The emergence of intense near-infrared photoluminescence by photoactivation of silver nanoclusters.

Photoirradiation of a pyridine solution of Ag29 nanoclusters (NCs) with red photoluminescence (PL) at 680 nm activated intense PL in the near infrared (NIR) region, giving a PL quantum yield (PLQY) of 33% at 770 nm. The use of Au-doped silver NCs further boosted the PLQY to more than 45% at 800 nm. Photoirradiation is considered to induce a change in the charge localization in the NCs, leading to the formation of NIR emitting sites.

Photoactivation of Strong Photoluminescence in Superacid-Treated Monolayer Molybdenum Disulfide.

To advance the development of atomically thin optoelectronics using two-dimensional (2D) materials, engineering strong luminescence with a physicochemical basis is crucial. Semiconducting monolayer transition-metal dichalcogenides (TMDCs) are candidates for this, but their quantum yield (QY) is known to be poor. Recently, a molecular superacid treatment of bis(trifluoromethane)sulfonimide (TFSI) generated unambiguously bright monolayer TMDCs and a high QY. However, this method is highly dependent on the processing conditions and therefore has not been generalized. Here, we shed light on environmental factors to activate the photoluminescence (PL) intensity of the TFSI-treated monolayer MoS2, with a factor of more than 2 orders of magnitude greater than the original by photoactivation. The method is useful for both mechanically exfoliated and chemically deposited samples. The existence of photoirradiation larger than the band gap demonstrates enhancement of the PL of MoS2; on the other hand, activation by thermal annealing, as demonstrated in the previous report, is less effective for enhancing the PL intensity. The photoactivated monolayer MoS2 shows a long lifetime of ∼1.35 ns, more than a 30-fold improvement over the original as exfoliated. The consistent realization of the bright monolayer MoS2 reveals that air exposure is an essential factor in the process. TFSI treatment in a N2 environment was not effective for achieving a strong PL, even after the photoactivation. These findings can serve as a basis for engineering the bright atomically thin materials for 2D optoelectronics.

Identification procedure for Pasteurella pneumotropica in microbiologic monitoring of laboratory animals.

Discrepancies have been recognized in the identification of Pasteurella pneumotropica between testing laboratories. To determine the causes of the differences and to propose a reliable identification procedure for P. pneumotropica, a working group was organized and 69 isolates identified or suspected as P. pneumotropica were collected from 8 laboratories in Japan. These isolates were examined by colony morphology, Gram-staining, the slide agglutination test using two antisera (ATCC35149 and MaR), two commercially available biochemical test kits (ID test, API20NE) and two primer sets of PCR tests (Wang PCR, CIEA PCR). The 69 isolates and two reference strains were divided into 10 groups by test results. No single procedure for P. pneumotropica identification was found. Among tested isolates, large differences were not observed by colony morphology and Gram-straining except for colony colors that depended on their biotypes. Sixty-eight out of 69 isolates were positive by the slide agglutination test using two antisera except for one isolate that tested with one antiserum. The ID test identified 61 out of 69 isolates as P. pneumotropica and there was no large difference from the results of CIEA PCR. From these results, we recommend the combination of colony observation, Gram-straining, the slide agglutination tests with two antisera and biochemical test using the ID test for practical and reliable identification of this organism.