PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
26288315-2	2015	Herein, we report the synthesis of 4H/fcc-Au@Ag2S core-shell nanoribbon (NRB) heterostructures from the 4H/fcc Au@Ag NRBs via the sulfurization of Ag.	Gold	42-44	angiotensin II receptor type 1	Homo sapiens	45-49	
26288315-2	2015	Herein, we report the synthesis of 4H/fcc-Au@Ag2S core-shell nanoribbon (NRB) heterostructures from the 4H/fcc Au@Ag NRBs via the sulfurization of Ag.	Gold	111-113	angiotensin II receptor type 1	Homo sapiens	45-49	
24707967-3	2014	In addition, we synthesized Au@Ag2S core-shell NPs, whose UV-vis absorption spectrum shows good spectral overlap with the ECL spectrum of GO-Au/RuSi@Ru(bpy)3(2+)/CS composites by adjusting the amount of Na2S and AgNO3 in the process of synthesis.	Gold	28-30	angiotensin II receptor type 1	Homo sapiens	31-35	
25160947-5	2014	Finally, Au is deposited at the surface of the Ag2S domain in each hetero-dimer, resulting in the formation of ternary Ag2S-Au-hPt nanocomposites with solid-state interfaces.	Gold	9-11	angiotensin II receptor type 1	Homo sapiens	47-51	
25160947-5	2014	Finally, Au is deposited at the surface of the Ag2S domain in each hetero-dimer, resulting in the formation of ternary Ag2S-Au-hPt nanocomposites with solid-state interfaces.	Gold	9-11	angiotensin II receptor type 1	Homo sapiens	119-123	
20306507-2	2010	The ability to direct growth on the nanorods can lead to "Janus-type" structures where Au is located at the more reactive end of the nanorod, whilst Ag(2)S is located at the other (see picture; CdSe dark blue, CdS light blue, Au yellow, Ag(2)S gray).	Gold	87-89	angiotensin II receptor type 1	Homo sapiens	237-243	
24677361-1	2014	Triangular Au-Ag2S hybrid nanoframes were successfully synthesised by using Ag nanoprisms as templates through gold coating, etching and sulfuration.	Gold	11-13	angiotensin II receptor type 1	Homo sapiens	14-18	
24150322-3	2013	The plasmon band of Au core first red-shifted and broadened at the step of Au-Ag2S and then blue-shifted and narrowed at the step of Au-AgCdS.	Gold	20-22	angiotensin II receptor type 1	Homo sapiens	78-82	
19587908-1	2009	This manuscript demonstrates a room-temperature synthesis for Ag2S nanocrystals and their nanocompsites with Au and the Au could be deposited only at a single site on each Ag2S seed nanocrystal, where in contrast, Ag2S could grow homogeneously on Au seed nanocrystals, resulting in core-shell Au@Ag2S nanoparticles, which still possessed the optical properties of Au nanocrystals; this facile synthesis could be employed towards fabricating a variety of nanocomposites with interesting structures and tailored functionalities.	Gold	109-111	angiotensin II receptor type 1	Homo sapiens	62-66	
20121103-1	2010	The diffusion of Au in Ag(2)S from the inner core to the surface of Ag(2)S was reported, and a new nanocomposite of core-shell Pt@Ag(2)S and Au nanoparticles has been derived through this diffusion phenomenon.	Gold	17-19	angiotensin II receptor type 1	Homo sapiens	23-29	
20121103-1	2010	The diffusion of Au in Ag(2)S from the inner core to the surface of Ag(2)S was reported, and a new nanocomposite of core-shell Pt@Ag(2)S and Au nanoparticles has been derived through this diffusion phenomenon.	Gold	17-19	angiotensin II receptor type 1	Homo sapiens	68-74	
20121103-1	2010	The diffusion of Au in Ag(2)S from the inner core to the surface of Ag(2)S was reported, and a new nanocomposite of core-shell Pt@Ag(2)S and Au nanoparticles has been derived through this diffusion phenomenon.	Gold	17-19	angiotensin II receptor type 1	Homo sapiens	68-74	
20121103-3	2010	This elucidated the mechanism of formation of semiconductor-metal heterostructures as a consequence of Au diffusion in Ag(2)S nanocrystals.	Gold	103-105	angiotensin II receptor type 1	Homo sapiens	119-125	
19587908-1	2009	This manuscript demonstrates a room-temperature synthesis for Ag2S nanocrystals and their nanocompsites with Au and the Au could be deposited only at a single site on each Ag2S seed nanocrystal, where in contrast, Ag2S could grow homogeneously on Au seed nanocrystals, resulting in core-shell Au@Ag2S nanoparticles, which still possessed the optical properties of Au nanocrystals; this facile synthesis could be employed towards fabricating a variety of nanocomposites with interesting structures and tailored functionalities.	Gold	120-122	angiotensin II receptor type 1	Homo sapiens	62-66	
19587908-1	2009	This manuscript demonstrates a room-temperature synthesis for Ag2S nanocrystals and their nanocompsites with Au and the Au could be deposited only at a single site on each Ag2S seed nanocrystal, where in contrast, Ag2S could grow homogeneously on Au seed nanocrystals, resulting in core-shell Au@Ag2S nanoparticles, which still possessed the optical properties of Au nanocrystals; this facile synthesis could be employed towards fabricating a variety of nanocomposites with interesting structures and tailored functionalities.	Gold	120-122	angiotensin II receptor type 1	Homo sapiens	172-176	
19587908-1	2009	This manuscript demonstrates a room-temperature synthesis for Ag2S nanocrystals and their nanocompsites with Au and the Au could be deposited only at a single site on each Ag2S seed nanocrystal, where in contrast, Ag2S could grow homogeneously on Au seed nanocrystals, resulting in core-shell Au@Ag2S nanoparticles, which still possessed the optical properties of Au nanocrystals; this facile synthesis could be employed towards fabricating a variety of nanocomposites with interesting structures and tailored functionalities.	Gold	120-122	angiotensin II receptor type 1	Homo sapiens	172-176	
19587908-1	2009	This manuscript demonstrates a room-temperature synthesis for Ag2S nanocrystals and their nanocompsites with Au and the Au could be deposited only at a single site on each Ag2S seed nanocrystal, where in contrast, Ag2S could grow homogeneously on Au seed nanocrystals, resulting in core-shell Au@Ag2S nanoparticles, which still possessed the optical properties of Au nanocrystals; this facile synthesis could be employed towards fabricating a variety of nanocomposites with interesting structures and tailored functionalities.	Gold	120-122	angiotensin II receptor type 1	Homo sapiens	62-66	
19587908-1	2009	This manuscript demonstrates a room-temperature synthesis for Ag2S nanocrystals and their nanocompsites with Au and the Au could be deposited only at a single site on each Ag2S seed nanocrystal, where in contrast, Ag2S could grow homogeneously on Au seed nanocrystals, resulting in core-shell Au@Ag2S nanoparticles, which still possessed the optical properties of Au nanocrystals; this facile synthesis could be employed towards fabricating a variety of nanocomposites with interesting structures and tailored functionalities.	Gold	120-122	angiotensin II receptor type 1	Homo sapiens	172-176	
19587908-1	2009	This manuscript demonstrates a room-temperature synthesis for Ag2S nanocrystals and their nanocompsites with Au and the Au could be deposited only at a single site on each Ag2S seed nanocrystal, where in contrast, Ag2S could grow homogeneously on Au seed nanocrystals, resulting in core-shell Au@Ag2S nanoparticles, which still possessed the optical properties of Au nanocrystals; this facile synthesis could be employed towards fabricating a variety of nanocomposites with interesting structures and tailored functionalities.	Gold	120-122	angiotensin II receptor type 1	Homo sapiens	172-176	
34726908-6	2021	Interestingly, the catalytic activity of the hydrogen evolution reaction (HER) for the Au-Ag/Ag2S heterojunction nanorods (HJNRs) are higher than that for the Ag-Au-Ag HJNRs, although they have a lower surface temperature during photocatalysis; therefore, hot carriers and electronic structure contributed more to the catalytic activity of the Au-Ag/Ag2S HJNRs than that of the Ag-Au-Ag HJNRs.	Gold	87-89	angiotensin II receptor type 1	Homo sapiens	93-97	
34186387-0	2021	Synthesis of hybrid Au-Ag2S-Cu2-xS nanocrystals with disparate interfacial features.	Gold	20-22	angiotensin II receptor type 1	Homo sapiens	23-27	
34186387-4	2021	In this work, we demonstrate two types of Au-Ag2S-Cu2-xS NCs with disparate interfacial features.	Gold	42-44	angiotensin II receptor type 1	Homo sapiens	45-49	
34186387-5	2021	Specifically, the first type (Type I) is prepared through a routine two-step method and shows that Au domain close to the Ag2S-Cu2-xS interface; another type (Type II) is achieved by a facile one-pot synthesis procedure and contains Au domain with an interphase only with the Ag2S domain, far from the Cu2-xS domain.	Gold	99-101	angiotensin II receptor type 1	Homo sapiens	122-126	
34186387-7	2021	Au@Ag core-shell NCs, metastable Au@Ag2S NCs and Janus Au-Ag2S NCs are formed successively before the Cu2-xS domain appears.	Gold	55-57	angiotensin II receptor type 1	Homo sapiens	58-62	
34186387-8	2021	We speculate that the Au@Ag2S intermediate plays an essential role in building the final complex nanostructure.	Gold	22-24	angiotensin II receptor type 1	Homo sapiens	25-29	
34726908-6	2021	Interestingly, the catalytic activity of the hydrogen evolution reaction (HER) for the Au-Ag/Ag2S heterojunction nanorods (HJNRs) are higher than that for the Ag-Au-Ag HJNRs, although they have a lower surface temperature during photocatalysis; therefore, hot carriers and electronic structure contributed more to the catalytic activity of the Au-Ag/Ag2S HJNRs than that of the Ag-Au-Ag HJNRs.	Gold	87-89	angiotensin II receptor type 1	Homo sapiens	350-354	
34726908-6	2021	Interestingly, the catalytic activity of the hydrogen evolution reaction (HER) for the Au-Ag/Ag2S heterojunction nanorods (HJNRs) are higher than that for the Ag-Au-Ag HJNRs, although they have a lower surface temperature during photocatalysis; therefore, hot carriers and electronic structure contributed more to the catalytic activity of the Au-Ag/Ag2S HJNRs than that of the Ag-Au-Ag HJNRs.	Gold	344-346	angiotensin II receptor type 1	Homo sapiens	93-97	
34726908-6	2021	Interestingly, the catalytic activity of the hydrogen evolution reaction (HER) for the Au-Ag/Ag2S heterojunction nanorods (HJNRs) are higher than that for the Ag-Au-Ag HJNRs, although they have a lower surface temperature during photocatalysis; therefore, hot carriers and electronic structure contributed more to the catalytic activity of the Au-Ag/Ag2S HJNRs than that of the Ag-Au-Ag HJNRs.	Gold	344-346	angiotensin II receptor type 1	Homo sapiens	350-354	
35121445-0	2022	Ultrasensitive photoelectrochemical aptasensor for detecting telomerase activity based on Ag2S/Ag decorated ZnIn2S4/C3N4 3D/2D Z-scheme heterostructures and amplified by Au/Cu2+-boron-nitride nanozyme.	Gold	170-172	angiotensin II receptor type 1	Homo sapiens	90-94	
35424647-1	2022	A technique of obtaining plexitonic structures based on Ag2S quantum dots passivated with l-cysteine (Ag2S/l-Cys QDs) in the presence of Au nanorods passivated with cetyltrimethylammonium bromide molecules (Au/CTAB NRs) with controlled luminescence properties has been developed.	Gold	207-209	angiotensin II receptor type 1	Homo sapiens	102-106	
35424647-2	2022	The structural and luminescence properties of Ag2S/l-Cys QDs with Au/CTAB NRs are studied.	Gold	66-68	angiotensin II receptor type 1	Homo sapiens	46-50	
35424647-7	2022	With weak plexcitonic coupling in the nanostructures (Ag2S QD/l-Cys)/(polyDADMAC)/(Au/CTAB NRs), the possibility of increasing the quantum yield of trap state luminescence for Ag2S QDs due to the Purcell effect has been demonstrated.	Gold	83-85	angiotensin II receptor type 1	Homo sapiens	54-58	
35424647-7	2022	With weak plexcitonic coupling in the nanostructures (Ag2S QD/l-Cys)/(polyDADMAC)/(Au/CTAB NRs), the possibility of increasing the quantum yield of trap state luminescence for Ag2S QDs due to the Purcell effect has been demonstrated.	Gold	83-85	angiotensin II receptor type 1	Homo sapiens	176-180	
35209443-1	2022	The luminescence properties of Ag2S quantum dots passivated with L-Cysteine (Ag2S/L-Cys QDs) are studied in the presence of Au nanorods passivated with cetyltrimethylammonium bromide molecules (Au/CTAB NRs).	Gold	194-196	angiotensin II receptor type 1	Homo sapiens	77-81	
35209443-6	2022	With weak plexcitonic coupling in the nanostructures (Ag2S QD/L-Cys)/(PolyDADMAC)/(Au/CTAB NRs), the possibility of increasing the quantum yield of trap state luminescence for Ag2S QDs due to the Purcell effect has been demonstrated.	Gold	83-85	angiotensin II receptor type 1	Homo sapiens	54-58	
35209443-6	2022	With weak plexcitonic coupling in the nanostructures (Ag2S QD/L-Cys)/(PolyDADMAC)/(Au/CTAB NRs), the possibility of increasing the quantum yield of trap state luminescence for Ag2S QDs due to the Purcell effect has been demonstrated.	Gold	83-85	angiotensin II receptor type 1	Homo sapiens	176-180	
32657318-0	2020	Engineering one-dimensional trough-like Au-Ag2S nano-hybrids for plasmon-enhanced photoelectrodetection of human alpha-thrombin.	Gold	40-42	angiotensin II receptor type 1	Homo sapiens	43-47	
33295340-0	2021	Photoelectrochemical thrombin biosensor based on perylene-3,4,9,10-tetracarboxylic acid and Au co-functionalized ZnO nanorods with signal-off quenching effect of Ag@Ag2S.	Gold	92-94	angiotensin II receptor type 1	Homo sapiens	165-169	
33295340-1	2021	In this work, a thrombin photoelectrochemical aptasensor was reported based on a photoanode of perylene-3,4,9,10-tetracarboxylic acid (PTCA), Au nanoparticle co-functionalized ZnO nanorods (ZnO NRs) and the "signal-off" amplification effect of Ag@Ag2S.	Gold	142-144	angiotensin II receptor type 1	Homo sapiens	247-251	
32657318-1	2020	One-dimensional (1D) morphology-unique Au-Ag2S nano-hybrids are achieved by combining the interfacial self-assembly of Ag nanowires, interface-oriented site-specific etching of Ag nanowires with AuCl4-, and the sulfurization of S2-.	Gold	39-41	angiotensin II receptor type 1	Homo sapiens	42-46	
32657318-2	2020	The as-formed Au-Ag2S nano-hybrid has a trough-like morphology.	Gold	14-16	angiotensin II receptor type 1	Homo sapiens	17-21	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	16-18	angiotensin II receptor type 1	Homo sapiens	19-23	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	16-18	angiotensin II receptor type 1	Homo sapiens	40-44	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	16-18	angiotensin II receptor type 1	Homo sapiens	40-44	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	16-18	angiotensin II receptor type 1	Homo sapiens	40-44	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	16-18	angiotensin II receptor type 1	Homo sapiens	40-44	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	16-18	angiotensin II receptor type 1	Homo sapiens	40-44	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	16-18	angiotensin II receptor type 1	Homo sapiens	40-44	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	16-18	angiotensin II receptor type 1	Homo sapiens	40-44	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	45-47	angiotensin II receptor type 1	Homo sapiens	19-23	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	45-47	angiotensin II receptor type 1	Homo sapiens	19-23	
32657318-3	2020	The wall of the Au-Ag2S nanotrough is a Ag2S/Au/Ag2S trilayer wall, but the Ag2S layer is a Ag2S-rich mixture of Ag2S and Au rather than pure Ag2S because of the diffusion of Au atoms towards Ag2S.	Gold	45-47	angiotensin II receptor type 1	Homo sapiens	19-23	
32657318-4	2020	The Au-Ag2S nanotrough shows strong absorption in the visible region (400-800 nm) and exhibits a favorable photoelectrochemical (PEC) response, the photocurrent of which is ~8.5 times larger than that of pure Ag2S.	Gold	4-6	angiotensin II receptor type 1	Homo sapiens	7-11	
32657318-4	2020	The Au-Ag2S nanotrough shows strong absorption in the visible region (400-800 nm) and exhibits a favorable photoelectrochemical (PEC) response, the photocurrent of which is ~8.5 times larger than that of pure Ag2S.	Gold	4-6	angiotensin II receptor type 1	Homo sapiens	209-213	
32657318-6	2020	Moreover, the PEC biosensor based on the Au-Ag2S nanotroughs shows high sensitivity and selectivity, satisfactory reproducibility, and good stability towards human alpha-thrombin (TB) detection: a sensitive linear response ranging from 1.00 to 10.00 pmol L-1 and a low detection limit of 0.67 pmol L-1.	Gold	41-43	angiotensin II receptor type 1	Homo sapiens	44-48	
32657318-7	2020	This study provides a new model for studying the PEC behavior of plasmonic metal/semiconductor materials, and this Au-Ag2S nanotrough may also be useful in the fields of photocatalysis and photovoltaics.	Gold	115-117	angiotensin II receptor type 1	Homo sapiens	118-122	
31989132-1	2020	A novel signal self-enhancement photoelectrochemical immuno-sensor has been developed based on the curing of sacrificial agent SO32- coated-Au NPs sensitizing Ag2S/CuS/alpha-Fe2O3 n-p-n hetero-structure films for the first time.	Gold	140-142	angiotensin II receptor type 1	Homo sapiens	159-163	
32814430-4	2020	It was attributed to the increase of the refractive index of the environment around the Au nanosphere arrays with silver coating due to the partial formation of Ag2S after detecting the H2S.	Gold	88-90	angiotensin II receptor type 1	Homo sapiens	161-165	
31038933-8	2019	Under 800 nm radiation, the temperature of 1 can rise up to 24.5  C in 3 min with photothermal conversion efficiency of 22.1%, which is about 2x that of pure inorganic Ag2S material and among the highest compared to various known inorganic materials, for example, Au nanoshells (13%), nanorods (21%), and Cu2- xSe nanocrystals (22%) irradiated with 800 nm light, while for 2, the NIR absorption is absent.	Gold	264-266	angiotensin II receptor type 1	Homo sapiens	168-172	
31761035-4	2020	With the sulfide concentration increasing, the Ag2S constantly formed, and consequently the SERS signal intensity of Au@4-MBN@Ag gradually decreased owing to the weaker SERS activity of Ag2S.	Gold	117-119	angiotensin II receptor type 1	Homo sapiens	47-51	
31761035-4	2020	With the sulfide concentration increasing, the Ag2S constantly formed, and consequently the SERS signal intensity of Au@4-MBN@Ag gradually decreased owing to the weaker SERS activity of Ag2S.	Gold	117-119	angiotensin II receptor type 1	Homo sapiens	186-190	
31620730-0	2019	Structural evolution induced by Au atom diffusion in Ag2S.	Gold	32-34	angiotensin II receptor type 1	Homo sapiens	53-57	
31620730-2	2019	By using aberration-corrected high-resolution transmission electron microscopy and X-ray absorption near-edge structure spectroscopy in combination with in situ X-ray diffraction, we confirm that single-atom diffusion of Au to Ag2S occurs, and that the transition from the Au@Ag2S core-shell nanostructure to AuAgS-AuAgx or Ag3AuS2-AuAgx heterostructures was observed.	Gold	221-223	angiotensin II receptor type 1	Homo sapiens	227-231	
31620730-2	2019	By using aberration-corrected high-resolution transmission electron microscopy and X-ray absorption near-edge structure spectroscopy in combination with in situ X-ray diffraction, we confirm that single-atom diffusion of Au to Ag2S occurs, and that the transition from the Au@Ag2S core-shell nanostructure to AuAgS-AuAgx or Ag3AuS2-AuAgx heterostructures was observed.	Gold	221-223	angiotensin II receptor type 1	Homo sapiens	276-280	
31620730-3	2019	Moreover, the phase of the ternary sulfide induced by Au single-atom diffusion in Ag2S is determined by the ratio of Au and Ag, thus exhibiting a significant difference in the photocatalytic activity performance.	Gold	54-56	angiotensin II receptor type 1	Homo sapiens	82-86	
31620730-3	2019	Moreover, the phase of the ternary sulfide induced by Au single-atom diffusion in Ag2S is determined by the ratio of Au and Ag, thus exhibiting a significant difference in the photocatalytic activity performance.	Gold	117-119	angiotensin II receptor type 1	Homo sapiens	82-86	
31335149-2	2019	In the presence of HS- in aqueous solution, the stochastic collision and adsorption of Ag nanoparticles at a Au microelectrode initiates the partial anodic transformation of Ag to Ag2S at each particle.	Gold	109-111	angiotensin II receptor type 1	Homo sapiens	180-184	
30001113-3	2018	After the incorporation of Au NPs on the Ag2S QDs modified ITO electrode, the photoelectric conversion efficiency was greatly increased, at ~2.5 times that of the pure Ag2S QDs modified electrode.	Gold	27-29	angiotensin II receptor type 1	Homo sapiens	41-45	
30001113-3	2018	After the incorporation of Au NPs on the Ag2S QDs modified ITO electrode, the photoelectric conversion efficiency was greatly increased, at ~2.5 times that of the pure Ag2S QDs modified electrode.	Gold	27-29	angiotensin II receptor type 1	Homo sapiens	168-172	
27769496-0	2016	NaEuF4/Au@Ag2S nanoparticles-based fluorescence resonant transfer DNA sensor for ultrasensitive detection of DNA energy.	Gold	7-9	angiotensin II receptor type 1	Homo sapiens	10-14	
27241031-5	2016	The as-prepared Au/AuAg/Ag2S/PbS core-multishell nanorods display distinct localized surface plasmon resonance and nonlinear optical properties, demonstrating an effective pathway for maneuvering the optical properties of nanocavities.	Gold	16-18	angiotensin II receptor type 1	Homo sapiens	24-28	
27314986-2	2016	Significant fluorescence enhancement of over 100 times for Ag2S QDs deposited on Au-nanostructured arrays, paves the way for novel sensing and imaging applications based on Ag2S QDs, with improved detection sensitivity and contrast enhancement.	Gold	81-83	angiotensin II receptor type 1	Homo sapiens	59-63	
27314986-2	2016	Significant fluorescence enhancement of over 100 times for Ag2S QDs deposited on Au-nanostructured arrays, paves the way for novel sensing and imaging applications based on Ag2S QDs, with improved detection sensitivity and contrast enhancement.	Gold	81-83	angiotensin II receptor type 1	Homo sapiens	173-177