The lattice oxygen mechanism (LOM) is considered one of the promising approaches to overcome the sluggish oxygen evolution reaction (OER), bypassing -OOH* coordination with a high energetic barrier. Activated lattice oxygen can participate in the OER as a reactant and enables O*-O* coupling for direct O2 formation. However, such reaction kinetics inevitably include the generation of oxygen vacancies, which leads to structural degradation, and eventually shortens the lifetime of catalysts. Here, we demonstrate that Se incorporation significantly enhances OER performance and the stability of NiFe (oxy)hydroxide (NiFe) which follows the LOM pathway. In Se introduced NiFe (NiFeSe), Se forms not only metal-Se bonding but also Se-oxygen bonding by replacing oxygen sites and metal sites, respectively. As a result, transition metals show reduced valence states while oxygen shows less reduced valence states (O-/O2 2-) which is a clear evidence of lattice oxygen activation. By virtue of its electronic structure modulation, NiFeSe shows enhanced OER activity and long-term stability with robust active lattice oxygen compared to NiFe.

Recently, due to high theoretical capacitance and excellent ion diffusion rate caused by the 2D layered crystal structure, transition metal hydroxides (TMHs) have generated considerable attention as active materials in supercapacitors (or electrochemical capacitors). However, TMHs should be designed using morphological or structural modification if they are to be used as active materials in supercapacitors, because they have insulation properties that induce low charge transfer rate. This study aims to modify the morphological structure for high cycling stability and fast charge storage kinetics of TMHs through the use of nickel cobalt hydroxide [NiCo(OH)2] decorated on nickel foam. Among the samples used, needle-like NiCo(OH)2 decorated on nickel foam offers a high specific capacitance (1110.9 F/g at current density of 0.5 A/g) with good rate capability (1110.9 - 746.7 F/g at current densities of 0.5 - 10.0 A/g). Moreover, at a high current density (10.0 A/g), a remarkable capacitance (713.8 F/g) and capacitance retention of 95.6% after 5000 cycles are noted. These results are attributed to high charge storage sites of needle-like NiCo(OH)2 and uniformly grown NiCo(OH)2 on nickel foam surface.

Cobalt (Co) is mainly used to prepare cathode materials for lithium-ion batteries (LIBs) and binder metals for WC-Co hard metals. Developing an effective method for recovering Co from WC-Co waste sludge is of immense significance. In this study, Co is extracted from waste cemented carbide soft scrap via mechanochemical milling. The leaching ratio of Co reaches approximately 93%, and the leached solution, from which impurities except nickel are removed by pH titration, exhibits a purity of approximately 97%. The titrated aqueous Co salts are precipitated using oxalic acid and hydroxide precipitation, and the effects of the precipitating agent (oxalic acid and hydroxide) on the cobalt microstructure are investigated. It is confirmed that the type of Co compound and the crystal growth direction change according to the precipitation method, both of which affect the microstructure of the cobalt powders. This novel mechanochemical process is of significant importance for the recovery of Co from waste WC-Co hard metal. The recycled Co can be applied as a cemented carbide binder or a cathode material for lithium secondary batteries.

Layered-double hydroxide (LDH)-based nanostructures offer the two-fold advantage of being active catalysts with incredibly large specific surface areas. As such, they have been studied extensively over the last decade and applied in roles as diverse as light source, catalyst, energy storage mechanism, absorber, and anion exchanger. They exhibit a unique lamellar structure consisting of a wide variety of combinations of metal cations and various anions, which determine their physical and chemical performances, and make them a popular research topic. Many reviewed papers deal with these unique properties, synthetic methods, and applications. Most of them, however, are focused on the form-factor of nanopowder, as well as on the control of morphologies via one-step synthetic methods. LDH nanostructures need to be easy to control and fabricate on rigid substrates such as metals, semiconductors, oxides, and insulators, to facilitate more viable applications of these nanostructures to various solid-state devices. In this review, we explore ways to grow and control the various LDH nanostructures on rigid substrates.

In this paper, synthesis of terephthalate intercalated Zn-Al: Layered double hydroxides (LDHs) was studied. We designed freestanding Zn-Al: carbonate LDH nanosheets for a facile exchange technique. The as-prepared Zn-Al carbonate LDHs were converted to terephthalate intercalated Zn-Al:LDHs by ion exchange method. Initially, Al-doped ZnO (AZO) thin films were deposited on p-Si (001) by facing target sputtering. For synthesis of free standing carbonate Zn-Al:LDH, we dipped the AZO thin film in naturally carbonated water for 3 hours. Further, Zn-Al: carbonate LDH nanosheets were immersed in terepthalic acid (TA) solution. The ion exchange phenomena in the terephthalate assisted Zn-Al:LDH were confirmed using FTIR analysis. The crystal structure of terephthalate intercalated Zn-Al:LDH was investigated by XRD pattern analysis with different mole concentrations of TA solution and reaction times. The optimal conditions for intercalation of terephthalate from carbonated Zn-Al LDH were established using 0.3 M aqueous solution of TA for 24 hours.

칼슘은 인체의 뼈 또는 치아와 같은 골격구조의 주요 성분이며 다양한 생체 기능에 중요한 인자로서 작용하기 때문 에 적절한 섭취가 필요하다. 하지만 칼슘보충제로 섭취 시 칼슘의 생체이용률이 낮으므로 이를 개선하기 위한 연구가 진행되고 있다. 층상형 이중층수산화물(layered double hydroxide: LDH)은 층간에 다양한 음이온들을 삽입할 수 있고 독성이 낮은 것으로 알려져 있어 약물이나 생리활성물질의 전달매체로 응용하고자 활발히 연구 개발되고 있는 물질이 다. 본 연구에서는 칼슘을 포함하는 LDH 구조물(CaAl-LDH)을 합성하고, 이의용해 안정성과 소장에서의 흡수를 효율 적으로 조절하기 위하여 폴리머 코팅(E-coated CaAl-LDH)을 진행하였다. XRD 측정 결과폴리머 코팅에 의해 CaAl-LDH의 결정형 구조가 변형되지 않았으며, SEM 관찰에 의해 코팅 후에도 크기 및 형태가 유지됨을 확인하였다. 위액 모사조건에서 용해도 분석 결과 폴리머 코팅에 의해 칼슘이온의 용해가 감소하는 것을 확인하였으며, 이로써 소 장에서의 칼슘 흡수를 향상시킬 수 있을 것으로 보인다. 장관세포 및 마우스에 단회 경구투여 결과 세포독성 및 급성 독성을 나타내지 않았으며, 약동학적 분석 결과 체내 칼슘 흡수율이 향상될 수 있음을 알 수 있었다.이러한 연구는 CaAl-LDH 나노소재의 폴리머 코팅을 통해 체내 안정성과 흡수율 향상을 유도할 수 있어 칼슘보충제로서의 잠재적 활 용 가능성을 제시한다.

A formation of aluminum hydroxide by hydrolysis of nano and micro aluminum powder has been studied. The nano aluminum powder of 80 to 100 nm in diameter was fabricated by a pulsed wire evaporation (PWE) method. The micro powder was commercial product with more than in diameter. The hydroxide type and morphology depending on size of the aluminum powder were examined by several analyses such as XRD, TEM, and BET. The hydrolysis procedure of micro aluminum powder was different from that of nano aluminum powder. The nano aluminum powder after immersing in the water was transformed rapidly to a nano fibrous boehmite, accompanying with a remarkable temperature increase, and then further transformed slowly to a stable bayerite. However, the micro powder was changed to the stable bayerite slowly and directly. The formation of fibrous aluminum hydroxide from nano aluminum powder might be due to the fine cracks which were formed by hydrogen gas pressure on the surface hydroxide layer during hydrolysis. The nano powder with large specific surface area and small size reacted more actively and faster than the micro powder, and transformed to meta-stable hydroxide in relatively short reaction time. Therefore, the formation of fibrous boehmite is special characteristic of hydrolysis of nano aluminum powder.

This study investigated that the reconstruction process of calcined Mg-Al layered double hydroxide in distilled water or calcium hydroxide solution for 3 days. The ATR-FTIR (Attenuated total reflection-Fourier transform infrared spectroscopy) was used for analysis of the reconstruction process. The results showed that the reconstruction of the calcined layered double hydroxide was almost completed within 1 day.

외핵은 대부분 철로 이루어져 있으나 외핵의 밀도를 10% 정도 줄일 수 있는 희석 원소가 존재해야 한다. 외핵에서 존재할 가능성이 있는 가벼운 희석원소가 수소와 산소라는 가정 하에, 고압 하에서 수소의 열역학적 안정성을 적철석(Fe2O3) + 수소(H2) → 괴타이트(FeOOH) + 철(Fe) 반응관계식을 이용하여 계산하였다. 열역학적 해석 결과, 상온 및 상압에서 이러한 화학반응의 깁스자유에너지는 12.62 kJ/mol로 계산되었다. 상온에서 압력이 증가함에 따라 깁스자유에너지 값은 감소하여 0.068 GPa에서 '0 kJ/mol'을 나타내었다. 압력이 증가함에 따라 깁스자유에너지 값은 일정한 비율로 점차적으로 감소하여 200 GPa에서는 -208.26 kJ/mol을 나타내었다. 이러한 열역학적 분석 결과로 볼 때 고압 하에서 수소와 철산화물이 반응하여 철원소와 철 수산화물을 생성하는 환원반응이 선호되며, 수소와 산소가 철수산화물의 형태로 원시지구 핵 내에 존재하게 되었을 가능성을 배제할 수 없다.