PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
33755454-8	2021	Then, we investigated the reactivities of the (mu-eta2:eta2-NO2)dicopper complex toward methane and benzene by considering the conversions of N2O to N2 in the presence and the absence of methane or benzene.	Benzene	100-107	DNA polymerase iota	Homo sapiens	50-54	
33755454-8	2021	Then, we investigated the reactivities of the (mu-eta2:eta2-NO2)dicopper complex toward methane and benzene by considering the conversions of N2O to N2 in the presence and the absence of methane or benzene.	Benzene	100-107	DNA polymerase iota	Homo sapiens	55-59	
33755454-8	2021	Then, we investigated the reactivities of the (mu-eta2:eta2-NO2)dicopper complex toward methane and benzene by considering the conversions of N2O to N2 in the presence and the absence of methane or benzene.	Benzene	198-205	DNA polymerase iota	Homo sapiens	50-54	
33755454-10	2021	Thus, the (mu-eta2:eta2-NO2)dicopper complex prefers the reactions with methane and benzene to that with N2O.	Benzene	84-91	DNA polymerase iota	Homo sapiens	14-18	
33755454-10	2021	Thus, the (mu-eta2:eta2-NO2)dicopper complex prefers the reactions with methane and benzene to that with N2O.	Benzene	84-91	DNA polymerase iota	Homo sapiens	19-23	
33755454-11	2021	The reaction of the (mu-eta2:eta2-NO2)dicopper complex with methane or benzene generated the (mu-nitrosyl)dicopper complex.	Benzene	71-78	DNA polymerase iota	Homo sapiens	24-28	
33755454-11	2021	The reaction of the (mu-eta2:eta2-NO2)dicopper complex with methane or benzene generated the (mu-nitrosyl)dicopper complex.	Benzene	71-78	DNA polymerase iota	Homo sapiens	29-33	
30931152-5	2019	Moreover, when the lattice of the metal surface is commensurate with the size of benzene rings, the contribution to the adsorption energy from eta2-coordination is about twice that from eta1-coordination.	Benzene	81-88	DNA polymerase iota	Homo sapiens	143-147	
32842728-8	2020	Static DFT calculations also identified an eta2-coordinated benzene complex in which the arene is held more loosely than in the ground state, primarily through dispersion forces.	Benzene	60-67	DNA polymerase iota	Homo sapiens	43-47	
32842728-9	2020	Although a single reaction pathway was identified by static calculations, quasiclassical direct dynamics simulations identified a network of several reaction pathways connecting the eta2-benzene and phenyl hydride isomers, due to the relatively flat energy landscape.	Benzene	199-213	DNA polymerase iota	Homo sapiens	182-186	
30773724-1	2019	The reaction of Re2 (CO)8 (mu-C6 H5 )(mu-H), 1 with corannulene (C20 H10 ) yielded the product Re2 (CO)8 (mu-H)(mu-eta2 -1,2-C20 H9 ), 2 (65 % yield) containing a Re2 metalated corannulene ligand formed by loss of benzene from 1 and the activation of one of the CH bonds of the nonplanar corannulene molecule by an oxidative-addition to 1.	Benzene	214-221	DNA polymerase iota	Homo sapiens	115-119	
32383858-2	2020	The reaction is initiated by boron atom addition to benzene in forming an eta2-(1, 4) Pi adduct (A).	Benzene	52-59	DNA polymerase iota	Homo sapiens	74-78	
20858013-0	2010	C-H bond activation of benzene by unsaturated eta2-cyclopropene and eta2-benzyne complexes of niobium.	Benzene	23-30	DNA polymerase iota	Homo sapiens	46-50	
29780565-1	2018	Previous theoretical and experimental endeavors suggested that [Cu(C6H6)]+ prefers the eta1/eta2 mode over the eta6 mode due to the augmented repulsion between the benzene ring and metal d-electrons.	Benzene	164-171	DNA polymerase iota	Homo sapiens	92-96	
29780565-3	2018	However, the use of IPr (1,3-bis(2,6-diisopropylphenyl)imidazol-2-ylidene) in place of silylene results in the formation of [IPr Cu(eta2-C6H6)]+[SbF6]- (6), where the copper atom is bound to the benzene ring in the eta2 mode.	Benzene	195-202	DNA polymerase iota	Homo sapiens	132-136	
28742965-1	2017	The effects of an electron-withdrawing group on the organic chemistry of an eta2-bound benzene ring are explored using the complex TpW(NO)(PMe3)(eta2-PhCF3).	Benzene	87-94	DNA polymerase iota	Homo sapiens	76-80	
28742965-1	2017	The effects of an electron-withdrawing group on the organic chemistry of an eta2-bound benzene ring are explored using the complex TpW(NO)(PMe3)(eta2-PhCF3).	Benzene	87-94	DNA polymerase iota	Homo sapiens	145-149	
20858013-0	2010	C-H bond activation of benzene by unsaturated eta2-cyclopropene and eta2-benzyne complexes of niobium.	Benzene	23-30	DNA polymerase iota	Homo sapiens	68-72	
18072764-4	2008	The reaction of [MoO2(eta2-Pz)2] with NacNacH in benzene at room temperature leads to a mixture of 1 and the monomeric molybdenum(VI) compound [MoO2(NacNac)(eta2-Pz)] (2).	Benzene	49-56	DNA polymerase iota	Homo sapiens	22-26	
17165710-1	2006	The intermolecular C-H bond activation of benzene occurs under very mild conditions (room temperature) via a rare stereospecific 1,3-H addition on an unsaturated eta2-cyclopropene intermediate generated by a beta-H abstraction of CH4 from TpMe2NbMe(c-C3H5)(MeCCMe) to give TpMe2NbPh(c-C3H5)(MeCCMe).	Benzene	42-49	DNA polymerase iota	Homo sapiens	162-166	
16852478-2	2005	Coadsorbed benzene or naphthalene are found to convert eta1- and eta2-states of ethyl formate and acetone into new states displaying slightly red-shifted carbonyl bands.	Benzene	11-18	DNA polymerase iota	Homo sapiens	65-69