Film Production Research Articles

Production of bioplastic films from wild cocoyam (Caladium bicolor) starch

This study tackles the pressing environmental challenges resulting from the rapid and ongoing use of conventional plastics by investigating biodegradable alternatives derived from wild cocoyam starch. The bioplastics developed from various formulations, incorporating gelatin, glycerine, vegetable oil, and vinegar, were systematically evaluated for their mechanical, chemical, microstructural and biodegradability properties. The addition of glycerine and gelatin enhanced the moisture content and flexibility of the films while vegetable oil improved water resistance, reducing water absorption. Th sample that contains 3 g of gelatin and 3 ml of glycerine exhibited the best overall performance with a tensile strength of 6.5 MPa and an elongation at break of 77 %. This sample also achieved an impressive biodegradation rate of 70 % within 7 days. Scanning Electron Microscopy revealed a uniform and smooth morphology, while Fourier Transform Infrared Spectroscopy confirmed the presence of key functional groups responsible for the material's performance. These results establish wild cocoyam starch as a promising resource for producing biodegradable bioplastics with considerable potential in various industries, particularly in packaging and agricultural applications. The excellent mechanical properties and biodegradability of the materials along with its natural abundance, offer an eco-friendly solution to the plastic waste problem. The study also opens new avenues for optimizing bioplastic formulations to enhance specific properties like thermal stability and moisture resistance, further broadening their practical applications. This research contributes to the sustainable materials landscape and represents a step toward reducing reliance on fossil-based plastics, advancing the global effort to mitigate environmental pollution.

Research On the Impact of Pop Music In 2000s Films: Shaping Youth Culture Through Soundtracks

This research delves into the profound impact of pop music on youth-oriented films of the 2000s, examining aspects such as cultural representation, emotional connection, and financial gains. The introduction underscores the critical importance of this topic in understanding how media shapes youth culture and influences societal perceptions. By focusing on iconic films like "High School Musical" and "Mean Girls," the study illustrates how pop music is used to enrich narratives and captivate audiences, making it an integral part of the storytelling process. The analysis reveals several key issues, including cultural homogenization, the reinforcement of stereotypes, and the prioritization of commercialization over artistic integrity. These challenges highlight the need for a more thoughtful integration of music in films to avoid superficial portrayals and promote authenticity. To address these issues, the research recommends expanding the range of musical themes to reflect diverse cultures and experiences, breaking away from stereotypes to foster more nuanced character portrayals, and balancing commercial objectives with creative expression in future film productions. The conclusion emphasizes the significance of this research in guiding media practices toward greater cultural diversity in youth-oriented entertainment. By adopting these recommendations, filmmakers can create richer, more diverse content that resonates emotionally with audiences while also contributing positively to the cultural landscape.

Thin film synthesis and photovoltaic performance of polypyrrole@cobalt hydroxide composites for solar cells and optoelectronic devices

Mono-nanocomposites (MNCs) comprising polypyrrole (PPy) and cobalt hydroxide nanoparticles (Co(OH)2 NPs) are emerging as highly favorable contenders for applications in solar cells and optoelectronic devices, owing to their distinctive attributes encompassing robust light absorption, elevated conductivity, and commendable chemical stability. This investigation delves into the production of a thin film [PPy@Co(OH)2]MNC utilizing the physical vapor deposition (PVD) method. The structural and morphological characteristics of the [PPy@Co(OH)2]MNC thin film were scrutinized through X-ray diffraction (XRD) and scanning electron microscopy (SEM). Optical properties, namely reflectance (R), absorbance (Abs), and transmittance (T) within the UV–vis–NIR spectrum, were precisely gauged at room temperature. Time-dependent density functional theory (TD-DFT) calculations and optimizations were conducted to analyze the geometric parameters, while the refractive index dispersion was probed using the single oscillator Wemple-Didomenico (WD) model. Additionally, the energy of a single oscillator and the energy of dispersion were quantified. The [PPy@Co(OH)2]MNC thin film exhibited pronounced light absorption across the UV–vis–NIR spectrum, characterized by a bandgap of 1.6 eV. The Au/[PPy@Co(OH)2]MNC/p-Si/Al heterojunction device demonstrated a power conversion efficiency and fill factor (FF) of 2.6 % and 55.07 %, respectively, under an irradiance of 100 W/cm2. The findings of this investigation underscore the potential of [PPy@Co(OH)2]MNC-based thin films as auspicious candidates for deployment in solar cells and optoelectronic devices.

Intelligent Packaging Systems with Anthocyanin: Influence of Different Polymers and Storage Conditions

With the aim of meeting the growing demand for safe food, intelligent packaging has emerged, which monitors the conditions of the food and informs the consumer about its quality directly at the time of purchase. Among intelligent packaging options, colorimetric indicator films, which change color in response to changes in the food, such as the release of volatile compounds, have been widely studied. Among them, pH indicator films composed of dyes sensitive to small variations in the pH value of the food surface have received greater attention in recent years. Anthocyanins, which are natural pigments, have stood out as one of the most commonly used sources of dyes in the production of these indicator films. In this context, the present review aims to present an updated overview of research employing anthocyanins in indicator films, including their stability under different storage conditions, the influence of different polymers used in their production, and alternative techniques for maintaining stability.

Storage Potential of Cactus Mucilage Powder for Incorporation into Foods and Production of Biopolymeric Films.

The objective was to investigate the physicochemical stability of stored cactus pear mucilage and assess the technological feasibility to produce polymeric films. Mucilage of cactus pear species Nopalea cochenillifera (L.) Salm-Dyck MIU and Opuntia stricta (Haw.) Haw-OEM was extracted and stored for 2, 4, 6, 8, and 10 months in the absence of light at a temperature of 26.5 °C and relative humidity of 41.3%. At each storage time, polymeric films were produced using hydrated mucilage (4%, weight-w/volume-(v)), glycerol (60%, v/v), and calcium lactate (2%, w/v). Among the species, MIU stood out due to its higher water and oil retention, but it also presented higher levels of phenolic compounds, and more intense peaks in Fourier transform infrared spectrophotometry (FTIR) analysis. On the other hand, OEM is richer in carbohydrates, denser, and electrically conductive. The characteristics highlighted for each species are also observed in the principal component analysis (PCA). Both species are equally soluble in water, and more than 60% of their granules have a diameter of 250 mm. The resulting films of MIU exhibited increased resistance and permeability but were less soluble and transparent. Microscopically, greater homogeneity was observed, and the films were thicker, whitish, and thermally stable. Both species have the potential for producing polymeric films with various applications in the food industry, particularly as edible coatings.

A new method for growing epitaxial films on foreign substrates − Bent epitaxy

In recent years, to mitigate the effects of climate change, countries’ transition to the green economy has accelerated, and thereby, the demand of semiconductor industry for wide-gap semiconductors such as SiC and GaN has increased dramatically. These semiconductors are expensive. To reduce the price of the final product, industrial production of thin epitaxial films of sought-after semiconductors on accessible and cheap substrates, such as Si and sapphire, is being developed. When growing epitaxial films on foreign substrates, the resulting heterostructure bends, becomes concave or convex, due to a mismatch between the coefficients of thermal expansion (CTE) of the substrate and the epitaxial film. As a result, the quality of the epitaxial film deteriorates and further processing of the resulting heterostructures in production lines becomes difficult or even impossible. The essence of the proposed new method is that the epitaxial film is grown not on a flat, but on a pre-curved substrate with the expectation that after cooling the fabricated heterostructure to room temperature, the heterostructure will take a flat shape due to the difference in the CTE of the epitaxial film and the substrate. A round bimetallic plate, located under the substrate, bends the substrate in the required direction to the desired value at the growth temperature, and gradually reduces the bend of the fabricated heterostructure during cooling, in proportion to the thermal contraction of the epitaxial film. This allows obtaining qualitative and flat epitaxial films, regardless of the material of the substrate or epitaxial film and the diameter of the substrate or thickness of the epitaxial film, without any buffer layers or carrying out any additional operations and costs.

Research on the Strategy of Film and Television Operation Management Mode

At this stage, with the rapid development of the film industry, more and more film and television works have emerged, mainly films, TV series, and online dramas. The film industry is an important part of the cultural industry of various countries. Analysing the operation mechanism of the film production management model will help the prosperity and development of the film industry. The research is mainly about the operation and management mode of the film and television industry. It uses the methods of searching for literature, searching on the Internet, and finally summarises the steps and strategies of film and television operation. The operation steps of film and television mainly include four links: shooting, production, distribution, and screening. Each link is quite important and needs to be carefully arranged and operated, with a strong team and psychological quality to deal with various emergencies. It must invest much money and energy in every step to complete perfect work and create profits in the final release. The operation of film and television is still advancing and will continue to develop new models and update strategies to meet the development of the times.

Precursor Ink Engineering to Implement Vacuum Extraction Method for Scalable Production of Perovskite Solar Cells.

Engineering perovskite precursor ink to widen the processing window is crucial to obtaining uniform, compact, and pinhole-free perovskite films at scale using industrially relevant solution coating techniques. Here, we introduce a ternary solvent system and systematically investigate the impacts of coordinating solvents, N-methyl-2-pyrrolidone (NMP) and N,N'-dimethylpropyleneurea (DMPU), on the physical properties of the slot-die-coated perovskite films and on the corresponding device performance. Tailoring NMP and DMPU concentrations in the precursor ink allows us to control the perovskite intermediate phase formation and widen the processing window, enabling the reproducible production of perovskite films with high photoelectrical quality at scale. Using the optimized precursor ink, we demonstrate slot-die-coated perovskite minimodules with power conversion efficiencies of 19 and 16% on 56 and 100 cm2 substrates, respectively.

A Versatile InF3 Substituted Argyrodite Sulfide Electrolyte Toward Ultrathin Films for All‐Solid‐State Lithium Batteries

AbstractAll‐solid‐state lithium batteries (ASSLBs) incorporating sulfide solid electrolytes capture great attention due to their intrinsic safety features and high energy density. Nevertheless, the implementation of sulfide solid electrolytes faces significant challenges, including moisture sensitivity, narrow intrinsic electrochemical windows, and excessively thick solid electrolyte layers. Here, the substitution of In for P and F for Cl in argyrodite sulfide Li5.7PS4.7Cl1.3 is presented. With appropriate elemental substitutions, the Li symmetric cells exhibit a high critical current density value of 2.5 mA cm−2 and deliver prolonged plating/stripping over 1000 h at 1 mA cm−2 and 25 °C. Further, the Li5.82P0.94In0.06S4.7Cl1.12F0.18 displays high chemical stability toward organic solvents, which is further demonstrated by the density functional theory (DFT) calculations. Using polyisobutylene as a binder, a uniform sulfide film (35 µm) is prepared by slurry casting and hot pressing process, delivering a high ionic conductivity of 1.4 mS cm−1 at 25 °C. Coupled with FeS2 and LiCoO2 cathode, the all‐solid‐state lithium metal cell exhibits a long cycling life and excellent rate performance. This study provides a design strategy and reveals the importance of high‐performance sulfide SEs in the scalable production of sulfide film.

Co-immobilization of lipase and β-galactosidase in gelatin-carboxymethyl cellulose blend films used as an active packaging component

β-Galactosidase and lipase were co-immobilized in polymeric blends of gelatin (GEL) and carboxymethyl cellulose (CMC) synthesized with different ratios of GEL/CMC: A (0GEL:100CMC), B (25GEL:75CMC), C (50GEL:50CMC), D (75GEL:25CMC), E (100GEL:0CMC). The films obtained good electrostatic interaction and a regular and uniform structure. The addition of CMC increased the mechanical resistance of the films, the tensile strength being 35.04 ± 0.10 MPa for A (0GEL:100CMC) films and 19.17 ± 2.44 MPa for E (100GEL:0CMC) films. Thermogravimetry (TG) showed that the addition of the enzyme decreases the thermal stability of the films. Film B (25GEL:75CMC) showed greater affinity with the added enzymes and greater thermal stability, in addition to increasing the crystallinity by up to 5.8 % and forming more transparent films. CMC was the most hydrophilic polymer, with higher moisture content (17.35 ± 1.73 %) and PVA (0.398 ± 0.047 g.mm/h.m2.kPa), higher still after the addition of enzyme (22.91 ± 1.06 % and 1.136 ± 0.087 g.mm/h.m2.kPa). The enzymes showed greater interaction with the bulky groups of CMC and the film with the highest concentration of this polymer was the one that presented the best hydrolysis rate of lactose and triglycerides, enabling the production of films.

Supercritical Fluid for Retama Raetam Porous Film Production: A Strategy for Advancing Drug Dosage

Supercritical Fluid for Retama Raetam Porous Film Production: A Strategy for Advancing Drug Dosage

Insights into Surfactant-Induced Aggregation and the Production of White Light-Emitting Thin Films from Cellulose-Derived Carbon Dots

Insights into Surfactant-Induced Aggregation and the Production of White Light-Emitting Thin Films from Cellulose-Derived Carbon Dots

Green Packaging Films with Antioxidant Activity Based on Pectin and Camellia sinensis Leaf Extract.

In the packaging materials sector, increasing globalization has created the need for increased efforts to develop consumer protection measures. Consequently, new packaging materials are being sought to replace petroleum-based materials in the future. For this reason, global awareness of the environmental problems associated with the use of synthetic and non-degradable packaging has increased the attention paid to bio-packaging based on natural and biodegradable polymers. The bio-packaging sector is developing innovations to address the sustainability issues facing the food packaging industry. Our research has shown that green matcha extract can be a promising source of antioxidants for the production of bioactive pectin films. This study further confirmed that green matcha extract can be a promising source of antioxidants for the production of bioactive pectin films. The antioxidant activity test showed high activity of films containing matcha extract. The antioxidant activity of films without matcha addition, P, PJ, PC, PJC, was negligible. The addition of matcha to the polymer matrix did not significantly affect the mechanical properties (TS, EB) of the films obtained. The addition of cellulose had the greatest effect on changing the mechanical properties. It caused a twofold increase in the mechanical properties of the obtained packaging films. The addition of matcha significantly improved the barrier properties (for PM films, the WVTR was 3.40 [g/m2d]; for PJM films the WVTR was 1.70 [g/m2d]). The green packaging films showed no toxic effects on the plants (Phacelia tanacetifolia, Salvia hispanica, Brassica napus) and invertebrates (Daphnia pulex, Chaoborus, Chironomus aprilinus) tested. The half-solubility time of the membranes in a solution mimicking gastric acid was also determined. The longest half-dissolution time of the films was about 2 min. Our research has therefore shown that the biodegradable and environmentally safe green packaging films with antioxidant activity that we have developed can be used as edible functional casings in the future, e.g., for sausages and other food products.

The Kinomatics Australian Film Production Dataset: A Curated Dataset Describing Australian Feature Film Titles and Personnel 1975–2022

Abstract This article presents a novel, extensive, and thoroughly documented dataset describing Australian feature films and the personnel filling ten key production roles on those films. The dataset is curated from public information in multiple sources and draws on further supplemental resources to verify, validate and consolidate this information. In total, the data describes 22,720 roles filled by 9,397 distinct people across 1,877 films, covering an important 47-year period in the Australian film industry. The authors outline how the dataset solves several problems for scholars interested in data that provides a historical record of the collaborative filmmaking process. In particular, to address concerns about known coverage problems with popular sources such as the Internet Movie Database, this dataset has undergone extensive manual checking to ensure that it is reliable as a source of information on a national film industry. Moreover, the authors have carefully and manually linked each person appearing in the dataset, which allows the dataset to provide a rich source of information for exploring the relationality of filmmaking collaborations. The inclusion of ten key filmmaking roles further expands the utility of the dataset beyond existing datasets which tend to focus on actors and/or directors, writers and producers.

Representaciones de Cali en el cine documental de los años veinte

The film production that began to be carried out in the city of Cali during the twenties was registered, very well, with the modernizing spirit that the elites wanted to implement in the city because, they saw in the cinema, an opportunity to project an image of a modern and cosmopolitan city.This article seeks to analyze two documentaries that were produced the first in 1926, "El Valle del Cauca y su progreso" and the second: "Las Olimpiadas de Cali" in 1928. Both share a view of the city in which industries, residential neighborhoods and sites considered emblematic such as churches, squares, monuments, etc. are privileged.In addition to the aspects of urban infrastructure, there is an idea of progress that goes through body hygiene, especially in the second documentary, where the importance of sport and physical education as a fundamental instrument for the development of the race is emphasized.

From multilayer LDPE/EVOH flexible film scraps to new multilayer films

This study explores the mechanical and optical properties of multilayer films incorporating recycled materials, mimicking the structure of industrial films. Using a coextrusion blown film line with a three-layer ABC configuration extrusion head, films were produced using two different recycled multilayer films, from post-industrial scraps, in layers A and B and virgin low-density polyethylene (LDPE) in one of the external layers (C). These recycles result from multilayer films mainly constituted of LDPE; one has also linear-LDPE (LLDPE) Metallocene, and the other has Ethylene Vinyl Alcohol (EVOH). Both recycled materials enabled to maintain blown film extrusion process stability during film production. The multilayer films produced with the incorporation of recycles were characterized using scanning electron microscopy (SEM), haze and gloss measurements, and tensile tests. Films with Recycled EVOH presented haze values much higher than those obtained for the Recycled Metallocene. However, all films presented good mechanical properties when compared to single layer virgin LDPE film. Anisotropic behaviour was observed, emphasizing the directional dependence of mechanical properties. The findings provide insights into the behaviour of multilayer films with recycled content, offering valuable information for the development of sustainable packaging solutions.

Fight Like Girls: The Stuntwomen of Bond

In their 2015 article on stuntwomen, Miranda J. Banks and Lauren Steimer argue that the figure of the stunt double is subjected to a process of erasure throughout the production of the action film or series, and most certainly in popular press accounts that promote the idea of stars (both male and female) as the performers of their own stunts. This erasure is also evident in the comparative lack of scholarly work on the labour-intensive – and often life-threatening – contributions made by stunt performers to the on-screen fantasy of the kick-ass action star. The Bond franchise has seen its female characters increasingly defined by their all-action credentials and, consequently, the size of the stunt team has grown with a higher number of female stunt performers being included. This article looks at how stuntwomen have contributed to the spectacle of the Bond franchise, including driver Jessica Hawkins and the much in demand Marie Mouroum, both of whom worked on No Time to Die (2021). As behind-the-scenes footage of most action franchises becomes more available and often forms part of the marketing of franchise cinema, including the Bond films, the concept of erasure will be examined in relation to these contemporary contexts of production. The increased diversity of action heroines also opens up sites of exploration around women of colour as part of these production processes, both on-screen and behind the scenes.

An in-depth study of the synthesis of ReSe2 for anisotropic Raman characteristics

Abstract Two-dimensional transition metal dichalcogenides (TMDs) have received more interest for their potential role in future electronic and optoelectronic applications. Unlike other TMDs, Rhenium diselenide (ReSe2) stands out for its distinctive anisotropic growth characteristics. These unique features arise from its low lattice symmetry and interlayer decoupling, this has sparked significant interest among researchers. Previous research has indicated the presence of various growth patterns, including dendritic formations and structures resembling flowers. In this study, we effectively produced ReSe2 using the ‘Tilting Boat’ method to achieve growth on a 21 μm scale. Through precise manipulation of the growth conditions, we successfully attained flakes of 21 μm scale in comparison to prior findings. Moreover, we successfully produced a variety of shapes, including triangles, diamonds, and hexagons, on 1 × 1 cm2 Si/SiO2 substrates. Furthermore, we achieved the successful production of a continuous ReSe2 film on a 1 × 3 cm2 Al2O3 substrate. We verified the distinct anisotropic properties of ReSe2 via Raman Spectroscopy. Furthermore, we acquired three-dimensional visual representations of ReSe2 flakes and continuous films via SEM measurements. By employing EDS data and analysing x-ray photoelectron spectroscopy spectra, we have established a compositional ratio of 1:2 for Re and Se, which aligns with the MX2 structure. This confirmation indicates the successful synthesis of high-quality ReSe2 flakes.

Towards electrochemical machining of powder superalloy René 88DT with high surface integrity in different solvent-based electrolytes

Electrochemical machining (ECM) presents numerous applications in the production of aero-engine components. The effects of current density on surface quality during ECM of René 88DT in NaCl-ethylene glycol and NaNO3-aqueous solutions was investigated here. The results indicated that the René 88DT surface has lower sensitivity to current density and more homogeneous electrochemical dissolution in NaCl-glycol solution than in NaNO3-aqueous solution, which results in the suppression of stray corrosion and consistently high surface quality regardless of current density. These strengths are attributed that C2H5O2- and Cl- ions replace OH– ions and combine with alloy ions to form solubles and complexes, which prevent the formation of obstructive passive film, oxide layer, and insoluble electrolytic products. The electrochemical dissolution model in two solutions was established. Furthermore, the high tensile strength and precision machinability of René 88DT in NaCl-glycol solution were also demonstrated.

Film and Television Animation Production Technology Based on Expression Transfer and Virtual Digital Human

The world of film and TV animation has witnessed a revolutionary transformation with the combination of Expression transfer and digital virtual Human technology. This paper delves into the superior methodologies and technological improvements in the discipline of animation production, especially specializing in how those technology are redefining the requirements and practices of animation in film and television. Expression transfer technology, a groundbreaking approach in animation, entails the transfer of facial expressions from real actors to lively characters. This technique not most effective enhances the realism of lively characters but additionally lets in for a extra nuanced and emotive performance, bridging the space among conventional animation and stay-action performances. Digital Human era, however, entails creating extraordinarily practical virtual representations of people. Those digital humans aren’t mere caricatures or stylized variations however are reasonable in appearance and movement, way to advancements in motion seize, 3-D modeling, and synthetic intelligence. The mixture of those technologies is main to a new technology in animation where characters aren’t only visually stunning however also exhibit a depth of emotion and realism previously unimaginable. This paper explores diverse case research and applications of these technology in current animation, highlighting their effect on storytelling, person improvement, and viewer engagement. It also addresses the demanding situations and moral considerations in employing these technologies, which includes retaining artistic integrity and the capacity for misuse. The research concludes with a forward-searching attitude on how Expression transfer and digital digital Human technologies are set to redefine the future of movie and television animation, presenting new opportunities for creative expression and narrative intensity.