Control of the Photocatalytic Activity of Metastable Layered Oxynitride K₂LaTa₂O₆N through Topochemical Transformation of Tuned Oxide Precursors

Abstract: In the development of oxynitride photocatalysts, thermal ammonolysis of a metal oxide precursor has often been conducted by varying the reaction conditions (e.g., temperatures, reaction times, and ammonia gas flow rates) to obtain high-quality oxynitride particles that efficiently function as photocatalysts. However, this approach may suffer from undesirable changes in the physicochemical properties of the resulting oxynitride, leading to the lowering of the photocatalytic activity. Here, we show that it is po… Show more

“…In our previous work, lower-valence Ta species (specifically Ta 3+ ) that were associated with the formation of anionic defects were found to lower the photocatalytic H 2 evolution activity of H x K 2− x LaTa 2 O 6 N by shortening the lifetimes of photogenerated free electrons. 26 As shown in Fig. 5, the valence state of the Ta in the EA/H x K 2− x LaTa 2 O 6 N, which was the most active material, was similar to those in the H x K 2− x LaTa 2 O 6 N and R–K 2 LaTa 2 O 6 N. All three specimens exhibited features related almost entirely to Ta 5+ .…”

“…The synthesis was done according to a previously reported procedure with minor modications. 23,26 Briey, CsLaTa 2 O 7 was rst synthesized using a polymerized complex method employing Cs 2 CO 3 ($99.5%; Kanto Chemicals Co.), La(NO 3 ) 3 $6H 2 O ($99.0%; Kanto Chemicals Co.) and TaCl 5 ($99.9%; Mitsuwa Chemicals Co.) with calcination in air at 1273 K for 2 h. The resulting material was then subjected to a topochemical cation exchange reaction in molten KNO 3 ($99.0%; Wako Pure Chemicals Co.) at 673 K for 48 h to obtain KLaTa 2 O 7 . K 2 LaTa 2 O 6 N was produced by heating the as-prepared KLaTa 2 O 7 together with 75 mol% K 2 CO 3 ($99.5%; Kanto Chemicals Co.) in a tube furnace at 1173 K for 3 h under a 50 mL min −1 ow of gaseous ammonia ($99.9995%; Sumitomo Seika Chemicals Co.).…”

“…S3 † for details), as discussed in a previous paper by our group. 26 Following protonexchange, the Ta 4f peak became sharper and showed features typical of Ta 5+ . A loss of the lattice nitrogen content from the surface was also observed aer the proton-exchange (Table 1).…”

“…K 2 LaTa 2 O 6 N, which has a structure comprising two-layer perovskite blocks, undergoes H + /K + exchange in water while maintaining a suitable degree of visible light absorption. 23,26 This material also shows much higher photocatalytic activity than the three-layer analogue because of a longer photogenerated free electron lifetime. 24 Therefore, the application of K 2 LaTa 2 O 6 N to photocatalytic reactions aer suitable modication is of interest.…”

Interlayer modification and single-layer exfoliation of the Ruddlesden–Popper perovskite oxynitride K₂LaTa₂O₆N to improve photocatalytic H₂ evolution activity

“…In our previous work, lower-valence Ta species (specifically Ta 3+ ) that were associated with the formation of anionic defects were found to lower the photocatalytic H 2 evolution activity of H x K 2− x LaTa 2 O 6 N by shortening the lifetimes of photogenerated free electrons. 26 As shown in Fig. 5, the valence state of the Ta in the EA/H x K 2− x LaTa 2 O 6 N, which was the most active material, was similar to those in the H x K 2− x LaTa 2 O 6 N and R–K 2 LaTa 2 O 6 N. All three specimens exhibited features related almost entirely to Ta 5+ .…”

“…The synthesis was done according to a previously reported procedure with minor modications. 23,26 Briey, CsLaTa 2 O 7 was rst synthesized using a polymerized complex method employing Cs 2 CO 3 ($99.5%; Kanto Chemicals Co.), La(NO 3 ) 3 $6H 2 O ($99.0%; Kanto Chemicals Co.) and TaCl 5 ($99.9%; Mitsuwa Chemicals Co.) with calcination in air at 1273 K for 2 h. The resulting material was then subjected to a topochemical cation exchange reaction in molten KNO 3 ($99.0%; Wako Pure Chemicals Co.) at 673 K for 48 h to obtain KLaTa 2 O 7 . K 2 LaTa 2 O 6 N was produced by heating the as-prepared KLaTa 2 O 7 together with 75 mol% K 2 CO 3 ($99.5%; Kanto Chemicals Co.) in a tube furnace at 1173 K for 3 h under a 50 mL min −1 ow of gaseous ammonia ($99.9995%; Sumitomo Seika Chemicals Co.).…”

“…S3 † for details), as discussed in a previous paper by our group. 26 Following protonexchange, the Ta 4f peak became sharper and showed features typical of Ta 5+ . A loss of the lattice nitrogen content from the surface was also observed aer the proton-exchange (Table 1).…”

“…K 2 LaTa 2 O 6 N, which has a structure comprising two-layer perovskite blocks, undergoes H + /K + exchange in water while maintaining a suitable degree of visible light absorption. 23,26 This material also shows much higher photocatalytic activity than the three-layer analogue because of a longer photogenerated free electron lifetime. 24 Therefore, the application of K 2 LaTa 2 O 6 N to photocatalytic reactions aer suitable modication is of interest.…”

Interlayer modification and single-layer exfoliation of the Ruddlesden–Popper perovskite oxynitride K₂LaTa₂O₆N to improve photocatalytic H₂ evolution activity

“…Oxynitrides, including N-doped oxides, have been attracting attention as functional materials. , Oxynitrides are typically synthesized via thermal ammonolysis of an oxide precursor at high temperatures (>1073 K). , The successful synthesis of a desired oxynitride is strongly dependent on the choice of the precursor and the synthesis conditions. Because the diffusion of N 3– ions in the crystal lattice is slow, the use of smaller-sized oxide precursors leads to more effective conversion to the corresponding oxynitrides. − Thermal ammonolysis requires a continuous flow of toxic ammonia gas; however, a solid-state nitriding agent such as urea or carbon nitride, both of which are much less toxic than ammonia, can be used as an alternative to thermal ammonolysis. − …”

Orange Zn–Al–O–N Powder Active for Photocatalytic Water Reduction and Oxidation Synthesized from a Zn–Al Layered Double Hydroxide Using Urea as the Nitriding Agent

Photocatalysis