PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
31986003-5	2020	In addition, Sn-rich and Ag-rich particles/areas observed in the matrix of Sn0.98Na0.016Ag0.004Se contribute to the reduction of lattice thermal conductivity from 0.61 W m-1 K-1 for Sn0.98Ag0.02Se to 0.47 W m-1 K-1 at 785 K. The combination of simultaneously enhanced power factor and depressed thermal conductivity leads to a maximum ZT ~1.2 at 785 K and a high average ZT ~0.74 at 335-785 K for Sn0.98Na0.016Ag0.004Se, and generating a high theoretical conversion efficiency of ~11%.	Tin	13-15	keratin 1	Homo sapiens	174-177	
31986003-5	2020	In addition, Sn-rich and Ag-rich particles/areas observed in the matrix of Sn0.98Na0.016Ag0.004Se contribute to the reduction of lattice thermal conductivity from 0.61 W m-1 K-1 for Sn0.98Ag0.02Se to 0.47 W m-1 K-1 at 785 K. The combination of simultaneously enhanced power factor and depressed thermal conductivity leads to a maximum ZT ~1.2 at 785 K and a high average ZT ~0.74 at 335-785 K for Sn0.98Na0.016Ag0.004Se, and generating a high theoretical conversion efficiency of ~11%.	Tin	13-15	keratin 1	Homo sapiens	211-214	
31986003-5	2020	In addition, Sn-rich and Ag-rich particles/areas observed in the matrix of Sn0.98Na0.016Ag0.004Se contribute to the reduction of lattice thermal conductivity from 0.61 W m-1 K-1 for Sn0.98Ag0.02Se to 0.47 W m-1 K-1 at 785 K. The combination of simultaneously enhanced power factor and depressed thermal conductivity leads to a maximum ZT ~1.2 at 785 K and a high average ZT ~0.74 at 335-785 K for Sn0.98Na0.016Ag0.004Se, and generating a high theoretical conversion efficiency of ~11%.	Tin	75-77	keratin 1	Homo sapiens	174-177	
31986003-5	2020	In addition, Sn-rich and Ag-rich particles/areas observed in the matrix of Sn0.98Na0.016Ag0.004Se contribute to the reduction of lattice thermal conductivity from 0.61 W m-1 K-1 for Sn0.98Ag0.02Se to 0.47 W m-1 K-1 at 785 K. The combination of simultaneously enhanced power factor and depressed thermal conductivity leads to a maximum ZT ~1.2 at 785 K and a high average ZT ~0.74 at 335-785 K for Sn0.98Na0.016Ag0.004Se, and generating a high theoretical conversion efficiency of ~11%.	Tin	75-77	keratin 1	Homo sapiens	211-214	
31986003-5	2020	In addition, Sn-rich and Ag-rich particles/areas observed in the matrix of Sn0.98Na0.016Ag0.004Se contribute to the reduction of lattice thermal conductivity from 0.61 W m-1 K-1 for Sn0.98Ag0.02Se to 0.47 W m-1 K-1 at 785 K. The combination of simultaneously enhanced power factor and depressed thermal conductivity leads to a maximum ZT ~1.2 at 785 K and a high average ZT ~0.74 at 335-785 K for Sn0.98Na0.016Ag0.004Se, and generating a high theoretical conversion efficiency of ~11%.	Tin	75-77	keratin 1	Homo sapiens	174-177	
31986003-5	2020	In addition, Sn-rich and Ag-rich particles/areas observed in the matrix of Sn0.98Na0.016Ag0.004Se contribute to the reduction of lattice thermal conductivity from 0.61 W m-1 K-1 for Sn0.98Ag0.02Se to 0.47 W m-1 K-1 at 785 K. The combination of simultaneously enhanced power factor and depressed thermal conductivity leads to a maximum ZT ~1.2 at 785 K and a high average ZT ~0.74 at 335-785 K for Sn0.98Na0.016Ag0.004Se, and generating a high theoretical conversion efficiency of ~11%.	Tin	75-77	keratin 1	Homo sapiens	211-214	
31986003-5	2020	In addition, Sn-rich and Ag-rich particles/areas observed in the matrix of Sn0.98Na0.016Ag0.004Se contribute to the reduction of lattice thermal conductivity from 0.61 W m-1 K-1 for Sn0.98Ag0.02Se to 0.47 W m-1 K-1 at 785 K. The combination of simultaneously enhanced power factor and depressed thermal conductivity leads to a maximum ZT ~1.2 at 785 K and a high average ZT ~0.74 at 335-785 K for Sn0.98Na0.016Ag0.004Se, and generating a high theoretical conversion efficiency of ~11%.	Tin	75-77	keratin 1	Homo sapiens	174-177	
31986003-5	2020	In addition, Sn-rich and Ag-rich particles/areas observed in the matrix of Sn0.98Na0.016Ag0.004Se contribute to the reduction of lattice thermal conductivity from 0.61 W m-1 K-1 for Sn0.98Ag0.02Se to 0.47 W m-1 K-1 at 785 K. The combination of simultaneously enhanced power factor and depressed thermal conductivity leads to a maximum ZT ~1.2 at 785 K and a high average ZT ~0.74 at 335-785 K for Sn0.98Na0.016Ag0.004Se, and generating a high theoretical conversion efficiency of ~11%.	Tin	75-77	keratin 1	Homo sapiens	211-214