PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
31997833-0	2018	The deposition of thin films of cadmium zinc sulfide Cd1-x Zn x S at 250  C from spin-coated xanthato complexes: a potential route to window layers for photovoltaic cells.	Zinc	59-61	CD1c molecule	Homo sapiens	53-56	
33462468-4	2021	We also exploited the atomic-level miscibility of Cd and Zn to synthesize Mn2+:(Cd1-xZnxSe)13 alloy suprastructures with tunable metal synergy: Mn2+:(Cd0.5Zn0.5Se)13 suprastructures demonstrated high catalytic activity (turnover number, 17,964 per cluster in 6 h; turnover frequency, 2,994 per cluster per hour) for converting CO2 to organic cyclic carbonates under mild reaction conditions.	Zinc	57-59	CD1c molecule	Homo sapiens	80-83	
32326581-3	2020	In addition, it is possible to tune the CdTe bandgap by introducing, for example, Zn into the composition, forming Cd1-xZnxTe alloys, which can fulfill the Shockley-Queisser limit design criteria for tandem devices.	Zinc	82-84	CD1c molecule	Homo sapiens	115-118	
30645027-4	2019	Interestingly, the band alignments, exposure of active sites, and interfacial charge separation of Cd1- x Znx S@O-MoS2 /NiOx are optimized by tuning the Zn-doping content as well as the growth of defect-rich O-MoS2 layer and NiOx nanoparticles, which endow the hybrids with excellent HER performances.	Zinc	106-108	CD1c molecule	Homo sapiens	99-102	
31997833-8	2018	This work is the first study to demonstrate Cd1-x Zn x S thin films by a spin coating/melt method from xanthato precursors.	Zinc	50-52	CD1c molecule	Homo sapiens	44-47	
29170618-1	2017	We report on the growth and characterization of optical quality multiple quantum well structures of Zn x Cd1-x Se/Zn x Cd y Mg1-x-y Se on an ultra-thin Bi2Se3/CdTe virtual substrate on c-plane Al2O3 (sapphire).	Zinc	100-102	CD1c molecule	Homo sapiens	105-108	
28683540-3	2017	Thus, the main goal of this study was to develop composition-tunable and biocompatible Zn x Cd1 - x S QDs using carboxymethylcellulose polysaccharide as direct capping ligand via green colloidal aqueous route at neutral pH and at room temperature for potential biomedical and environmental applications.	Zinc	87-89	CD1c molecule	Homo sapiens	92-95	
28683540-6	2017	The XRD results indicated that monophasic ternary alloyed Zn x Cd1 - x S nanocrystals were produced with homogenous composition of the core as evidenced by EELS and XPS analyses.	Zinc	58-60	CD1c molecule	Homo sapiens	63-66	
28683540-7	2017	In addition, the absorption and emission optical properties of Zn x Cd1 - x S QDs were red shifted with increasing the amount of Cd2+ in the alloyed nanocrystals, which have also increased the quantum yield compared to pure CdS and ZnS nanoparticles.	Zinc	63-65	CD1c molecule	Homo sapiens	68-71	
28683540-7	2017	In addition, the absorption and emission optical properties of Zn x Cd1 - x S QDs were red shifted with increasing the amount of Cd2+ in the alloyed nanocrystals, which have also increased the quantum yield compared to pure CdS and ZnS nanoparticles.	Zinc	232-235	CD1c molecule	Homo sapiens	68-71	
25977654-0	2015	Facile synthesis of composition-tuned ZnO/Zn x Cd1-x Se nanowires for photovoltaic applications.	Zinc	38-40	CD1c molecule	Homo sapiens	47-50	
28116384-0	2017	Effect of Zn substitution on the magnetic and magnetocaloric properties of Cd1-xZnxCr2Se4 spinel.	Zinc	10-12	CD1c molecule	Homo sapiens	75-78	
28176522-3	2017	Our results identify that full miscibility of most Cd1-xZnxOyS1-y compositions and even binaries like Zn(O,S) is outside typical photovoltaic processing conditions.	Zinc	56-58	CD1c molecule	Homo sapiens	51-54	
26451804-2	2015	Here we report a novel strategy to synthesize Zn x Cd1-x S NFs via the synergistic actions of the graphene oxide (GO) confinement effect and oriented cation exchange.	Zinc	46-48	CD1c molecule	Homo sapiens	51-54	
24833283-4	2015	The band gap of Znx Cd1-x S/alginate core/shell nanoparticles increases with increasing Zn/Cd molar ratio, and the UV/vis absorption blue-shifts correspondingly.	Zinc	16-18	CD1c molecule	Homo sapiens	20-23	
24833283-6	2015	A cadmium-related emission was observed for both the uncovered Znx Cd1-x S and Znx Cd1-x S/alginate core/shell nanoparticles, which has a significant blue-shift with increasing Zn/Cd molar ratio.	Zinc	63-65	CD1c molecule	Homo sapiens	67-70	
34490697-5	2021	Owing to the efficient charge transfer, the Zn x Cd 1-x S-Pt 1 exhibited outstanding photocatalytic performance of CO 2 to CO, with the highest CO generation rate of 75.31 mumol h -1.	Zinc	44-46	CD1c molecule	Homo sapiens	49-53	
23905339-6	2013	The 20% and 30% cu-doped Cd1-x Zn, Te films were both p-type conductivity.	Zinc	31-33	CD1c molecule	Homo sapiens	25-28	
16834351-5	2006	The activation energy for solid-solution formation was determined as approximately 152 kJ/mol, which evidently indicates that the diffusion of Zn2+ ions in the CdSe-ZnSe system is the governing mechanism for the Cd1-xZnxSe solid-solution formation.	Zinc	143-147	CD1c molecule	Homo sapiens	212-215	
11670523-7	1998	An analogous reaction was observed for the cadmium derivative, Cd-1, which displays a (1)H NMR spectrum identical to that of Zn-2.	Zinc	125-129	CD1c molecule	Homo sapiens	63-67	
15721369-4	2005	Using APOBEC3G deletion and point mutants, we mapped the encapsidation determinant to the Zn(2+) coordination residues of the N-terminal catalytic domain (CD1).	Zinc	90-92	CD1c molecule	Homo sapiens	155-158	
34095649-7	2021	Elemental mapping showed that the Zn element was mainly distributed in the outermost layer of the hollow spheres; this might be the critical factor that enabled Ni-doped Zn x Cd1-x S to maintain excellent stability.	Zinc	34-36	CD1c molecule	Homo sapiens	175-178	
34095649-7	2021	Elemental mapping showed that the Zn element was mainly distributed in the outermost layer of the hollow spheres; this might be the critical factor that enabled Ni-doped Zn x Cd1-x S to maintain excellent stability.	Zinc	170-172	CD1c molecule	Homo sapiens	175-178