Effect of phosphorus concentration on the electronic structure of nanocrystalline electrodeposited Ni–P alloys: an XPS and XAES investigation

Abstract: A surface analysis has been conducted on a series of electrodeposited nickel-phosphorus (Ni-P) alloys containing from 6 to 29 at.% phosphorus, using X-ray photoelectron spectroscopy (XPS) and X-ray excited Auger electron spectroscopy (XAES). No changes in core-level binding energies, Ni2p3/2 and Ni2p1/2, P2p, P2s, or X-ray excited NiLMM and PKLL Auger lines were observed regardless of phosphorus concentration. The only systematic differences observed concerned: (i) the binding energy of the Ni2p satellite peak… Show more

“…The binding energy of the Ni2p3/2 signal is found at 853.0 ± 0.1 eV in good agreement with the literature [11,33]. The distance of the satellite is found here to be 7.2 eV, thus clearly higher than the 6 eV reported for pure nickel but in keeping with the concept of the influence of phosphorus content on the electronic properties of Ni-P alloys [33]. A very small amount of nickel phosphate (856.4 ± 0.1 eV) is also found.…”

“…5) is very similar to the typical Ni2p3/2 plus satellite structure as known from pure metallic nickel [33]. The binding energy of the Ni2p3/2 signal is found at 853.0 ± 0.1 eV in good agreement with the literature [11,33].…”

“…On the other hand, the authors' work on amorphous Fe70Cr10P13C7 alloys has shown that phosphorus in the bulk of this alloy has a partial negative charge [23,24] in agreement with the literature data for Ni-P alloys [27,28] and on a series of binary nickel-phosphides [29]. Thus phosphorus in the bulk of the Ni-P alloy undergoes partial covalent bonding with the metal atoms, influencing both the structural order [29,30,31] and the electronic state of nickel in Ni-P compounds and alloys [29,32,33].…”

“…5) is very similar to the typical Ni2p3/2 plus satellite structure as known from pure metallic nickel [33]. The binding energy of the Ni2p3/2 signal is found at 853.0 ± 0.1 eV in good agreement with the literature [11,33]. The distance of the satellite is found here to be 7.2 eV, thus clearly higher than the 6 eV reported for pure nickel but in keeping with the concept of the influence of phosphorus content on the electronic properties of Ni-P alloys [33].…”

“…4.5 Electronic structure of Ni-P alloys XPS/XAES measurements have provided evidence of the metallic character of crystalline Ni-phosphides [29]. The high corrosion resistance of Ni-P alloys might be influenced by the electronic structure of these alloys [32] that in turn is affected by phosphorus content [33]. As also shown by the negatively charged (-0.4 eV) phosphorus in the bulk alloy (see above), nickel and phosphorus undergo partial covalent bonding between Ni 3d and P 3p bands [29,33,34].…”

Electroless deposited Ni–P alloys: corrosion resistance mechanism

“…The binding energy of the Ni2p3/2 signal is found at 853.0 ± 0.1 eV in good agreement with the literature [11,33]. The distance of the satellite is found here to be 7.2 eV, thus clearly higher than the 6 eV reported for pure nickel but in keeping with the concept of the influence of phosphorus content on the electronic properties of Ni-P alloys [33]. A very small amount of nickel phosphate (856.4 ± 0.1 eV) is also found.…”

“…5) is very similar to the typical Ni2p3/2 plus satellite structure as known from pure metallic nickel [33]. The binding energy of the Ni2p3/2 signal is found at 853.0 ± 0.1 eV in good agreement with the literature [11,33].…”

“…On the other hand, the authors' work on amorphous Fe70Cr10P13C7 alloys has shown that phosphorus in the bulk of this alloy has a partial negative charge [23,24] in agreement with the literature data for Ni-P alloys [27,28] and on a series of binary nickel-phosphides [29]. Thus phosphorus in the bulk of the Ni-P alloy undergoes partial covalent bonding with the metal atoms, influencing both the structural order [29,30,31] and the electronic state of nickel in Ni-P compounds and alloys [29,32,33].…”

“…5) is very similar to the typical Ni2p3/2 plus satellite structure as known from pure metallic nickel [33]. The binding energy of the Ni2p3/2 signal is found at 853.0 ± 0.1 eV in good agreement with the literature [11,33]. The distance of the satellite is found here to be 7.2 eV, thus clearly higher than the 6 eV reported for pure nickel but in keeping with the concept of the influence of phosphorus content on the electronic properties of Ni-P alloys [33].…”

“…4.5 Electronic structure of Ni-P alloys XPS/XAES measurements have provided evidence of the metallic character of crystalline Ni-phosphides [29]. The high corrosion resistance of Ni-P alloys might be influenced by the electronic structure of these alloys [32] that in turn is affected by phosphorus content [33]. As also shown by the negatively charged (-0.4 eV) phosphorus in the bulk alloy (see above), nickel and phosphorus undergo partial covalent bonding between Ni 3d and P 3p bands [29,33,34].…”

Electroless deposited Ni–P alloys: corrosion resistance mechanism

Expedited Synthesis of Metal Phosphides Maximizes Dispersion, Air Stability, and Catalytic Performance in Selective Hydrogenation

Expedited Synthesis of Metal Phosphides Maximizes Dispersion, Air Stability, and Catalytic Performance in Selective Hydrogenation