Bangladesh enjoys an advantageous geographical position. It has been a transit station for businessmen from South Asia, Southeast Asia, Central Asia and even Europe since ancient times. It is located at the intersection of China Economic Circle, South Asia Economic Circle and ASEAN Economic Circle, and is an important country along the belt and road initiative. The “Belt and Road” initiative was supported by Bangladeshi Prime Minister Sheikh Hasina. Since the “Belt and Road” initiative was put forward, China and Bangladesh have achieved remarkable results in policy communication, facility connectivity, smooth trade, capital financing and people-to-people communication. However, China and Bangladesh still face challenges in the political, security, economic and social fields to jointly build the “Belt and Road” initiative. In the new period, China and Bangladesh should strengthen political communication, promote the docking of China-Bangladesh development strategies, strengthen facility connectivity and industrial cooperation, promote cultural exchanges, promote the upgrading of cooperation between the two countries, and jointly build a high-quality “Belt and Road” initiative.

범밀도이론함수(Density Functional Theory, DFT) 기반의 제일원리전산모사는 기저상태의 DFT 에너지를 구하는데 많은 시간소요 및 전산자원을 소모하였다. 이러한 막대한 전산자원의 소모는 DFT 계산에서 고려할 원자수를 수 백개 이 하로 제한되게 되었으며, 이를 해결하기 위해서는 전자구조 계산이 아닌 원자의 환경 내에 원자간 상호작용을 정의 (Force Field, 힘장)하고 이를 통해 주어진 조성 혹은 구조에 따른 에너지를 빠르게 예측 할 수 있어야 한다. 본 논문에서 는 Behler-Parrinello가 제시한 인공신경망 모델을 활용해 인공지능 다원계 힘장을 개발하고 코발트-구리 산화물의 조성에 따른 에너지를 예측하고 안정한 구조를 탐색하는 연구를 수행하였다. 인공신경망 기술로 부터 구리-코발트 산화물에 대 해 15.7 meV/atom의 에너지 오차와 단위거리당 힘 103.6 meV/Å의 정확도를 가지는 인공신경망 포텐셜을 개발하였다. 이 방법으로 빠르고 정확하게 CuCoO 표면구조의 산소 결함률에 따른 생성에너지를 계산할 수 있었고, 에너지 컨벡스 홀을 도시 조성에 따른 안정한 구조를 예측하였다.

The electrical resistances of small-sized activated carbon fiber (ACF) fabric (specific surface area: 1244.7 m2/ g, average pore diameter: 1.92 nm) and felt (specific surface area: 1321.2 m2/ g, average pore diameter: 2.21 nm) sensors were measured in a temperature and humidity controlled gas chamber by CO2 adsorption at different surrounding CO2 concentrations (3000–10,000 ppm). The electrical resistances of ACF sensors decreased linearly as the increase of temperature and decreased exponentially as the increase of humidity in the ambient atmospheric chamber. The electrical resistances of ACF rapidly decreased within 4 s and an equilibrium state was achieved within 10 s due to the very rapid CO2 adsorption at room temperature and 40% humidity. Comparing the difference in electrical resistance values measured during injection of similar concentrations of CO2 after reaching the equilibrium value, the fabric exhibited a significant change, whereas the felt did not, even though it had a relatively larger specific surface area. The reason is that micropore volume greatly affected the amount of CO2 adsorbed, whereas the specific surface area did not affect it as much. Therefore, ACF fabric with large micropores (> 2.0 nm) can be developed and used as CO2 sensors in small rooms such as a passenger vehicles.

Herein, a new and generic strategy has been proposed to introduce uniformly distributed graphitic carbon into the nanostructured metal oxide. A facile and generic synthetic protocol has been proposed to introduce uniformly distributed conducting graphitic carbon into the Co3O4 nanoparticles ( Co3O4 NPs@graphitic carbon). The prepared Co3O4 NPs@graphitic carbon has been drop casted onto the portable screen-printed electrode (SPE) to realize its potential application in the individual and simultaneous quantification of toxic Pb(II) and Cd(II) ions present in aqueous solution. The proposed Co3O4 NPs@graphitic carbon-based electrochemical sensor exhibits a wide linear range from 0 to 120 ppb with limit of detection of 3.2 and 3.5 ppb towards the simultaneous detection of Pb(II) and Cd(II), which falls well below threshold limit prescribed by WHO.

본 연구에서는 순수 PEBAX® 분리막의 투과특성을 향상시키기 위해 개질된 fumed silica 나노입자를 혼합한 MMMs (mixed matrix membranes) 타입의 PEBAX®/fumed silica 하이브리드 분리막을 제조하고, 이산화탄소와 메탄의 투과 특성을 측정하였다. PEBAX®-1657/TS-530 하이브리드 소재의 경우, FT-IR과 XRD 분석을 통해 PEBAX® 고분자에 무기입자 가 비교적 잘 분산되었음을 확인하였다. 기체투과특성 측정 결과 TS-530을 10 wt% 혼합한 분리막의 경우, 순수 PEBAX® 분 리막과 비교하여 투과도 계수는 약간 감소하나 이상분리인자는 약간 증가하였다. 이는 비투과성 silica 입자의 도입에 따라 기 체 확산 경로가 줄어들고, 경로의 비틀림이 증가하기 때문으로 볼 수 있다. TS-530 함량이 증가함에 따라서는 투과도 계수와 이상분리인자 간에 전형적인 trade-off 경향을 보였다. 이는 TS-530 함량이 증가함에 따라 결정성이 감소하고, 고분자 사슬 간 충전 억제에 따라 자유부피가 증가하기 때문으로 볼 수 있다. 또한 무기입자 함량 증가에 나노간극의 형성 가능성이 높아지 고, 이에 따라 기체 확산도가 커지기 때문으로 판단된다.

The present study analyzed the pore formation and development process in carbon black that was activated by CO2 gas and the effect of the burn-off (BO) ratio on the process, particularly based on changes in the surface shape and internal microstructure. The activation process was performed as follows. Carbon blacks were injected into a horizontal tube furnace when the inside temperature reached 1000 °C. Carbon black samples with different BOs, i.e., 7.2%, 15.4%, 30.4%, 48.2%, 59.9%, and 83.2%, were prepared by varying the activation time. The microstructure of the activated samples was observed and examined using SEM and TEM. The results showed that pore passages were first created on the surface of the primary particles of the carbon black, and then the inner portion of the carbon black with a lower degree of crystallinity started to be activated, thereby causing inner pores to be formed. These inner pores then started to grow and coalesce into larger pores, thereby causing the crystallite layers in the inner portion of the carbon black to be activated. The changes in the microstructure of the carbon black during the activation reaction were attributable to the carbon black manufacturing process, in which the nucleation and growth of the primary particles of the carbon black occurred within a very short period of time. Thus, the crystallization of the inner portion was suppressed, and therefore, the degree of crystallinity was lower in the inner portion than in the outer portion.

Global warming and climate changes are the ultimate consequences of increased CO2 volume in the air. Physical activation was used to prepare high-throughput activated carbon from a low-cost date stone. The adsorption performance of activated carbon using fixed bed for CO2 separation was studied. The reliance of temperature, flow rate, and initial CO2 concentration levels on breakthrough behaviour was analysed. The adsorption response was explored in terms of breakthrough and saturation points, adsorption capacity, temperature profiles, utilization factor, and length of mass-transfer zone. Increased temperatures lead to vary the breakthrough periods notably. The vastly steep breakthrough curves reveal satisfactory utilization of bed capacity. LMTZ is varied positively with increased feed rates and temperatures. The high utilization factor of 0.9738 with 1.66 mmol/g CO2 uptake was acquired at 298 K and 0.25 bars. The findings recommend that the carbon prepared from date stone is encouraging to capture CO2 from CO2/ N2 mixture.

대표적인 상업화된 박테리오신인 나이신은 Listeria monocytogenes 및 Staphylococcus aureus와 같은 병원성 세균에 대해 강력한 항균 활성을 보인다. 본 연구에서는 시판되는 나이신 제품을 박테리오파지 SAP84와 함께 병용 처리했을 때 S. aureus 억제에 대한 상승효과에 대하여 평가했다. S. aureus KCTC 3881 균주에 대해 나이신은 농도의존적으로 생균수를 감소시켰으며 18 IU/mL의 나이신은 대조구와 비교하여 6시간째에 4.03 Log CFU/mL의 균수가 감소된 반면, 동일 용량의 나이신이 박테리오파지 SAP84 (0.1 MOI)와 병용처리 되었을 때 5.54 Log CFU/mL의 생균수 감소가 관찰되었다. 또한 나이신과 SAP84 의 조합은 양상추에서 S. aureus 균주를 효과적으로 제어하는데 성공적으로 적용되었다.

As the size of market for electric vehicles and energy storage systems grows, the demand for lithium-ion batteries (LIBs) is increasing. Currently, commercial LIBs are fabricated with liquid electrolytes, which have some safety issues such as low chemical stability, which can cause ignition of fire. As a substitute for liquid electrolytes, solid electrolytes are now being extensively studied. However, solid electrolytes have disadvantages of low ionic conductivity and high resistance at interface between electrode and electrolyte. In this study, Li7La3Zr2O12 (LLZO), one of the best ion conducting materials among oxide based solid electrolytes, is fabricated through RF-sputtering and various electrochemical properties are analyzed. Moreover, the electrochemical properties of LLZO are found to significantly improve with co-sputtered Li2O. An all-solid thin film battery is fabricated by introducing a thin film solid electrolyte and an Li4Ti5O12 (LTO) cathode; resulting electrochemical properties are also analyzed. The LLZO/Li2O (60W) sample shows a very good performance in ionic conductivity of 7.3  108 S/cm, with improvement in c-rate and stable cycle performance.