13.22 ± 0.25 MeV (Γ ≈ 2 MeV) are also reported (1984SM04). See (1991AB04) for an analysis of Cohen-Kurath wavefunctions at Ep = 30.3 MeV, and see (1998CA18) for a Glauber model analysis of Ep = 800 MeV data. States of 11C previously observed in this reaction are displayed in 11.24 (in PDF or PS) of (1980AJ01). See also 13N in (1991AJ01).

 29. 12C(p, n + p) Qm = -18.7217

At 1 GeV the separation energy between Γ ≈ 6 and 13 MeV broad 1p3/2 and 1s1/2 groups is ≈ 17 MeV (1985BE30, 1985DO16). At Ep = 200 MeV, angular distributions were evaluated in a study of the collective influence of the nuclear medium on the NN interaction (1999CA15). At Epol. p = 200 MeV, analyzing powers were measured (1999CA11). The study was evaluating the difference between free NN scattering and quasifree scattering to help improve the understanding of how the presence of a nuclear medium modifies the NN interaction.

The excitation function for 11C production via proton spallation on carbon, nitrogen and oxygen was measured for Ep = threshold to 200 MeV (2004KE05) and Ep = 60 to 250 MeV (1999CH50). Measurement of the excitation function for Ep = 95 to 200 MeV determined cross sections for clinical proton therapy applications (1993KO48). Also see (1996MA53) for Ep < 200 MeV and see 12C.

 30. 12C(d, t)11C Qm = -12.4644

At Ed = 28 MeV the t0 angular distribution was measured, and a detailed comparison has been made with the results for the mirror reaction 12C(d, 3He)11B. At Ed = 29 MeV the t0 angular distribution leads to pick-up spectroscopic factor C2S = 2.82 or 3.97 depending on different sets of parameters for 11Cg.s.; 11C*(2.0, 4.32) are also populated; see (1980AJ01). At Epol. d = 200 MeV angular distributions and analyzing powers were measured (1994VA28); a DWBA analysis deduced spectroscopic factors for 11C*(0, 2.0). See also 14N in (1986AJ01), (1980AJ01) for references.

 31. (a) 12C(3He, α)11C Qm = 1.8560 (b) 12C(3He, tp)11C Qm = -17.9579

Angular distributions have been measured at many energies to E(3He) = 217 MeV [see (1968AJ02, 1975AJ02, 1980AJ01, 1985AJ01) for references]. Observed states are displayed in 11.44 (in PDF or PS). Excitation of additional states at Ex = 11.2, 12.4, 15.3, 23, and (28) MeV has also been suggested: see (1980AJ01).

At E(3He) = 35.6 MeV DWBA analysis indicates good fits for strong l = 1 transitions, and reasonable agreement in the forward direction, as well as with Stheor, for weak l = 1 transitions. Transitions involving l = 0 or 2 (and 3) are weak and the agreement with theory is poor. It is suggested that 11C*(8.10) [3/2-] is predominantly a p3/2 hole state coupled to 12C*(7.65)[0+]: see (1980AJ01).

Alpha-γ correlations have been studied for E(3He) = 4.7 to 12 MeV. The results are summarized in 11.39 (in PDF or PS) and are discussed in detail in reaction 22 of (1968AJ02). A measurement of the linear polarization of the 2.00 MeV γ-ray (together with knowledge of the τm) fixes Jπ = 1/2- for 11C*(2.00). τm = 10.3 ± 0.7 fs for 11C*(2.00). See also 12N, and 15O in (1986AJ01).

Reaction (b) has been studied at E(3He) = 75 MeV: transitions to 11C*(0, 2.0, 4.3, 4.8, 6.3) are observed by analyzing p, t angular correlations: see (1985AJ01).

Nuclear rainbow effects are studied at E(3He) = 50 and 60 MeV (1992AD06) and at E(3He) = 98 MeV (1995DA08, 1995DA21). See (1997TE16) for applications in 12C concentration depth profiling.

 32. (a) 12C(6Li, 7Li)11C Qm = -11.4706 (b) 12C(6Li, 6He + p)11C Qm = -21.4452

The angular distributions involving 7Lig.s. + 11Cg.s. and 7Li*(0.48) + 11C*(2.00) have been studied at E(6Li) = 36 MeV: see (1980AJ01). At E(pol. 6Li) = 50 MeV polarization observables were measured for the reaction populating 11Cg.s. (1997KE04). For reaction (b) see (1992SC10, 1993SC02) and 12N.

 33. 12C(10B, 11B)11C Qm = -7.2675

At E(10B) = 100 MeV, angular distributions have been measured involving 11Bg.s. + 11Cg.s., 11Bg.s. + 11C*(2.00) and 11Cg.s. + 11B*(2.12). See (1985AJ01).

 34. 12C(12C, 13C)11C Qm = -13.7753

Angular distributions involving 11Cg.s. have been studied at E(12C) = 93.8 and 114 MeV [see (1980AJ01, 1985AJ01)], at 20 MeV/A (1985BO39), at 25, 35, and 50 MeV/A (1988WI09, 1989WI07) and at 344.5 MeV (1992JA10). The strongest peak observed is due to the unresolved 13C*(3.68 + 3.85) + 11C*(4.32) states (1988WI09, 1989WI07). The results are in agreement with the predictions of the exact FRDWBA. Above ≈ 30 MeV/A the angle-integrated cross sections fall off with an approximately exponential shape (1988WI09).

A theoretical analysis of spin polarization in nuclei following one nucleon transfer for 12C + 12C at Elab = 140 and 300 MeV is given in (1994YA01).

At E(28Si) = 13.4 GeV/A the 11C activation cross section is σ = 73.5 ± 1.4 (stat.) ± 3.5 (syst.) mb (1990WI09).

 36. 13C(γ, 2n) Qm = -23.6680

This reaction was measured at Ebrem ≈ 36 MeV in the region of the 13C GDR (1993MC02). Also see 13C in (1991AJ01).

 37. 13C(π+, d)11C Qm = 118.9091

At Eπ+ = 32 MeV angular distributions have been obtained for the deuterons to 11C*(0, 6.48): see (1985AJ01).

 38. 13C(p, t)11C Qm = -15.1862

Angular distributions have been measured for Ep = 26.9 to 65 MeV [see (1980AJ01, 1985AJ01)]. At Ep = 43.7 to 50.5 MeV the tritons have been studied to 11C*(0, 2.00, 4.32, 4.80, 6.48, 6.90, 7.50) and to a T = 3/2 state at Ex = 12.47 MeV [see 11.40 (in PDF or PS)] whose Jπ is determined to be 1/2- [it is thus the analog of 11Be*(0.32)]. The state primarily proton decays to 10B*(1.74). Alpha decay to 7Be*(0 + 0.4) is also observed. At Ep = 46.7 MeV the T = 3/2 state is also observed by (1974BE20) who, in addition, report the population of states with Ex = 11.03 ± 0.03, 13.33 ± 0.06, 13.90 ± 0.04 and 14.07 ± 0.04 MeV [Γ = 300 ± 60, 270 ± 80, 150 ± 50 and 135 ± 50 keV, respectively].

 39. (a) 14N(p, α)11C Qm = -2.9229 (b) 14N(p, pt)11C Qm = -22.7367

Angular distributions have been reported at a number of energies in the range Ep = 5.0 to 44.3 MeV for the α0 and α1 groups: see (1975AJ02, 1980AJ01). A DWBA analysis of angular distributions measured for 11C*(0, 2.0, 4.3, 4.8) at Ep = 20 to 45 MeV (2005AB17) found that the reaction proceeds mainly by the direct mechanism.

The astrophysical importance of this reaction is discussed in (1998AD12). The excitation function was evaluated as a method to produce 11C for PET applications at Ep = 5 to 25 MeV (2003TA17), and at Ep = 6 to 19 MeV (2003KO72). Also see (1990KO21, 2006TR08). For reaction (b) see (1986VDZY; Ep = 50 MeV).

 40. 14N(d, αn)11C Qm = -5.1474

The excitation function of 14N(d, αn) was measured from threshold to Ed = 12.3 MeV using activation techniques (1998SZ01).

 41. 14N(10B, 13C)11C Qm = 1.1388

This reaction has been studied at E(10B) = 100 MeV; see (1980AJ01).

 42. 16O(ν, e- + p + α) Qm = -25.6122

Cross sections for neutrino induced reactions on 16O are calculated in (2003KO50).

 43. (a) 16O(γ, 11C) (b) 181Ta(γ, 11C)

For reaction (a) γ-rays from Ebrem = 1 GeV were used to evaluate PET radioisotope production (1996BB09). For reaction (b) a 50 TWatt laser was focused on a Ta target, and the intense energy at the laser focus accelerated electrons in the target to relativistic energies; as the electrons stopped Bremsstrahlung photons were produced with energies above 10 MeV. The high energy photons induced photo-breakup reactions in the Ta and 11C ions were produced (2000LE02).

 44. (a) 16O(d, 7Li)11C Qm = -17.1587 (b) 16O(α, 9Be)11C Qm = -24.3109

At Ed = 80 MeV, angular distributions for 11C*(0, 2.0, 4.3 + 4.8, 6.3 + 6.5 + 6.9) have been measured (1978OE1A). At Eα = 42 MeV, the angular distribution involving the two ground state transitions has been measured (1972RU03).

 45. 16O(9Be, 7Be + α) Qm = -14.6024

At E(9Be) = 70 MeV 11C states at Ex = 8.65, 9.85, 10.7 and 12.1 MeV were observed in the relative energy spectrum of 7Be + α particles (2004SO19, 2004SO28, 2005SO13). There is weak evidence for peaks corresponding to 11C*(12.6, 13.4). Observation of 11C*(12.1), which is assumed to be the T = 3/2 analog of the 11Be ground state, may indicate a significant T = 1/2 isospin mixing.

Total reaction cross sections for 11C + 28Si were measured at E(11C) = 15 to 53 MeV/A (2006WA18). A Glauber model analysis was used to deduce the 11C Rrmsmatter = 2.18 ± 0.26 fm.  