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“5 Persuasive Reasons That Make ‘Andor’ on Disney+ Shine as One of the Top TV Series of the Past Ten Years”

# **Why *Andor* Stands Out in the Star Wars Realm: A Political Thriller Set in a Galaxy Far, Far Away**

The Star Wars realm is expansive, brimming with legendary lightsaber confrontations, grand space skirmishes, and the enigmatic Force. Nonetheless, *Andor*, the live-action series on Disney+, takes a unique direction. Crafted by Tony Gilroy, co-writer of *Rogue One*, *Andor* sheds the familiar Star Wars conventions of Jedi, Sith, and the Force, instead spotlighting the gritty, human aspects of rebellion and the perils of authoritarianism. As the series prepares for its second season, debuting on April 22, 2025, it remains distinguished not merely as a Star Wars reimagining, but as one of the finest political thrillers of the last ten years.

## **Investigating the Perils of Authoritarianism and the Value of Sacrifice**

At its essence, *Andor* is a narrative of defiance — not solely against a malevolent empire, but against the tangible threats of authoritarian rule. The Galactic Empire, which in earlier Star Wars episodes was often depicted as a nameless, monolithic evil, receives a more layered and chilling portrayal in *Andor*. The series probes into the mechanics behind how a fascist regime like the Empire functions, from its bureaucratic systems to its surveillance practices, and how it systematically quashes dissent.

Cassian Andor (portrayed by Diego Luna), the lead character, is neither a Jedi nor a prophesied hero. He’s an average individual, initially a petty criminal, who is drawn into the rebellion not by fate, but by necessity. His journey illustrates the sacrifices that people must endure when faced with overwhelming tyranny. The show underscores that resistance isn’t glamorous; it’s chaotic, perilous, and often demands personal sacrifice.

## **A Keen Emphasis on Political Intrigue**

One of the most captivating facets of *Andor* is its emphasis on political intrigue. While the Star Wars films frequently focus on grand battles and the hero’s odyssey, *Andor* adopts a more realistic perspective. The series dedicates considerable time to the corridors of power, examining the internal dynamics of the Galactic Senate and the Empire’s bureaucratic machinery.

Season 2 is poised to maintain this focus, consisting of 12 episodes that cover four years and lead up to the events of *Rogue One*. The storyline will be segmented into three-episode arcs, each illuminating various facets of the escalating rebellion and the Empire’s tightening hold on the galaxy. The series doesn’t merely portray the physical conflicts between rebels and the Empire; it also explores the ideological and political skirmishes occurring behind closed doors.

In the Senate, viewers witness how the establishment increasingly leans toward the regime, while prominent resistance figures covertly bolster and incite rebellion. Concurrently, everyday citizens across the galaxy are gradually confronting the Empire’s oppressive nature, as they endure surveillance, violence, and the suffocating weight of totalitarian governance.

## **Humanizing the Empire**

One of the most intriguing aspects of *Andor* is its ability to humanize the Empire. In most Star Wars narratives, the Empire appears as a nameless, villainous force — an organization of bad actors in black attire. While this is effective for the more fantastical elements of the franchise, *Andor* adopts a distinct approach. It not only illustrates the “what” of the Empire’s malevolence; it investigates the “why” and “how.”

Characters such as Dedra Meero and Syril Karn, Imperial officers, are given depth and nuance. They aren’t merely mindless antagonists; they are ambitious, calculating figures who believe in the Empire’s ideology. By spotlighting these characters, *Andor* illustrates that fascism isn’t solely about a singular malevolent leader (like Emperor Palpatine), but involves the multitude of individuals who sustain and foster the system. This renders the Empire more authentic and more terrifying, reflecting how real-world authoritarian regimes operate.

## **A Gritty, Realistic Take on Star Wars**

While numerous Star Wars enthusiasts cherish the saga for its grand space battles and lightsaber confrontations, *Andor* adopts a more realistic stance. There are no Jedi, no Sith, and no breathtaking exhibitions of the Force. Instead, the series concentrates on ordinary individuals — rebels, criminals, and bureaucrats — who find themselves entangled in the larger conflict between the Empire and the Rebellion.

This approach makes *Andor* feel more akin to a political thriller rather than a conventional Star Wars narrative. The stakes are personal and immediate, and the show does not shy away from portraying the stark realities of life under authoritarian rule. The characters in *Andor* aren’t larger-than-life champions; they are flawed, intricate individuals striving to navigate a perilous and oppressive landscape.

Researchers Create Technique for Producing Electricity from Styrofoam and Wind

# RMIT University Researchers Uncover Method to Generate Electricity from Styrofoam

### Introduction

Styrofoam, a material typically regarded as an ecological challenge due to its non-biodegradable characteristics, has recently been found to possess unexpected potential as a renewable energy source. A team of researchers at RMIT University in Australia has formulated an innovative technique to extract electricity from Styrofoam, transforming an ecological liability into a source of sustainable energy. This significant advancement could not only aid in waste reduction but also provide an economical, low-effort means of electricity generation.

### The Styrofoam Conundrum

Styrofoam, or expanded polystyrene (EPS), is extensively utilized in packaging, thermal insulation, and single-use food containers. Nevertheless, it is infamously difficult to recycle and can require as much as 500 years to break down in landfills. Its lightweight and robust properties render it a longstanding pollutant, exacerbating environmental damage and littering habitats. The finding by the researchers at RMIT University presents a novel approach to repurposing this troublesome material, potentially mitigating its ecological footprint.

### The Science Behind the Breakthrough

The cornerstone of electricity generation from Styrofoam is the **triboelectric effect**, a phenomenon where specific materials either gain or lose electrons upon contact. This phenomenon is commonly experienced as static electricity, such as the sensation felt when rubbing a balloon on hair or shuffling across a carpet and subsequently touching a metal doorknob. While static electricity is usually harmless and often overlooked in daily activities, the researchers at RMIT recognized an opportunity to utilize it for energy generation.

### Mechanism of Action

The RMIT research team created patches made from **polystyrene**, the very substance found in Styrofoam, which produce static electricity when subjected to moving air. These patches are strategically placed in locations with natural airflow, such as within heating, ventilation, and air conditioning (HVAC) systems. As air circulates through these systems, it generates friction with the polystyrene patches, thus producing small yet continuous streams of static electricity.

This produced electricity can then be harvested and transformed into usable power. Although the volume of electricity generated is modest, it suffices to help alleviate the energy demands of the HVAC systems, enhancing their energy efficiency.

### Potential Applications and Advantages

The prospective uses of this technology are immense. By situating Styrofoam patches in areas of natural air movement, such as within buildings, factories, or vehicles, small quantities of electricity could be generated consistently without requiring elaborate infrastructure or conventional energy sources like fossil fuels. This method could contribute to lowering energy expenses and bolster sustainability initiatives.

Some potential advantages of this technology include:

1. **Waste Reduction**: Bypassing Styrofoam as a renewable energy resource addresses the disposal waste issue. Instead of being sent to landfills, Styrofoam could find a practical use.

2. **Affordability in Energy Production**: The process involved in generating electricity from Styrofoam is relatively straightforward and cost-effective, making it appealing for budget-friendly energy generation.

3. **Enhanced Energy Efficiency**: By incorporating this technology into HVAC systems, structures could become significantly more energy-efficient, diminishing their total energy usage and carbon emissions.

4. **Eco-Friendly Approach**: This method of power generation is independent of conventional resources such as coal, oil, or natural gas, and it does not necessitate the establishment of large-scale power stations. It provides a sustainable option that could supplement other renewables such as solar and wind.

### Challenges and Constraints

Despite the promising nature of this discovery, there are still hurdles to surmount for broader implementation. The scale of electricity produced by Styrofoam patches is relatively limited, rendering it improbable to energize entire cities or major industrial enterprises. Nonetheless, it could be adopted for smaller applications, such as supplying power to individual buildings or compensating for the energy use of particular systems like HVAC units.

Moreover, the technology is still in the development phase, and further investigation is needed to enhance its efficacy and scalability. The RMIT team is actively looking for methods to boost the energy output of the polystyrene patches and to identify new domains where the technology could be employed.

### A Progression Toward a Sustainable Tomorrow

The revelation of electricity generation from Styrofoam marks a considerable advancement toward a more sustainable future. It introduces an innovative means to repurpose a material long deemed an environmental liability, thus transforming it into a renewable energy source. While this may not completely replace conventional energy sources, it could significantly contribute to waste reduction and energy efficiency.

As global efforts to mitigate climate change and lessen dependency on fossil fuels persist, innovations like this one inspire optimism for a cleaner, greener future. By creatively reimagining everyday materials, researchers are paving the way for a more sustainable planet.

### Conclusion

The RMIT University team’s finding regarding electricity generation from Styrofoam represents a groundbreaking advancement in renewable energy.

My Journey Shifting from the iPhone 14 Pro to the iPhone 16 Plus: Obstacles and Reflections

# iPhone 16 Plus Upgrade: 2 Suggestions to Consider if You Wish to Bypass the Pro

Transitioning to a new iPhone is always thrilling, but it can also feel a bit daunting, particularly when choosing between the Pro and standard models. With the introduction of the iPhone 16 series, numerous users are pondering whether they truly require the additional features of the Pro models or if the basic iPhone 16 or iPhone 16 Plus would be adequate.

Having spent over a month with the iPhone 16 Plus, I can assert that the transition from my iPhone 14 Pro was worthwhile, despite some early hesitations. In this article, I will outline two crucial factors to assess if you’re thinking about switching from a Pro model to the iPhone 16 or 16 Plus. These factors will assist you in determining if you can do without the Pro functionalities or if it’s best to remain with the premium models.

## 1. The Camera: Is Zoom Really Essential?

A notable distinction between the iPhone 16 Pro and the standard iPhone 16 models is the camera system. The Pro variants come with a 12-megapixel tetraprism zoom camera capable of up to 5x optical zoom, whereas the iPhone 16 and 16 Plus maintain a dual-camera layout devoid of advanced zoom features.

If you frequently utilize the zoom functionality on your current iPhone, this may be a crucial factor. However, after upgrading from the iPhone 14 Pro, which included a 3x optical zoom, to the iPhone 16 Plus, I discovered that I didn’t miss the zoom as much as anticipated. In fact, my use of the zoom on my previous phone was rare, and the dual-camera arrangement on the iPhone 16 Plus has more than fulfilled my photography requirements.

Before reaching a conclusion, I advise evaluating how often you use the zoom feature on your current device. If it turns out that you seldom use it, you might not require the additional camera enhancements offered by the Pro models. Conversely, if zoom photography plays a significant role in your mobile experience, you may want to consider the iPhone 16 Pro or Pro Max.

Moreover, the Pro models provide additional camera advantages such as Night Mode portraits, Apple ProRaw, Log video recording, and a four-mic array for superior audio capture. These features are excellent for professional photographers and videographers, but for the everyday user, the standard iPhone 16 camera system will likely suffice.

## 2. The Display: Can You Manage Without 120Hz?

Another major distinction between the Pro and non-Pro iPhones is the display. The iPhone 16 Pro models are equipped with a 120Hz ProMotion display, delivering smoother scrolling and animations compared to the 60Hz display on the iPhone 16 and 16 Plus. The ProMotion display also offers Always-On functionality, keeping vital information visible even when the phone is not active.

At first sight, switching from a 120Hz display to a 60Hz one may seem like a notable downgrade. However, I found the change to be less disruptive than anticipated. In fact, I had already deactivated the Always-On display on my iPhone 14 Pro to extend battery life, and I had adjusted the refresh rate to 60Hz for similar reasons. Thus, moving to the iPhone 16 Plus’s 60Hz display felt seamless, and I hardly noticed any significant change in everyday usage.

If you’re uncertain about your ability to forgo the 120Hz display, try this experiment: Access your iPhone’s settings to disable the Always-On display and switch the refresh rate to 60Hz. Use your device this way for a few days and observe if you perceive any significant differences. If the 60Hz display doesn’t bother you, then the iPhone 16 or 16 Plus may be a suitable option. If you realize that you miss the fluidity of the 120Hz display, then the Pro models may justify the additional expense.

It’s also important to mention that the ProMotion display adjusts its refresh rate dynamically based on user activity. This means that even on a Pro model, the display isn’t perpetually operating at 120Hz—it will only increase when optimal, such as during gaming or browsing content.

## Conclusion: Is the iPhone 16 Plus Satisfactory?

In the end, the choice between the iPhone 16/16 Plus and the Pro models hinges on your individual preferences and usage habits. If you are someone who appreciates advanced camera features and a high-refresh-rate display, the Pro models are probably worth the purchase. However, if you can manage without these enhancements, the iPhone 16 and 16 Plus should meet your needs.

Japanese researchers create hybrid cells combining plant and animal traits that can generate energy from sunlight.

### Japanese Researchers Develop Solar-Powered Hybrid Cells: A Game-Changer for Lab-Cultivated Meat and Organs

A team of scientists in Japan has achieved a remarkable breakthrough that has the potential to transform biotechnology and food science. A recent study published in the *Proceedings of the Japan Academy, Series B* reveals that researchers have successfully created tissues powered by solar energy, utilizing plant-animal hybrid cells. This pioneering method could greatly enhance the manufacturing of lab-cultivated meat and even human organs for transplantation purposes.

#### The Science Behind the Innovation

At the heart of this discovery is the combination of plant and animal cells. Generally, plants obtain energy via photosynthesis, a process that transforms sunlight into chemical energy, while animals generate energy through mitochondria via cellular respiration. The goal of the researchers was to merge these two energy-generation processes by incorporating chloroplasts—organelles responsible for photosynthesis in plants—into animal cells.

In their study, the team utilized cells from hamsters and sought to cultivate them alongside chloroplasts extracted from plant cells. The aim was to create hybrid cells capable of harnessing sunlight for energy in a manner akin to plants. After two days of cultivation, the researchers analyzed the cells for indications of chlorophyll, the pigment involved in capturing light during photosynthesis.

#### An Unexpected Victory

To their surprise, the researchers discovered that the hamster cells had accepted the chloroplasts. Utilizing a specialized laser, they confirmed the existence of chlorophyll within the animal cells. Additional tests using amplitude modulation fluorometry indicated that the chloroplasts were actively engaging in photosynthesis inside the animal cells. This achievement marked the inaugural instance of integrating photosynthetic electron transport into animal cells.

Even more astonishing was the finding that these solar-powered hybrid cells exhibited faster growth rates compared to conventional hamster cells. This hints that the introduction of chloroplasts might boost cellular growth, a revelation that could hold substantial implications across various scientific disciplines.

#### Potential Implications: Cultivated Meat and Organ Development

The success of this experiment opens a plethora of exciting opportunities for the future of biotechnology. One of the most immediate applications could relate to lab-cultured meat production. Traditional methods of growing meat in laboratory settings typically depend on supplying external nutrients to the cells, which can be both costly and resource-intensive. However, if cells can autonomously generate energy through photosynthesis, it could significantly diminish the reliance on external resources, making lab-cultivated meat more sustainable and economical.

Additionally, this novel approach could lead to advancements in regenerative medicine. The capability to produce tissues and organs more efficiently could significantly alleviate the global shortage of transplantable organs. Researchers have been pursuing methods to grow functional human tissues in lab settings, and this discovery could be a significant step toward achieving that aim.

#### A New Era in Biotechnology

Professor Sachihiro Matsunaga, one of the study’s authors, underscored the importance of this breakthrough: “This is the first occurrence of photosynthetic electron transport in chloroplasts being integrated into animal cells,” Matsunaga shared with *New Atlas*. The researchers are optimistic that this innovation could enhance prospects for organ cultivation and the production of lab-grown meat, both of which are fields of intense scientific focus.

Creating solar-powered tissues may have broader implications for sustainability as well. As the planet grapples with the environmental repercussions of conventional agriculture and meat production, lab-cultivated meat presents a promising alternative. Should these hybrid cells be scaled for commercial utilization, they could contribute to lower the carbon footprint associated with food production and foster a more sustainable future.

#### Obstacles and Future Research

Despite the encouraging outcomes of this study, numerous challenges remain before solar-powered tissues can become widely adopted. A significant obstacle lies in ensuring the longevity and functionality of chloroplasts within animal cells over extended periods. Moreover, researchers must investigate how these hybrid cells perform within more complex tissue constructs and whether they can be safely utilized in humans.

Further inquiry is also necessary to establish how this technology might be applied to various cells and tissues. For instance, can human cells be engineered to include chloroplasts, or is this technique confined to specific animal species? These questions will demand attention in forthcoming studies.

#### Conclusion

The creation of solar-powered hybrid cells signifies a pivotal achievement in the realms of biotechnology, regenerative medicine, and food science. By merging the energy-producing attributes of plants with the cellular functions of animals, researchers are unveiling new avenues for sustainable meat production and organ development. Although much work remains ahead, this breakthrough offers a vision of a future where lab-cultivated meat and organs can be generated more effectively and sustainably.

As researchers continue to probe the potential of this technology, we stand on the brink of a transformative era where the distinctions between plant and animal cells may merge, paving the way for innovations that could drastically change both medical and agricultural landscapes.