Open Access
Table A.2
Literature and Redhead-TST desorption energies
| Moleculea | Surfaceb | Precursor(s)c | Processingd | Tpeak K | β K s−1 | Λ pm | qrot,3D | qtr,3D | vlit s−1 | Edes,lit K | vTST s−1 | Edes,red K | Reference |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| C2H4 | (P) ASW | C2H4 | No | 68 | 0.033 | 40 | 125 | 62 | 4.0E+15 | 2800 | 1.1E+16 | 2780 | Behmard et al. (2019) |
| C2H4 | Compact ASW | C2H4 | No | 60 | 0.033 | 43 | 103 | 55 | 4.0E+15 | 2400 | 7.1E+15 | 2420 | Behmard et al. (2019) |
| CH2NH | Ag | CH3NH2 | 5 keV e− | 115 | 0.008 | 30 | 201 | 109 | – | – | 5.3E+16 | 5110 | Zhu et al. (2019b) |
| (CH2-O)x | Au | H2CO:H2CO | UV | 230 | 0.067 | 21 | 426 | 226 | – | – | 4.6E+17 | 10390 | Butscher et al. (2016) |
| (CH2-O)x | Au | H2O:NH3:H2CO | Thermal | 225 | 0.067 | 21 | 412 | 221 | – | – | 4.3E+17 | 10140 | Duvernay et al. (2014) |
| C2H6 | MgF2 | CH4 | UV | 66 | 0.017 | 39 | 503 | 65 | – | 2060 | 4.5E+16 | 2840 | Carrascosa et al. (2020) |
| C2H6 | (P) ASW | C2H6 | No | 67 | 0.033 | 39 | 514 | 66 | 6.0E+16 | 3000 | 4.7E+16 | 2840 | Behmard et al. (2019) |
| C2H6 | Compact ASW | C2H6 | No | 58 | 0.033 | 42 | 414 | 57 | 6.0E+16 | 2500 | 2.9E+16 | 2420 | Behmard et al. (2019) |
| C2H6 | ASW | C2H6 | No | – | 1.000 | 0 | 0 | – | 9.5E+15 | 2490 | – | - | Smith et al. (2016) |
| C2H6 | Graphene | C2H6 | No | – | 1.000 | 0 | 0 | – | 5.1E+28 | 2980 | – | - | Smith et al. (2016) |
| C2H6 | MgO(lOO) | C2H6 | No | 75 | 0.600 | 37 | 609 | 74 | 7.9E+14 | 2670 | 7.0E+16 | 3000 | Tait et al. (2005a) |
| N2H2 | Ag | CH4:NH3 | 5 keV e− | 110 | 0.008 | 30 | 237 | 108 | – | – | 5.9E+16 | 4890 | Förstel et al. (2017) |
| CH3NH2 | Ag | CH4:NH3 | 5 keV e− | 108 | 0.008 | 30 | 827 | 110 | – | – | 2.0E+17 | 4930 | Förstel et al. (2017) |
| CH3NH2 | Cu | HCN | H | 148 | 0.083 | 26 | 1326 | 151 | – | – | 6.2E+17 | 6630 | Theulé et al. (2011) |
| CH3NH2 | Cu | CH2NH | H | 125 | 0.083 | 28 | 1029 | 127 | – | – | 3.4E+17 | 5510 | Theulé et al. (2011) |
| CH3NH2 | HOPG | CH3NH2 | No | 160 | 0.200 | 25 | 1490 | 163 | – | 7000 | 8.1E+17 | 7080 | Chaabouni et al. (2018) |
| CH3NH2 | np-ASW | CH3NH2 | No | 137 | 0.200 | 27 | 1181 | 139 | – | 4200 | 4.7E+17 | 5970 | Chaabouni et al. (2018) |
| N2H4 | Ag | CH4:NH3 | 5 keV e− | 145 | 0.008 | 26 | 957 | 152 | – | – | 4.4E+17 | 6780 | Förstel et al. (2017) |
| NH2OH | (A) silicate | NO | H | 188 | 0.017 | 22 | 1107 | 204 | 1.0E+13 | 6520 | 8.8E+17 | 8840 | Congiu et al. (2012) |
| NH2OH | (C) H2O | NO | H | 188 | 0.017 | 22 | 1107 | 204 | – | – | 8.8E+17 | 8840 | Congiu et al. (2012) |
| NH2OH | Au | NO | H | 170 | 0.083 | 23 | 952 | 184 | – | – | 6.2E+17 | 7640 | Fedoseev et al. (2016) |
| NH2OH | Au | NO:CO | H | 200 | 0.083 | 21 | 1214 | 217 | – | – | 1.1E+18 | 9140 | Fedoseev et al. (2016) |
| NH2OH | (A) Silicate | NH3:O | O | 180 | 1.000 | 23 | 1037 | 195 | – | – | 7.6E+17 | 7690 | He et al. (2015) |
| NH2OH | Rh | NH3:O2 | 5 keV e− | 191 | 0.008 | 22 | 1133 | 207 | – | – | 9.3E+17 | 9130 | Tsegaw et al. (2017) |
| NH2OH | Ag | NH3:H2O | 5 keV e− | 180 | 0.008 | 23 | 1037 | 195 | – | – | 7.6E+17 | 8550 | Zheng & Kaiser (2010) |
| NH2OH | Graphite | NO2 | H | 245 | 0.017 | 19 | 1646 | 265 | – | – | 2.2E+18 | 11810 | Ioppolo et al. (2014) |
| CH3CCH | Pt(lll) | CH3CCH | No | 138 | 4.000 | 23 | 767 | 181 | – | – | 4.0E+17 | 5580 | Peck et al. (1998) |
| CH3CCH | Ag | C2H2:NH3 | 5 keV e− | 105 | 0.017 | 27 | 509 | 138 | – | – | 1.5E+17 | 4690 | Turner et al. (2021) |
| CH3CCH | (P) ASW | C3H4 | No | 97 | 0.033 | 28 | 452 | 127 | 1.0E+19 | 4700 | 1.2E+17 | 4230 | Behmard et al. (2019) |
| CH3CCH | Compact ASW | C3H4 | No | 92 | 0.033 | 29 | 418 | 121 | 1.0E+19 | 4400 | 9.7E+16 | 3990 | Behmard et al. (2019) |
| CH3NC | α-quartz(0001) | CH3NC | No | 120 | 0.200 | 25 | 527 | 161 | 3.0E+17 | 4990 | 2.1E+17 | 5120 | Bertin et al. (2017) |
| CH3NC | α-quartz(0001) | CH3NC | No | 120 | 0.200 | 25 | 527 | 161 | 3.0E+17 | 5340 | 2.1E+17 | 5120 | Bertin et al. (2017) |
| CH3NC | ASW | CH3NC | No | 135 | 0.167 | 23 | 629 | 182 | 1.0E+18 | 6270 | 3.2E+17 | 5850 | Bertin et al. (2017) |
| CH3NC | ASW | CH3NC | No | 135 | 0.167 | 23 | 629 | 182 | 1.0E+18 | 6380 | 3.2E+17 | 5850 | Bertin et al. (2017) |
| CH3NC | (C) H2O | CH3NC | No | 138 | 0.167 | 23 | 650 | 186 | 5.0E+16 | 5690 | 3.5E+17 | 6000 | Bertin et al. (2017) |
| CH3NC | (C) H2O | CH3NC | No | 138 | 0.167 | 23 | 650 | 186 | 5.0E+16 | 5690 | 3.5E+17 | 6000 | Bertin et al. (2017) |
| HCCNH2 | Ag | C2H2:NH3 | 5 keV e− | 160 | 0.017 | 22 | 2175 | 215 | – | – | 1.6E+18 | 7590 | Turner et al. (2021) |
| c-NCHCH2 | Ag | C2H2:NH3 | 5 keV e− | 200 | 0.017 | 19 | 3862 | 269 | – | – | 4.3E+18 | 9730 | Turner et al. (2021) |
| CH2CHCH3 | (P) ASW | C3H6 | No | 86 | 0.033 | 29 | 2087 | 119 | 6.0E+18 | 4100 | 4.4E+17 | 3860 | Behmard et al. (2019) |
| CH2CHCH3 | Compact ASW | C3H6 | No | 80 | 0.033 | 30 | 1873 | 110 | 6.0E+18 | 3800 | 3.4E+17 | 3560 | Behmard et al. (2019) |
| H2CCO | Ag | CO:CH4 | 5 keV e− | 93 | 0.008 | 28 | 381 | 128 | – | – | 9.5E+16 | 4160 | Maity et al. (2014) |
| H2CCO | Ag | CH3OH | 5 keV e− | 121 | 0.008 | 24 | 566 | 167 | – | – | 2.4E+17 | 5560 | Maity et al. (2015) |
| H2CCO | Ag | CH3OH:CO | 5 keV e− | 123 | 0.008 | 24 | 580 | 169 | – | – | 2.5E+17 | 5660 | Maity et al. (2015) |
| H2CCO | Ag | H2O:CO | 5 keV e− | 95 | 0.017 | 28 | 394 | 131 | – | – | 1.0E+17 | 4200 | Turner et al. (2020) |
| HCCOH | Ag | H2O:CO | 5 keV e− | 170 | 0.017 | 21 | 1460 | 234 | – | – | 1.2E+18 | 8030 | Turner et al. (2020) |
| CH2CHNH2 | Au | C2H2:NH3 | UV | 138 | 0.083 | 23 | 3336 | 195 | – | – | 1.9E+18 | 6330 | Chuang in prep. |
| CH3CHNH | Au | C2H2:NH3 | UV | 138 | 0.083 | 23 | 3351 | 195 | – | – | 1.9E+18 | 6330 | Chuang in prep. |
| HNCO | HOPG | HNCO | H | 120 | 0.200 | 24 | 676 | 169 | 1.0E+28 | 3960 | 2.9E+17 | 5150 | Noble et al. (2015) |
| HNCO | HOPG | HNCO | H | 120 | 0.200 | 24 | 676 | 169 | 1.0E+28 | 3730 | 2.9E+17 | 5150 | Noble et al. (2015) |
| C3H8 | MgF2 | CH4 | UV | 84 | 0.017 | 29 | 3050 | 121 | – | 2580 | 6.5E+17 | 3860 | Carrascosa et al. (2020) |
| C3H8 | (P) ASW | C3H8 | No | 73 | 0.033 | 31 | 2471 | 105 | 4.0E+18 | 3500 | 4.0E+17 | 3250 | Behmard et al. (2019) |
| C3H8 | Compact ASW | C3H8 | No | 84 | 0.033 | 29 | 3050 | 121 | 4.0E+18 | 4000 | 6.5E+17 | 3800 | Behmard et al. (2019) |
| C3H8 | ASW | C3H8 | No | – | 1.000 | 0 | 0 | – | 1.1E+16 | 2840 | – | - | Smith et al. (2016) |
| C3H8 | Graphene | C3H8 | No | – | 1.000 | 0 | 0 | – | 4.2E+28 | 3750 | – | - | Smith et al. (2016) |
| C3H8 | MgO(lOO) | C3H8 | No | 93 | 0.600 | 27 | 3553 | 134 | 4.0E+15 | 3490 | 9.2E+17 | 3980 | Tait et al. (2005a) |
| CH2CHOH | Au | O2:C2H2 | H | 145 | 0.083 | 22 | 3157 | 209 | – | – | 2.0E+18 | 6660 | Chuang et al. (2020) |
| CH2CHOH | Ag | CO:CH4 | 5 keV e− | 147 | 0.008 | 22 | 3222 | 212 | – | – | 2.1E+18 | 7100 | Abplanalp et al. (2016) |
| CH2CHOH | Ag | CO:CH4 | 5 keV e− | 147 | 0.008 | 22 | 3222 | 212 | – | – | 2.1E+18 | 7100 | Zhu et al. (2022b) |
| CH3CH2NH2 | Ag | CH4:NH3 | 5 keV e− | 125 | 0.008 | 24 | 4933 | 180 | – | – | 2.3E+18 | 6030 | Förstel et al. (2017) |
| CH3CHO | Au | O2:C2H2 | H | 130 | 0.083 | 23 | 3218 | 188 | – | – | 1.6E+18 | 5930 | Chuang et al. (2020) |
| CH3CHO | Ni | CH3CHO | No | 105 | 1.210 | 26 | 2333 | 151 | 1.0E+12 | 2850 | 7.7E+17 | 4410 | Corazzi et al. (2021) |
| CH3CHO | Olivine grains | CH3CHO | No | 103 | 1.210 | 26 | 2270 | 149 | – | – | 7.2E+17 | 4320 | Corazzi et al. (2021) |
| CH3CHO | Ni | CH3CHO:H2O | No | 108 | 1.210 | 25 | 2420 | 155 | 1.0E+12 | 3080 | 8.4E+17 | 4530 | Corazzi et al. (2021) |
| CH3CHO | Olivine grains | CH3CHO:H2O | No | 108 | 1.210 | 25 | 2444 | 156 | – | – | 8.6E+17 | 4560 | Corazzi et al. (2021) |
| CH3CHO | ASW | CH3CHO | No | 100 | 0.017 | 26 | 2171 | 144 | – | 4330 | 6.5E+17 | 4610 | Lasne et al. (2012) |
| CH3CHO | Ag | CO:CH4 | 5 keV e− | 122 | 0.008 | 24 | 2926 | 176 | – | – | 1.3E+18 | 5820 | Zhu et al. (2022b) |
| N2O | (A) silicate | NO | H | 85 | 0.017 | 29 | 0 | 123 | 1.0E+13 | 2770 | – | – | Congiu et al. (2012) |
 |
Au | HCN:NH3 | Thermal | 160 | 0.083 | 21 | 7415 | 231 | – | – | 1.6E+17 | 6970 | Danger et al. (2011a) |
 |
Au | HCN:NH3:CH2NH | Thermal | 180 | 0.083 | 20 | 8848 | 260 | – | – | 1.6E+17 | 7860 | Danger et al. (2011a) |
| CH3CH2OH | Ag | CH3OH:CH4 | 5 keV e− | 147 | 0.008 | 21 | 5875 | 222 | – | – | 4.0E+18 | 7200 | Bergantim et al. (2018d) |
| CH3CH2OH | Au | CH3CHO:H | H | 160 | 0.033 | 20 | 6671 | 241 | – | – | 5.4E+18 | 7670 | Bisschop et al. (2007) |
| CH3CH2OH | HOPG | CH3CH2OH | No | 151 | 0.500 | 21 | 6116 | 228 | – | – | 4.4E+18 | 6790 | Burke et al. (2008) |
| CH3CH2OH | Au | O2:C2H2 | H | 162 | 0.083 | 20 | 6797 | 244 | – | – | 5.6E+18 | 7630 | Chuang et al. (2020) |
| CH3CH2OH | (C) H2O | CH3CH2OH | No | 169 | 0.167 | 20 | 7242 | 255 | – | – | 6.5E+18 | 7880 | Lattelais et al. (2011) |
| CH3CH2OH | HOPG | CH3CH2OH | No | 162 | 1.000 | 20 | 6797 | 244 | 2.0E+15 | 6010 | 5.6E+18 | 7230 | Ulbricht et al. (2006) |
| CH3OCH3 | Ag | CH3OH:CH4 | 5 keV e− | 135 | 0.008 | 22 | 3419 | 204 | – | – | 2.0E+18 | 6500 | Bergantim et al. (2018d) |
| CH3OCH3 | (C) H2O | CH3OCH3 | No | – | 0.167 | 0 | 0 | – | 1.0E+14 | 4080 | – | – | Lattelais et al. (2011) |
| HCOOH | Au | HCOOH | No | 145 | 0.200 | 21 | 2482 | 219 | – | – | 1.6E+18 | 6510 | Chaabouni et al. (2020) |
| HCOOH | Au | CO:O2 | H | 160 | 0.008 | 20 | 2877 | 241 | – | – | 2.3E+18 | 7760 | Ioppolo et al. (2011) |
| NO2 | (SiO)2 | NO + O | 0 | 129 | 0.083 | 23 | 676 | 195 | – | – | 3.5E+17 | 5690 | Minissale & Dulieu (2014) |
| NO2 | (SiO)2 | NO + O2 | 0 | 122 | 0.083 | 23 | 621 | 184 | – | – | 2.9E+17 | 5350 | Minissale & Dulieu (2014) |
| NO2 | (SiO)2 | NO + O3 | 0 | 125 | 0.083 | 23 | 644 | 189 | – | – | 3.2E+17 | 5500 | Minissale & Dulieu (2014) |
| NO2 | HOPG | NO2 | No | 144 | 0.500 | 21 | 797 | 217 | 6.0E+16 | 4450 | 5.2E+17 | 6170 | Ulbricht et al. (2006) |
| HOCH2NH2 | Au | H2O:NH3:H2CO | Thermal | 205 | 0.017 | 18 | 8543 | 316 | – | 6980 | 1.2E+19 | 10180 | Bossa et al. (2009a) |
| HOCH2NH2 | Au | H2CO:NH3:HCN | Thermal | 214 | 0.083 | 17 | 9112 | 330 | 3.0E+12 | 6980 | 1.3E+19 | 10330 | Danger et al. (2012) |
| HOCH2NH2 | Au | HOCH2NH2 | Thermal | 200 | 0.083 | 18 | 8233 | 308 | – | – | 1.1E+19 | 9590 | Danger et al. (2012) |
| HOCH2NH2 | Ag | CH3NH2:O2 | 5 keV e− | 210 | 0.017 | 18 | 8858 | 324 | – | – | 1.3E+19 | 10450 | Singh et al. (2022) |
| CH3OOH | Ag | CH3OH:O2 | 5 keV e− | 162 | 0.017 | 20 | 4903 | 255 | – | – | 4.2E+18 | 7850 | Zhu et al. (2022a) |
| CH3PH2 | Ag | CH4:PH3 | 5 keV e− | 102 | 0.017 | 25 | 1294 | 161 | – | – | 4.4E+17 | 4660 | Turner et al. (2016) |
| CH3SH | Au(111) | CH3SH | No | 139 | 3.000 | 21 | 2116 | 219 | 1.0E+13 | 4030 | 1.3E+18 | 5830 | Liu et al. (2002) |
| CH3SH | Au(111) | CH3SH | No | 160 | 0.240 | 20 | 2614 | 252 | – | – | 2.2E+18 | 7220 | Rzeznicka et al. (2005) |
| HOCH2OH | Au | H2O:NH3:H2CO | Thermal | 225 | 0.067 | 17 | 9052 | 354 | – | – | 1.5E+19 | 10940 | Duvernay et al. (2014) |
| HOCH2OH | Ag | CH3OH:O2 | 5 keV e− | 181 | 0.017 | 19 | 6531 | 285 | – | – | 7.0E+18 | 8880 | Zhu et al. (2022a) |
| H2POH | Ag | CO2:PH3 | 5 keV e− | 205 | 0.017 | 17 | 2433 | 336 | – | – | 3.5E+18 | 9940 | Turner et al. (2018) |
| H2POH | Ag | H2O:PH3 | 5 keV e− | 205 | 0.017 | 17 | 2433 | 336 | – | – | 3.5E+18 | 9940 | Turner et al. (2018) |
| H2POH | Ag | H2O:PH3 | 5 keV e− | 177 | 0.017 | 19 | 1952 | 290 | – | – | 2.1E+18 | 8460 | Turner et al. (2018) |
| HC2CHO | Ag | CO:C2H2 | 5 keV e− | 140 | 0.002 | 20 | 6387 | 248 | – | – | 4.6E+18 | 7090 | Abplanalp & Kaiser (2019) |
| HC2CHO | Ag | C2H2:CO | 5 keV e− | 135 | 0.002 | 20 | 6048 | 239 | – | – | 4.1E+18 | 6820 | Kleimeier et al. (2021a) |
| c-H2C3O | Ag | CO:C2H2 | 5 keV e− | 190 | 0.002 | 17 | 9994 | 337 | – | – | 1.3E+19 | 9890 | Abplanalp & Kaiser (2019) |
| c-H2C3O | Ag | C2H2:CO | 5 keV e− | 180 | 0.002 | 18 | 9215 | 319 | – | – | 1.1E+19 | 9320 | Kleimeier et al. (2021a) |
| CH2CHCHO | Ag | CO:C2H4 | 5 keV e− | 140 | 0.008 | 20 | 7896 | 257 | – | – | 5.9E+18 | 6900 | Abplanalp et al. (2015) |
| CH2CHCHO | Ag(111) | CH2CHCHO | No | 164 | 1.000 | 18 | 10011 | 301 | – | – | 1.0E+19 | 7420 | Muir et al. (2020) |
| NH2CH2CN | Au | HCN:NH3:NHCH2 | Thermal | 185 | 0.083 | 17 | 15275 | 340 | – | – | 2.0E+19 | 8970 | Danger et al. (2011a) |
| NH2CH2CN | Au | CH3CN:NH3 | UV | 205 | 0.067 | 16 | 17818 | 377 | – | – | 2.9E+19 | 10080 | Danger et al. (2011b) |
| c-C3H4O | Ag | CO:C2H4 | 5 keV e− | 110 | 0.008 | 22 | 6220 | 202 | – | – | 2.9E+18 | 5320 | Abplanalp et al. (2015) |
| CH3NCO | Au | CH4:HNCO | UV | 145 | 0.083 | 19 | 8334 | 271 | – | – | 6.8E+18 | 6840 | Ligterink et al. (2017) |
| HOCH2CN | Au | H2CO:NH3:HCN | Thermal | 214 | 0.083 | 16 | 17898 | 400 | 3.0E+12 | 6980 | 3.2E+19 | 10510 | Danger et al. (2012) |
| HOCH2CN | Au | HCN:H2CO:H2O | Thermal | 208 | 0.067 | 16 | 17151 | 389 | – | – | 2.9E+19 | 10240 | Danger et al. (2014) |
| C4H10 | Al2O3(0001) | C4H10 | No | – | – | 0 | 0 | – | 4.0E+10 | 4230 | – | – | Slayton et al. (1995) |
| C4H10 | MgO(100) | C4H10 | No | 110 | 0.600 | 22 | 11628 | 209 | 5.0E+15 | 4200 | 5.6E+18 | 4920 | Tait et al. (2005b) |
| C4H10 | MgO(100) | C4H10 | No | 111 | 0.600 | 22 | 11787 | 211 | 5.0E+15 | 4200 | 5.8E+18 | 4970 | Tait et al. (2005a) |
| CH2CHCH2OH | Pd(111) | CH3CH2CHO | No | 200 | 0.017 | 16 | 20780 | 381 | – | 6010 | 3.3E+19 | 10140 | Dostert et al. (2016) |
| CH3CH2CHO | Ag(111) | CH3CH2CHO | No | 162 | 1.000 | 18 | 15542 | 308 | – | – | 1.6E+19 | 7400 | Muir et al. (2020) |
| CH3CH2CHO | Au | C2H2:CO | H | 125 | 0.083 | 21 | 10534 | 238 | – | – | 6.5E+18 | 5870 | Qasim et al. (2019) |
| CH3CH2CHO | Ag | CO:CH3CH3 | 5 keV e− | 127 | 0.008 | 20 | 10788 | 242 | – | – | 6.9E+18 | 6270 | Abplanalp et al. (2016) |
| CH3CH2CHO | Ag | P:C:E | 5 keV e− | 120 | 0.008 | 21 | 9908 | 228 | – | – | 5.7E+18 | 5890 | Abplanalp et al. (2016) |
| CH3CHCH2O | Ag | CO2:C3H6 | 5 keV e− | 117 | 0.008 | 21 | 8139 | 223 | – | – | 4.4E+18 | 5710 | Bergantim et al. (2018b) |
| CH3CHCHOH | Ag | CO:CH3CH3 | 5 keV e− | 165 | 0.008 | 18 | 14991 | 314 | – | – | 1.6E+19 | 8330 | Abplanalp et al. (2016) |
| CH3COCH3 | ASW | CH3C(O)CH3 | No | 130 | 0.017 | 20 | 11159 | 247 | – | 4690 | 7.5E+18 | 6340 | Lasne et al. (2012) |
| CH3COCH3 | (C) H2O | CH3C(O)CH3 | No | 140 | 5.000 | 19 | 12471 | 266 | 1.0E+13 | 4210 | 9.7E+18 | 6080 | Schaff & Roberts (1994) |
| CH3COCH3 | ASW | CH3C(O)CH3 | No | 157 | 5.000 | 18 | 14811 | 299 | 1.0E+13 | 4810 | 1.4E+19 | 6900 | Schaff & Roberts (1994) |
| CH3COCH3 | ASW | CH3C(O)CH3 | No | 157 | 4.500 | 18 | 14811 | 299 | 1.0E+13 | 4690 | 1.4E+19 | 6910 | Schaff & Roberts (1998) |
| CH3COCH3 | (P) ASW | CH3C(O)CH3 | No | 145 | 0.083 | 19 | 13145 | 276 | – | – | 1.1E+19 | 6910 | Souda (2011) |
| CH3COCH3 | non-(P) ASW | CH3C(O)CH3 | No | 120 | 0.083 | 21 | 9897 | 228 | – | – | 5.7E+18 | 5620 | Souda (2011) |
| CH2CH(OH)CH3 | Ag(lll) | CH2CH(OH)CH3 | No | 202 | 1.000 | 16 | 20048 | 391 | – | – | 3.3E+19 | 9420 | Muir et al. (2020) |
| CH3CONH2 | Au | NH2CH(CH3)OH | UV | 220 | 0.067 | 15 | 21555 | 426 | – | – | 4.2E+19 | 10920 | Duvernay et al. (2010) |
| CH3CONH2 | Au | HNCO:CH4 | UV | 215 | 0.083 | 16 | 20825 | 416 | – | – | 3.9E+19 | 10600 | Ligterink et al. (2018a) |
| CH3NHCHO | Au | CH3NH2:CO | UV | 200 | 0.067 | 16 | 15173 | 387 | – | – | 2.4E+19 | 9800 | Bossa et al. (2012) |
| CH3NHCHO | Ag | CH3NH2:CO | 5 keV e− | 225 | 0.008 | 15 | 18105 | 436 | – | – | 3.7E+19 | 11610 | Frigge et al. (2018b) |
| CH3OCH2CH3 | Ag | H2O:CH4 | 5 keV e− | 170 | 0.008 | 17 | 18173 | 329 | – | – | 2.1E+19 | 8630 | Bergantim et al. (2018c) |
| (CH2NH2)2 | Ag | CH3NH2 | 5 keV e− | 160 | 0.008 | 18 | 17907 | 315 | – | – | 1.9E+19 | 8100 | Zhu et al. (2019b) |
| (CHO)2 | Ag | CH3OH:CO | 5 keV e− | 145 | 0.008 | 19 | 7227 | 285 | – | – | 6.2E+18 | 7160 | Maity et al. (2015) |
| CH3CH2CH2OH | Ag(111) | CH3CH2CH2OH | No | 219 | 1.000 | 15 | 29470 | 431 | – | – | 5.8E+19 | 10350 | Muir et al. (2020) |
| CH3CH2CH2OH | Au | CH3CH2CHO | H | 155 | 0.083 | 18 | 17548 | 305 | – | – | 1.7E+19 | 7470 | Qasim et al. (2019) |
| CH3COOH | Ag | CH4:CO2 | 5 keV e− | 165 | 0.017 | 18 | 13305 | 325 | – | – | 1.5E+19 | 8200 | Bergantim et al. (2018a) |
| CH3COOH | ASW | CH3COOH | No | 157 | 0.017 | 18 | 12349 | 309 | 1.0E+00 | – | 1.2E+19 | 7770 | Bertin et al. (2011) |
| CH3COOH | HOPG | CH3COOH | No | 155 | 0.500 | 18 | 12114 | 305 | – | – | 1.2E+19 | 7130 | Burke et al. (2015b) |
| CH3COOH | (C) H2O | CH3COOH | No | 160 | 0.500 | 18 | 12705 | 315 | – | – | 1.3E+19 | 7390 | Burke et al. (2015c) |
| CH3COOH | (C) H2O | CH3COOH | No | 160 | 0.017 | 18 | 12705 | 315 | – | – | 1.3E+19 | 7930 | Lattelais et al. (2011) |
| CH3COOH | Ag | CH4:CO2 | 5 keV e− | 155 | 0.017 | 18 | 12114 | 305 | – | – | 1.2E+19 | 7660 | Zhu et al. (2018b) |
| CH3OCHO | ASW | CH3OCHO | No | 128 | 0.017 | 20 | 6717 | 252 | 1.0E+14 | 4450 | 4.5E+18 | 6180 | Bertin et al. (2011) |
| CH3OCHO | (C) H2O | CH3OCHO | No | 129 | 0.017 | 20 | 6795 | 254 | 1.0E+14 | 4570 | 4.6E+18 | 6230 | Bertin et al. (2011) |
| CH3OCHO | HOPG | CH3OCHO | No | 104 | 0.500 | 22 | 4919 | 205 | – | 2160 | 2.2E+18 | 4570 | Burke et al. (2015b) |
| CH3OCHO | HOPG | CH3OCHO | No | 104 | 0.500 | 22 | 4919 | 205 | – | 3320 | 2.2E+18 | 4570 | Burke et al. (2015b) |
| CH3OCHO | HOPG | CH3OCHO | No | 104 | 0.500 | 22 | 4919 | 205 | – | 3910 | 2.2E+18 | 4570 | Burke et al. (2015b) |
| CH3OCHO | HOPG | CH3OCHO | No | 104 | 0.500 | 22 | 4919 | 205 | – | 4140 | 2.2E+18 | 4570 | Burke et al. (2015b) |
| CH3OCHO | ASW | CH3OCHO | No | 127 | 0.500 | 20 | 6638 | 250 | – | 4410 | 4.4E+18 | 5690 | Burke et al. (2015c) |
| CH3OCHO | (C) H2O | CH3OCHO | No | 127 | 0.500 | 20 | 6638 | 250 | – | 4620 | 4.4E+18 | 5690 | Burke et al. (2015c) |
| CH3OCHO | (C) H2O | CH3OCHO | No | 127 | 0.017 | 20 | 6638 | 250 | 1.0E+14 | 4480 | 4.4E+18 | 6120 | Lattelais et al. (2011) |
| CH3OCHO | Ag(111) | CH3OCHO | No | 144 | 1.500 | 19 | 8015 | 283 | – | 4450 | 6.8E+18 | 6380 | Schwaner et al. (1997) |
| CH3OCHO | Ag(111) | CH3OCHO | No | 160 | 1.500 | 18 | 9387 | 315 | – | – | 9.9E+18 | 7160 | Schwaner et al. (1997) |
| CH3OCHO | Cu(111) | CH3OCHO | No | 155 | 2.000 | 18 | 8950 | 305 | – | – | 8.8E+18 | 6870 | Sexton et al. (1985) |
| CH3OCHO | Ni(111) | CH3OCHO | No | 142 | 0.500 | 19 | 7848 | 280 | – | – | 6.5E+18 | 6440 | Zahidi et al. (1994) |
| CH3OCHO | Mo(110) | CH3OH | 20/1 keV e− | 105 | 0.017 | 22 | 4990 | 207 | – | – | 2.3E+18 | 4970 | Sullivan et al. (2016) |
| H2CC(OH)2 | Ag | CO2:CH4 | 5 keV e− | 215 | 0.017 | 15 | 18061 | 423 | – | – | 3.4E+19 | 10920 | Kleimeier & Kaiser (2021) |
| H2CC(OH)2 | Ag | CH3OH | 5 keV e− | 210 | 0.008 | 16 | 17435 | 413 | – | – | 3.2E+19 | 10790 | Maity et al. (2015) |
| H2CC(OH)2 | Ag | CH3OH:CO | 5 keV e− | 218 | 0.008 | 15 | 18440 | 429 | – | – | 3.6E+19 | 11240 | Maity et al. (2015) |
| HOCH2CHO | HOPG | HOCH2CHO | No | 145 | 0.500 | 19 | 11502 | 285 | – | – | 9.9E+18 | 6640 | Burke et al. (2015b) |
| HOCH2CHO | ASW | HOCH2CHO | No | 160 | 0.500 | 18 | 13332 | 315 | – | – | 1.4E+19 | 7390 | Burke et al. (2015c) |
| HOCH2CHO | (C) H2O | HOCH2CHO | No | 160 | 0.500 | 18 | 13332 | 315 | – | – | 1.4E+19 | 7390 | Burke et al. (2015c) |
| HOCH2CHO | Au | H2CO:H2CO | UV | 200 | 0.067 | 16 | 18632 | 394 | – | – | 3.1E+19 | 9850 | Butscher et al. (2016) |
| HOCH2CHO | Ag | CH3OH | 5 keV e− | 166 | 0.008 | 17 | 14089 | 327 | – | – | 1.6E+19 | 8380 | Maity et al. (2014) |
| HOCH2CHO | Mo(110) | CH3OH | 1k eV e− | 145 | 0.017 | 19 | 11502 | 285 | – | – | 9.9E+18 | 7130 | Sullivan et al. (2016) |
| HOCHCHOH | Ag | CH3OH | 5 keV e− | 210 | 0.008 | 16 | 14261 | 413 | – | – | 2.6E+19 | 10750 | Kleimeier et al. (2021b) |
| HOCHCHOH | Ag | CH3OH | 5 keV e− | 225 | 0.008 | 15 | 15816 | 443 | – | – | 3.3E+19 | 11590 | Kleimeier et al. (2021b) |
| HOCHCHOH | Ag | CH3OH:CO | 5 keV e− | 198 | 0.008 | 16 | 13056 | 390 | – | – | 2.1E+19 | 10080 | Kleimeier et al. (2021b) |
| HOCHCHOH | Ag | CH3OH:CO | 5 keV e− | 217 | 0.008 | 15 | 14980 | 427 | – | – | 2.9E+19 | 11140 | Kleimeier et al. (2021b) |
| HOCHCHOH | Ag | CH3OH | 5 keV e− | 210 | 0.008 | 16 | 14261 | 413 | 1.0E+00 | – | 2.6E+19 | 10750 | Maity et al. (2014) |
| HOCHCHOH | Ag | CH3OH:CO | 5 keV e− | 218 | 0.008 | 15 | 15083 | 429 | 2.0E+00 | – | 2.9E+19 | 11200 | Maity et al. (2014) |
| NH2CONH2 | Ag | CO:NH3 | 5 keV e− | 250 | 0.008 | 14 | 11337 | 492 | – | – | 2.9E+19 | 12870 | Förstel et al. (2016a) |
| NH2CONH2 | Ag | CO:NH3 | 5 keV e− | 260 | 0.008 | 14 | 12024 | 512 | – | – | 3.3E+19 | 13430 | Förstel et al. (2016b) |
| NH2CONH2 | Au | HNCO:CH4 | UV | 267 | 0.083 | 14 | 12512 | 526 | – | – | 3.7E+19 | 13210 | Ligterink et al. (2018a) |
| NH2CONH2 | KBr | H2O:NH3:CO2 | UV | 270 | 0.033 | 14 | 12724 | 532 | – | – | 3.8E+19 | 13620 | Potapov et al. (2022) |
| OCS | HOPG | CS2:0 | O | 78 | 0.017 | 26 | 0 | 154 | 5.3E+14 | 2430 | – | – | Ward et al. (2012) |
 |
Au | CO:N2 | H/N | 185 | 0.083 | 17 | 0 | 364 | – | – | 2.9E+17 | 8190 | Fedoseev et al. (2015b) |
 |
Au | NO:CO | UV/H | 160 | 0.083 | 18 | 0 | 315 | – | – | 2.9E+17 | 7060 | Fedoseev et al. (2016) |
 |
Au | HNCO:CH4 | UV | 205 | 0.083 | 16 | 0 | 404 | – | – | 2.9E+17 | 9100 | Ligterink et al. (2018a) |
| c-C3H2O | Ag | CO:C2H2 | UV | 177 | 0.008 | 17 | 4493 | 348 | – | – | 5.8E+18 | 8770 | Wang et al. (2022a) |
| NH2CH(CH3)OH | Au | NH3:CH3CHO | Thermal | 200 | 0.067 | 16 | 25103 | 400 | – | – | 4.2E+19 | 9910 | Duvernay et al. (2010) |
| NH2COOH | Au | CO,:NH3 | Thermal | 265 | 0.083 | 14 | 23435 | 530 | 1.0E+13 | 9150 | 6.9E+19 | 13280 | Noble et al. (2014) |
| [H3O+][OCN−] | Cu | HNCO:H2O | No | 155 | 0.017 | 18 | 0 | 310 | 2.9E+12 | 4810 | 3.0E+17 | 7090 | Theulé et al. (2011) |
| (CH2OH)2 | Ag | CH3OH:CH4 | 5 keV e− | 195 | 0.008 | 16 | 22980 | 397 | – | – | 3.7E+19 | 10040 | Bergantim et al. (2018d) |
| (CH2OH)2 | Au | H2CO:H2CO | UV | 212 | 0.067 | 15 | 26050 | 431 | – | – | 5.0E+19 | 10550 | Butscher et al. (2016) |
| (CH2OH)2 | Au | CO+H | H | 200 | 0.083 | 16 | 23870 | 407 | – | – | 4.0E+19 | 9860 | Fedoseev et al. (2015a) |
| (CH2OH)2 | Au | HOCH2CHO:CO | H | 200 | 0.333 | 16 | 23870 | 407 | – | – | 4.0E+19 | 9580 | Fedoseev et al. (2017) |
| (CH2OH)2 | Rh | HOCH2CHO | H | 214 | 0.017 | 15 | 26420 | 435 | – | – | 5.1E+19 | 10960 | Leroux et al. (2021) |
| (CH2OH)2 | Ag | CH3OH | 5 keV e− | 200 | 0.008 | 16 | 23870 | 407 | – | – | 4.0E+19 | 10320 | Maity et al. (2014) |
| (CH2OH)2 | Ag | CH3OH:CO | 5 keV e− | 198 | 0.008 | 16 | 23513 | 403 | – | – | 3.9E+19 | 10210 | Maity et al. (2014) |
| (CH2OH)2 | Ag | CH3OH | 5 keV e− | 198 | 0.008 | 16 | 23513 | 403 | – | – | 3.9E+19 | 10210 | Maity et al. (2015) |
| (CH2OH)2 | Ag | CH3OH:CO | 5 keV e− | 198 | 0.008 | 16 | 23513 | 403 | – | – | 3.9E+19 | 10210 | Maity et al. (2015) |
| CH3OCH2OH | Ag | CH3OH:CH4 | 5 keV e− | 162 | 0.008 | 17 | 15000 | 330 | – | – | 1.7E+19 | 8180 | Bergantim et al. (2018d) |
| CH3OCH2OH | Mo(110) | CH3OH | 20 eV e− | 165 | 0.017 | 17 | 15419 | 336 | – | – | 1.8E+19 | 8230 | Boamah et al. (2014) |
| CH3OCH2OH | Ag | CH3OH | 5 keV e− | 170 | 0.008 | 17 | 16125 | 346 | – | – | 2.0E+19 | 8620 | Maity et al. (2015) |
| CH3OCH2OH | Ag | CH3OH:CO | 5 keV e− | 184 | 0.008 | 16 | 18157 | 374 | – | – | 2.6E+19 | 9400 | Maity et al. (2015) |
| CH3OCH2OH | Ta(110) | CH3OH | UV | 155 | 0.017 | 18 | 14038 | 315 | – | – | 1.4E+19 | 7690 | Schneider et al. (2019) |
| CH3OCH2OH | Ag | CH3OH | 5 keV e− | 161 | 0.008 | 17 | 14861 | 328 | – | – | 1.6E+19 | 8130 | Zhu et al. (2019a) |
| CH3OCH2OH | Mo(110) | CH3OH | 1keV e− | 180 | 0.017 | 17 | 17568 | 366 | – | – | 2.4E+19 | 9050 | Sullivan et al. (2016) |
| CH3OOCH3 | Ag | CH3OH:CH4 | 5 keV e− | 113 | 0.008 | 21 | 7590 | 230 | – | – | 4.1E+18 | 5510 | Bergantim et al. (2018d) |
| CH3OOCH3 | Ag | CH3OH | 5 keV e− | 115 | 0.008 | 21 | 7792 | 234 | – | – | 4.4E+18 | 5610 | Zhu et al. (2019a) |
| CH3SCH3 | ? | H2S:CH3OH:NH3:H2O | 10 keV e− | 290 | 0.008 | 13 | 29827 | 590 | – | – | 1.1E+20 | 15350 | Mahjoub et al. (2017) |
| H2CO3 | Ag | H2O:CO2 | 5 keV e− | 245 | 0.017 | 14 | 22261 | 498 | – | – | 5.7E+19 | 12600 | Jones et al. (2014) |
| H2CO3 | Al | OH:H:O:CO | OH | 235 | 0.067 | 14 | 20912 | 478 | – | – | 4.9E+19 | 11720 | Oba et al. (2010) |
| HCOPH2 | Ag | PH3:CO | 5 keV e− | 125 | 0.017 | 20 | 5629 | 254 | – | – | 3.7E+18 | 6010 | Frigge et al. (2018a) |
| HCOSH | Rh | CO:H2S | 5 keV e− | 131 | 0.017 | 19 | 5157 | 266 | – | – | 3.8E+18 | 6300 | Wang et al. (2022b) |
 |
CsI | NH3:HCOOH | No | 203 | 0.083 | 15 | 0 | 420 | – | – | 2.0E+18 | 9400 | Bergner et al. (2016) |
 |
Au | HCOOH:NH3 | No | 208 | 0.200 | 15 | 0 | 430 | 7.7E+15 | 8290 | 2.0E+18 | 9450 | Kruczkiewicz et al. (2021) |
| SO2 | Au(111) | SO2 | No | 142 | 3.000 | 18 | 0 | 298 | – | 3920 | – | – | Liu et al. (2002) |
| H2P(O)OH | Ag | CO2:PH3 | 5 keV e− | 290 | 0.017 | 13 | 21057 | 628 | – | – | 8.0E+19 | 15070 | Turner et al. (2018) |
| H2P(O)OH | Ag | H2O:PH3 | 5 keV e− | 295 | 0.017 | 13 | 21604 | 639 | – | – | 8.5E+19 | 15350 | Turner et al. (2018) |
| H2S2 | ? | H2S | UV | 138 | 0.023 | 18 | 3315 | 299 | – | – | 2.8E+18 | 6560 | Jimenez-Escobar & Muñoz Caro (2011) |
| H2SO2 | ? | H2S:H2O | UV | 106 | 0.017 | 21 | 5052 | 230 | – | – | 2.6E+18 | 5040 | Jimenez-Escobar & Muñoz Caro (2011) |
| P2H4 | Ag | CH4:PH3 | 5 keV e− | 130 | 0.017 | 19 | 2897 | 282 | – | – | 2.2E+18 | 6180 | Turner et al. (2016) |
| CH2OCHCN | HOPG | C2H3CN | O | 145 | 0.017 | 17 | 18968 | 328 | – | – | 1.9E+19 | 7220 | Kimber et al. (2018) |
| CH2OCHCN | HOPG | C2H3CN | O | 177 | 0.017 | 16 | 25582 | 401 | – | – | 3.8E+19 | 8980 | Kimber et al. (2018) |
| CH3COCN | HOPG | C2H3CN | O | 145 | 0.017 | 17 | 22310 | 328 | – | – | 2.2E+19 | 7250 | Kimber et al. (2018) |
| CH3COCN | HOPG | C2H3CN | O | 177 | 0.017 | 16 | 30089 | 401 | – | – | 4.4E+19 | 9000 | Kimber et al. (2018) |
| CHOCH2CN | HOPG | C2H3CN | O | 145 | 0.017 | 17 | 18968 | 328 | – | – | 1.9E+19 | 7220 | Kimber et al. (2018) |
| CHOCH2CN | HOPG | C2H3CN | O | 177 | 0.017 | 16 | 25582 | 401 | – | – | 3.8E+19 | 8980 | Kimber et al. (2018) |
| H3SiC(H)CO | Rh | SiH4:CO | 5 keV e− | 130 | 0.008 | 18 | 9491 | 307 | – | – | 7.9E+18 | 6440 | Tarczay et al. (2017) |
| (CH3)2NCHO | HOPG | (CH3)2NCHO | No | 186 | 1.000 | 15 | 38565 | 445 | 1.0E+14 | 6370 | 6.7E+19 | 8780 | Ulbricht et al. (2006) |
| CH3C(O)OCH3 | Ni(111) | CH3C(O)OCH3 | No | 165 | 0.500 | 16 | 29623 | 401 | – | – | 4.1E+19 | 7810 | Zahidi et al. (1994) |
| CH3CH2OCHO | HOPG | CH3CH2OCHO | No | 120 | 0.500 | 19 | 18004 | 291 | 4.2E+20 | 5200 | 1.3E+19 | 5500 | Salter et al. (2019) |
| CH3CH2OCHO | ASW | CH3CH2OCHO | No | 134 | 0.500 | 18 | 21245 | 325 | 1.0E+16 | 5830 | 1.9E+19 | 6210 | Salter et al. (2019) |
| CH3CH2OCHO | CH3CH2OH | CH3CH2OCHO | No | 116 | 0.500 | 19 | 17111 | 282 | – | – | 1.2E+19 | 5300 | Salter et al. (2019) |
| CH3CH2OCHO | Ni(111) | CH3CH2OCHO | No | 136 | 0.500 | 17 | 21722 | 330 | – | – | 2.0E+19 | 6310 | Zahidi et al. (1994) |
| HCOCOOH | Ag | H2O:CO | 5 keV e− | 210 | 0.017 | 14 | 35060 | 510 | – | – | 7.8E+19 | 10840 | Eckhardt et al. (2019) |
 |
Au | HNCO:CH4 | UV | 214 | 0.083 | 14 | 0 | 520 | – | – | 6.8E+17 | 9690 | Ligterink et al. (2018a) |
| HC5N | ASW | HC5N | No | 150 | 0.012 | 16 | 0 | 369 | 1.0E+13 | 10820 | – | – | Coupeaud et al. (2008) |
| NH2CH2COOH | Au | CO:CH3NH2:O2 | H | 245 | 0.083 | 13 | 55385 | 603 | – | – | 1.7E+20 | 12480 | Ioppolo et al. (2021) |
| NH2CH2COOH | Αl2O3 | NH2CH2COOH | No | 310 | 1.000 | 11 | 78829 | 763 | – | – | 3.9E+20 | 15350 | Tzvetkov et al. (2004b) |
| NH2CH2COOH | ASW / LDA | NH2CH2COOH | No | 310 | 1.000 | 11 | 78829 | 763 | – | – | 3.9E+20 | 15350 | Tzvetkov et al. (2004a) |
| CH3CH2CH2SH | Au(111) | CH3CH2CH2SH | No | 205 | 0.240 | 14 | 43957 | 511 | – | – | 9.6E+19 | 10070 | Rzeznicka et al. (2005) |
| CH3OCOOH | Ag | CO2:CH3OH | 5 keV e− | 195 | 0.008 | 14 | 33355 | 486 | – | – | 6.6E+19 | 10150 | Marks et al. (2023) |
| HOCH2COOH | Mo(110) | CH3OH | 20 eV e− | 235 | 0.017 | 13 | 51211 | 586 | – | – | 1.5E+20 | 12300 | Boamah et al. (2014) |
| HOCH2COOH | Ag | CO2:CH3OH | 5 keV e− | 247 | 0.008 | 13 | 55184 | 616 | – | – | 1.7E+20 | 13160 | Marks et al. (2023) |
| NCCCCN | ASW | NCCCCN | No | 159 | 0.013 | 16 | 0 | 396 | 1.0E+13 | 5050 | – | – | Guennoun et al. (2005) |
| NCCCCN | Au | NCCCCN | No | – | 0.013 | 0 | 0 | – | 1.0E+13 | 6130 | – | – | Guennoun et al. (2005) |
 |
Au | CH3COOH:NH3 | No | 199 | 0.200 | 14 | 0 | 503 | 3.0E+20 | 9980 | 1.3E+19 | 9410 | Kruczkiewicz et al. (2021) |
| C6H6 | Rh | C2H2 | 5 keV e− | 140 | 0.008 | 17 | 4872 | 358 | – | – | 5.1E+18 | 6880 | Abplanalp et al. (2019) |
| C6H6 | ASW | C6H6 | No | 141 | 0.050 | 17 | 4924 | 361 | 1.0E+13 | 4690 | 5.2E+18 | 6680 | Bahr & Kempter (2007) |
| C6H6 | HOPG | C6H6 | No | 148 | 0.500 | 16 | 5296 | 379 | 1.0E+13 | 5470 | 6.2E+18 | 6710 | Salter et al. (2018) |
| C6H6 | Graphene | C6H6 | No | 160 | 1.000 | 16 | 5953 | 409 | 1.0E+17 | 6560 | 8.1E+18 | 7200 | Smith & Kay (2018) |
| C6H6 | Cu(lll) | C6H6 | No | 155 | 4.000 | 16 | 5676 | 397 | - | - | 7.3E+18 | 6730 | Xi et al. (1994) |
| C6H6 | Cu(lll) | C6H6 | No | 195 | 4.000 | 14 | 8009 | 499 | - | - | 1.6E+19 | 8670 | Xi et al. (1994) |
| QHo | Cu(111) | C6H6 | No | 213 | 4.000 | 14 | 9143 | 545 | - | - | 2.2E+19 | 9560 | Xi et al. (1994) |
| C6H6 | Cu(111) | C6H6 | No | 225 | 4.000 | 13 | 9927 | 576 | - | - | 2.7E+19 | 10150 | Xi et al. (1994) |
| C6H6 | (A) silica | C6H6 | No | - | 0.100 | 0 | 0 | - | 1.0E+13 | 6250 | - | - | Thrower et al. (2009) |
| C6H6 | (A) silica | C6H6 | No | - | 0.100 | 0 | 0 | - | 1.0E+13 | 5890 | - | - | Thrower et al. (2009) |
| C6H6 | (A) silica | C6H6 | No | - | 0.100 | 0 | 0 | - | 1.0E+13 | 5290 | - | - | Thrower et al. (2009) |
| QHo | (A) silica | C6H6 | No | - | 0.100 | 0 | 0 | - | 1.0E+13 | 4990 | - | - | Thrower et al. (2009) |
| C6H6 | (A) silica | C6H6 | No | - | 0.100 | 0 | 0 | - | 1.0E+13 | 4930 | - | - | Thrower et al. (2009) |
| C6H6 | (A) silica | C6H6 | No | - | 0.100 | 0 | 0 | - | 1.0E+13 | 4750 | - | - | Thrower et al. (2009) |
| C6H6 | HOPG | C6H6 | No | 151 | 0.750 | 16 | 5458 | 386 | 9.0E+15 | 5770 | 6.6E+18 | 6800 | Ulbricht et al. (2006) |
| H2PCOOH | Ag | PH3:CO2 | 5 keV e− | 192 | 0.017 | 14 | 32421 | 491 | - | - | 6.4E+19 | 9850 | Zhu et al. (2018a) |
| [NH+4][NH2COO−] | Au | CO2:NH3 | Thermal | 240 | 0.083 | 13 | 104054 | 614 | 1.0E+13 | 8300 | 6.9E+19 | 12000 | Noble et al. (2014) |
| [NH+4][NH2COO−] | (A) carbon | CO2:NH3 | Thermal | 240 | 0.033 | 13 | 104054 | 614 | - | - | 6.9E+19 | 12220 | Potapov et al. (2019) |
| [NH+4][NH2COO−] | MgFeSiO4 | CO2:NH3 | Thermal | 240 | 0.033 | 13 | 104054 | 614 | - | - | 6.9E+19 | 12220 | Potapov et al. (2019) |
| [NH+4][NH2COO−] | KBr | CO2:NH3 | Thermal | 240 | 0.033 | 13 | 104054 | 614 | - | - | 6.9E+19 | 12220 | Potapov et al. (2019) |
| CH3P2H3 | Ag | CH3:P2H3 | 5 keV e− | 135 | 0.017 | 17 | 14034 | 354 | - | - | 1.4E+19 | 6670 | Turner et al. (2016) |
| PH2CH2PH2 | Ag | CH4:PH3 | 5 keV e− | 165 | 0.017 | 15 | 18920 | 433 | - | - | 2.8E+19 | 8310 | Turner et al. (2016) |
| C4H4S | Au(111) | C4H4S | No | 186 | 3.000 | 14 | 36209 | 513 | 1.0E+13 | 5540 | 7.2E+19 | 8590 | Liu et al. (2002) |
| C4H4S | Au(111) | C4H4S | No | 142 | 3.000 | 16 | 24153 | 391 | - | - | 2.8E+19 | 6390 | Liu et al. (2002) |
| c-C6H12 | Graphene | C6H6 | No | 153 | 1.000 | 15 | 46526 | 422 | 1.7E+16 | 6440 | 6.3E+19 | 7190 | Smith & Kay (2018) |
| C6H14 | Al2O3(0001) | QHI4 | No | - | - | 0 | 0 | - | 5.4E+09 | 5230 | - | - | Slayton et al. (1995) |
| CH6H14 | MgO(lOO) | QH14 | No | 144 | 0.600 | 16 | 70101 | 406 | 1.0E+16 | 5580 | 8.5E+19 | 6870 | Tait et al. (2005a) |
| CH3COCOCH3 | Ag | CH3CHO | 5 keV e− | 236 | 0.008 | 12 | 90763 | 666 | - | - | 3.0E+20 | 12690 | Kleimeier et al. (2020b) |
| CH3COCOCH3 | Ag | CH3COCOCH3 | No | 135 | 0.008 | 16 | 39268 | 381 | - | - | 4.2E+19 | 6920 | Kleimeier et al. (2020b) |
| CH3COCOCH3 | Ag | CH3COCOCH3 | No | 158 | 0.008 | 15 | 49719 | 446 | - | - | 7.3E+19 | 8210 | Kleimeier et al. (2020b) |
| CH3COCOCH3 | Ag | P:A | 5 keV e− | 160 | 0.008 | 15 | 50666 | 451 | - | - | 7.6E+19 | 8320 | Kleimeier et al. (2020b) |
| CH3COCOCH3 | Ag | P:A | 5 keV e− | 206 | 0.008 | 13 | 74018 | 581 | - | - | 1.8E+20 | 10950 | Kleimeier et al. (2020b) |
| CH3COCOCH3 | Ag | P:A | 5 keV e− | 236 | 0.008 | 12 | 90763 | 666 | - | - | 3.0E+20 | 12690 | Kleimeier et al. (2020b) |
| CH3COCOCH3 | Ag | H2O:CH3CHO | 5 keV e− | 160 | 0.008 | 15 | 50666 | 451 | - | - | 7.6E+19 | 8320 | Kleimeier et al. (2020b) |
| CH3COCOCH3 | Ag | H2O:CH3CHO | 5 keV e− | 170 | 0.008 | 14 | 55490 | 480 | - | - | 9.4E+19 | 8890 | Kleimeier et al. (2020b) |
| CH3COCOCH3 | Ag | H2O:CH3CHO | 5 keV e− | 200 | 0.008 | 13 | 61496 | 577 | - | - | 1.5E+20 | 10580 | Kleimeier et al. (2020a) |
| CH3COCOOH | Ag | CH3CHO:CO2 | 5 keV e− | 235 | 0.008 | 12 | 81777 | 679 | - | - | 2.7E+20 | 12610 | Kleimeier et al. (2020a) |
| CH3COCOOH | Ag | CH3COCOOH | No | 185 | 0.008 | 14 | 57120 | 534 | - | - | 1.2E+20 | 9730 | Kleimeier et al. (2020a) |
| HOCH2CH(OH)CHO | Au | HOCH2CHO:CO | H | 215 | 0.333 | 13 | 93892 | 635 | - | - | 2.7E+20 | 10720 | Fedoseev et al. (2017) |
| HOCH2CH(OH)CHO | Cu | H20:H2CO | UV | 225 | 0.033 | 12 | 100518 | 664 | - | - | 3.1E+20 | 11780 | Layssac et al. (2020) |
| HOCH2CH(OH)CHO | Pt(111) | G | No | 230 | 4.000 | 12 | 103887 | 679 | - | - | 3.4E+20 | 10970 | McManus et al. (2014) |
| HOCH2CH(OH)CHO | Pt(111) | G | No | 300 | 4.000 | 11 | 154758 | 886 | - | - | 8.6E+20 | 14660 | McManus et al. (2014) |
| CH3C6H5 | HOPG | CH3C6H5 | No | 149 | 0.500 | 15 | 20673 | 450 | 1.0E+13 | 5650 | 2.9E+19 | 6980 | Salter et al. (2018) |
| CH3C6H5 | HOPG | CH3C6H5 | No | 179 | 1.000 | 14 | 27221 | 540 | 1.0E+19 | 8180 | 5.5E+19 | 8410 | Ulbricht et al. (2006) |
| HOCH(CH2OH)2 | Mo(llO) | CH3OH | 20 eV e− | 280 | 0.017 | 11 | 158901 | 845 | - | - | 7.8E+20 | 15180 | Boamah et al. (2014) |
| HOCH(CH2OH)2 | Au | HOCH2CHO:CO | H | 240 | 0.333 | 12 | 126098 | 724 | - | - | 4.6E+20 | 12120 | Fedoseev et al. (2017) |
| HOCH(CH2OH)2 | Ag | CH3OH | 5 keV e− | 238 | 0.008 | 12 | 124525 | 718 | - | - | 4.4E+20 | 12890 | Kaiser & Maksyutenko (2015) |
| HOCH(CH2OH)2 | Cu | H2O:H2CO | UV | 250 | 0.033 | 12 | 134060 | 755 | - | - | 5.3E+20 | 13250 | Layssac et al. (2020) |
| HOCH(CH2OH)2 | Ag | CH3OH | 5 keV e− | 234 | 0.008 | 12 | 121399 | 706 | - | - | 4.2E+20 | 12660 | Maity et al. (2014) |
| HOCH(CH2OH)2 | Mo(llO) | CH3OH | lk eV e− | 280 | 0.017 | 11 | 158901 | 845 | - | - | 7.8E+20 | 15180 | Sullivan et al. (2016) |
| CH3P(O)(OH)2 | Ag | H20:C¾:P¾ | 5 keV e− | 250 | 0.017 | 11 | 62113 | 787 | - | - | 2.5E+20 | 13240 | Turner et al. (2019) |
| S3 | ? | H2S:CH3OH:NH3:H2O | 10 keV e− | 282 | 0.008 | 11 | 38093 | 888 | - | - | 2.0E+20 | 15100 | Mahjoub et al. (2017) |
| s3 | 9 | H2S | UV | 275 | 0.023 | 11 | 73366 | 866 | - | - | 3.6E+20 | 14600 | Jimenez-Escobar & Muñoz Caro (2011) |
| P3H5 | Ag | CH4:PH3 | 5 keV e− | 162 | 0.017 | 14 | 25261 | 521 | - | - | 4.4E+19 | 8230 | Turner et al. (2016) |
| C6H5CCH | Rh | C2H2 | 5 keV e− | 170 | 0.008 | 13 | 55058 | 569 | - | - | 1.1E+20 | 8910 | Abplanalp et al. (2019) |
| c-C6H5CN | Au(lOO) | C6H5CN | No | 285 | 4.000 | 10 | 119327 | 963 | 1.0E+14 | 9020 | 6.8E+20 | 13850 | Solomun et al. (1989) |
| c-C6H5CN | Cu | C6H6:CH3CN | 2 keV e− | 183 | 0.033 | 13 | 61397 | 618 | - | - | 1.4E+20 | 9400 | Maksyutenko et al. (2022) |
| C6H5CHCH2 | Rh | C2H2 | 5 keV e− | 163 | 0.008 | 13 | 111250 | 556 | - | - | 2.1E+20 | 8640 | Abplanalp et al. (2019) |
| C6H5CHCH2 | Ag(111) | C8H8 | No | 265 | 2.000 | 11 | 230615 | 904 | 1.0E+13 | 7940 | 1.2E+21 | 13180 | Wei et al. (2004) |
| C6H5CHCH2 | Ag(111) | C8H8 | No | 211 | 2.000 | 12 | 163848 | 720 | 1.0E+13 | 5650 | 5.2E+20 | 10280 | Wei et al. (2004) |
| C6H5CHCH2 | Ag(lOO) | C8H8 | No | 330 | 5.000 | 9 | 320471 | 1126 | 2.0E+11 | 8540 | 2.5E+21 | 16440 | Williams et al. (2003) |
| (CH3)2C6H4 | HOPG | (CH3)2C6H4 | No | 155 | 0.500 | 14 | 54464 | 539 | 3.1E+17 | 6130 | 9.5E+19 | 7450 | Salter et al. (2018) |
| (CH3)2C6H4 | HOPG | (CH3)2C6H4 | No | 153 | 0.500 | 14 | 109806 | 532 | 1.0E+16 | 5990 | 1.9E+20 | 7460 | Salter et al. (2018) |
| C6H5CHO | ASW | C6H5CHO | No | 180 | 0.017 | 13 | 126806 | 626 | – | 4810 | 3.0E+20 | 9500 | Lasne et al. (2012) |
| CH3CH2C6H5 | HOPG | CH3CH2C6H5 | No | 205 | 1.000 | 12 | 173146 | 713 | 5.0E+19 | 9500 | 5.3E+20 | 10130 | Ulbricht et al. (2006) |
| C4H5N3O | Au | Cytosine | No | 433 | 0.250 | 8 | 1212828 | 1577 | 1.0E+13 | 14670 | 1.7E+22 | 23820 | Demers et al. (2002) |
| C4H5N3O | Au(100) | Cytosine | No | 428 | 0.250 | 8 | 1191882 | 1559 | – | 15400 | 1.7E+22 | 23530 | Demers et al. (2002) |
| C8H18 | Al2O3(0001) | C8H18 | No | – | – | 0 | 0 | – | 1.6E+12 | 7350 | – | – | Slayton et al. (1995) |
| C8H18 | MgO(100) | C8H18 | No | 175 | 0.600 | 12 | 250305 | 655 | 7.9E+17 | 7560 | 6.0E+20 | 8730 | Tait et al. (2005a) |
| C5H6N2O2 | Au | Thymine | No | 373 | 0.250 | 8 | 519385 | 1542 | 1.0E+13 | 12510 | 6.2E+21 | 20090 | Demers et al. (2002) |
| C5H6N2O2 | Au(100) | Thymine | No | 378 | 0.250 | 8 | 529864 | 1563 | – | 13350 | 6.5E+21 | 20380 | Demers et al. (2002) |
| C10H8 | Rh | C10H8 | 5 keV e− | 185 | 0.008 | 11 | 114642 | 777 | – | – | 3.4E+20 | 9930 | Abplanalp et al. (2019) |
| C10H8 | HOPG | C10H8 | No | 235 | 1.000 | 10 | 164130 | 987 | 6.0E+16 | 9260 | 7.9E+20 | 11740 | Ulbricht et al. (2006) |
| S4 | ? | H2S:CH3OH:NH3:H2O | 10 keV e− | 282 | 0.008 | 9 | 118863 | 1184 | – | – | 8.3E+20 | 15500 | Mahjoub et al. (2017) |
| C6H15N3 | Au | HCOOH:CH3CHNH | Thermal | 230 | 0.067 | 10 | 363127 | 973 | – | – | 1.7E+21 | 12280 | Vinogradoff et al. (2012) |
| C5H5N5 | Au(100) | Adenine | No | 448 | 0.250 | 7 | 841125 | 1984 | – | 15760 | 1.6E+22 | 24620 | Demers et al. (2002) |
| C5H5N5 | Au | Adenine binding site 1 | No | 363 | 0.250 | 8 | 613484 | 1608 | 1.0E+13 | 12150 | 7.5E+21 | 19600 | Östblom et al. (2005) |
| C5H5N5 | Au | Adenine binding site 2 | No | 443 | 0.250 | 7 | 827083 | 1962 | 1.0E+13 | 14910 | 1.5E+22 | 24320 | Östblom et al. (2005) |
| C5H5N5 | Au | Adenine binding site 3 | No | 483 | 0.250 | 7 | 941595 | 2139 | 1.0E+13 | 16360 | 2.0E+22 | 26710 | Östblom et al. (2005) |
| C10H22 | MgO(100) | C10H22 | No | 204 | 0.600 | 10 | 679726 | 950 | 1.3E+19 | 9370 | 2.7E+21 | 10520 | Tait et al. (2005a) |
| CH3I | ASW | CH3I | No | 115 | 3.000 | 14 | 721 | 536 | – | – | 9.3E+17 | 4760 | DeSimone et al. (2013) |
| CH3I | (P) ASW | CH3I | No | 115 | 3.000 | 14 | 721 | 536 | – | – | 9.3E+17 | 4760 | DeSimone et al. (2013) |
| C5H5N5O | Au(100) | Guanine | No | 488 | 0.250 | 6 | 1451100 | 2418 | – | 17560 | 3.6E+22 | 27260 | Demers et al. (2002) |
| C5H5N5O | Au | Guanine | No | 453 | 0.250 | 7 | 1297821 | 2244 | 1.0E+13 | 15280 | 2.7E+22 | 25160 | Östblom et al. (2005) |
| [C6Hl5N3H+][HCOO−] | Au | HCOOH:CH3CHNH | Thermal | 270 | 0.067 | 8 | 0 | 1550 | – | – | 1.7E+21 | 14460 | Vinogradoff et al. (2012) |
| [C6Hl5N3H+][HCOO−] | Au | HCOOH:C6H15N3 | Thermal | 260 | 0.067 | 8 | 0 | 1493 | – | – | 1.7E+21 | 13910 | Vinogradoff et al. (2012) |
| C14H10 | Rh | C2H2 | 5 keV e− | 232 | 0.008 | 9 | 491510 | 1355 | – | – | 3.2E+21 | 13020 | Abplanalp et al. (2019) |
| C24H12 | HOPG | C24H12 | No | 390 | 2.000 | 5 | 1572181 | 3839 | 2.0E+16 | 15280 | 4.9E+22 | 21010 | Ulbricht et al. (2006) |
| C32H14 | HOPG | C32H14 | No | 490 | 2.000 | 4 | 15999447 | 6399 | 5.0E+21 | 27660 | 1.0E+24 | 28010 | Ulbricht et al. (2006) |
| C60 | HOPG | C60 | No | 573 | 2.000 | 3 | 25544230 | 13536 | 2.0E+13 | 19600 | 4.1E+24 | 33630 | Ulbricht et al. (2006) |
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