The development of highly competent electrocatalysts for the sluggish oxygen reduction reaction (ORR) at cathodes of proton-exchange membrane fuel cells (PEMFCs) is extremely important for their long-term operation and wide applications. Herein, we present highly efficient ORR electrocatalysts based on Pt/Ni bimetallic nanoparticles dispersed on highly porous carbon obtained via pyrolysis of a metal-organic framework MOF-5. In comparison to the commercial Pt/C (20%), the electrocatalyst Pt-Ni/PC 950 (15:15%) in this study exhibits a pronounced positive shift of 90 mV in Eonset. In addition, it also demonstrates excellent long-term stability and durability during the 500-cycle continue-oxygen-supply (COS) accelerating durability tests (ADTs). The significantly improved activity and stability of Pt-Ni/PC 950 (15:15%) can be attributed to the Pt electron interaction with Ni and carbon support as has been proved in X-ray and microscopic analysis.
Pd–Ag bimetallic and monometallic nanoparticles were decorated on g-C3N4 and evaluated for their ability to produce H2 through water splitting reactions.
Boosting the durability of Pt nanoparticles by controlling the composition and morphology is extremely important for fuel cells commercialization. We deposit the Pt-Cu alloy nanoparticles over high surface area carbon in different metallic molar ratios and optimize the conditions to achieve desired material. The novel bimetallic electro-catalyst {Pt-Cu/PC-950 (15:15%)} offers exceptional electrocatalytic activity when tested for both oxygen reduction reaction and methanol oxidation reactions. A high mass activity of 0.043 mA/μgPt (based on Pt mass) is recorded for ORR. An outstanding longevity of this electro-catalyst is noticed when compared to 20 wt % Pt loaded either on PC-950 or commercial carbon. The high surface area carbon support offers enhanced activity and prevents the nanoparticles from agglomeration, migration, and dissolution as evident by TEM analysis.
ZIF-12 is converted to Co/N-CNTs at 950 °C under an argon atmosphere. The obtained hybrid nanocomposite is used for LIBs application as an anode material with superior charge storage performance.
ObjectiveTo determine the frequency and clinical features of bleeding disorders in the tribe as a result of consanguineous marriages.DesignCross Sectional StudyIntroductionCountries in which consanguinity is a normal practice, these rare autosomal recessive disorders run in close families and tribes. Here we describe a family, living in village Ali Murad Chandio, District Badin, labeled as haemophilia.Patients & MethodsOur team visited the village & developed the pedigree of the whole extended family, up to seven generations. Performa was filled by incorporating patients, family history of bleeding, signs & symptoms, and bleeding from any site. From them 144 individuals were screened with CBC, bleeding time, platelet aggregation studies & RiCoF. While for PT, APTT, VWF assay and Factor VIII assay, samples were kept frozen at -70 degrees C until tested.ResultsThe family tree of the seven generations comprises of 533 individuals, 63 subjects died over a period of 20 years and 470 were alive. Out of all those 144 subjects were selected on the basis of the bleeding history. Among them 98(68.1%) were diagnosed to have a bleeding disorder; 44.9% patients were male and 55.1% patients were female. Median age of all the patients was 20.81, range (4 months- 80 yrs). The results of bleeding have shown that majority had gum bleeding, epistaxis and menorrhagia. Most common bleeding disorder was Von Willebrand disease and Platelet functional disorders.ConclusionConsanguineous marriages keep all the beneficial and adversely affecting recessive genes within the family; in homozygous states. These genes express themselves and result in life threatening diseases. Awareness, education & genetic counseling will be needed to prevent the spread of such common occurrence of these bleeding disorders in the community.
Recently, photoelectrochemical conversion
(PEC) of water into fuel is attracting great attention of researchers
due to its outstanding benefits. Herein, a systematic study on PEC
of water using CuFe2O4/ α–Fe2O3 composite thin films is presented. CuFe2O4/ α–Fe2O3 composite
thin films were deposited on two different substrates; (1) planner
FTO glass and (2) 3-dimensional nanospike (NSP). The films on both
substrates were characterized and tested as anode material for photoelectrochemical
water splitting reaction. During PEC studies, it was observed that
the ratio between two components of composite is crucial and highest
PEC activity results were achieved by 1:1 component ratio (CF-1) of
CuFe2O4 and α–Fe2O3. The CF-1 ratio sample deposited on planar FTO substrate
provided a photocurrent density of 1.22 mA/cm2 at 1.23 V
RHE which is 1.9 times higher than bare α–Fe2O3 sample. A significant PEC activity outperformance
was observed when CF-1 ratio composite thin films were deposited on
3D NSP. The highest photocurrent density of 2.26 mA/cm2 at 1.23 V
RHE was achieved for 3D NSP
sample which is around 3.6 times higher than photocurrent density
generated by α–Fe2O3 thin film
only. The higher photocurrent densities of 3D nanostructured devices
compared to planar one are attributed to the enhanced light trapping
and increased surface area for photoelectrochemical water oxidation
on the surface. The difference between valence and conduction bands
of CuFe2O4 and α–Fe2O3 allows better separation of photogenerated electrons
and holes at the CuFe2O4/ α–Fe2O3 interface which makes it more active for photoelectrochemical
water splitting.
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