How to Accelerate 100 x – Lessons Learned from China’s Coronavirus Response

This week’s climate story brings us to China. To be more specific, to the construction site for a new hospital in the city of Wuhan. Wuhan is the center of the coronavirus outbreak and the new hospital is being built to isolate and treat people with the virus. Imagine construction noise day and night. Cranes are moving and workers are assembling pieces. The remarkable thing: They are building the hospital in 10 days. Yes, you read correctly, 10 days.

How can that be? In the US it takes years to build a hospital. Building a hospital in 10 days is less then 1% of time compared to a three-year timeline. How can China build a hospital 100 times faster in this emergency situation? What lessons can we learn? And what can we apply to the climate change emergency?

Lesson 1: Scale what works. The plans for the hospital were copied from a similar hospital, built in 2003 during the SARS virus outbreak. The modular design has prefab rooms that have been constructed in factories and just need to be assembled onsite.

There are many climate solutions that work and exist today. According to project drawdown some of the most important solutions are installing wind turbines, restoring tropical forests, and building solar farms. These solutions are there today, we need to copy, apply, and scale them.

Lesson 2: Rethink what doesn’t work. Basically, we are building hospitals the same way we have been for hundreds of years. The new hospital is not a full-service facility, its designed for a single purpose: Isolating and treating people with the coronavirus. They looked at what is needed and removed everything not needed. The planners rethought how this hospital is being used and how it’s being built. With razor sharp focus, they delivered exactly what’s needed, 100 times faster.

Electric cars are a powerful climate solution. If charged by renewables, carbon dioxide emissions fall by 95 percent. Tesla is an example of a climate solution that re-examined, focused, and modernized a product. Their goal was to make an electric car that’s better than a gasoline powered car. By rethinking the dashboard and replacing screens, buttons and the entire conventional dashboard of a car with only one screen, they saved time and money during production while modernizing the way we interact with cars.

Lesson 3: Share a vision. One of the reasons the hospital is being built so quickly is that everybody is working together with the shared vision to contain the virus. Policy, regulations, and funding work towards the same goal. And thousands of workers are building the hospital around the clock in only 10 days.

For climate solutions, funding, policy and people need to be aligned. Right now, a lot of funding and policy works against climate solutions. Seaweed, for example, is a promising climate solution. It captures greenhouse gases and can be used to produce sustainable food, feed, fertilizer and packaging. Yet, it’s incredibly hard to get permissions to start a seaweed farm. Carlos Duarte, a leading seaweed scientist said in an interview with National Geographic it might be easier to obtain a license for an oil rig than it is for seaweed farming. We need to mobilize funding, policy and regulations, and the people working on it towards the same goal.

The new hospital in Wuhan is an incredible accomplishment. There are questions about the sustainability of the prefab rooms as well as its usage after the outbreak. But what we can learn from China is how to respond to an emergency and then apply these principles to the climate emergency.

What do I like most about these lessons in acceleration? They give me hope. Imagine we could respond to the climate emergency 100 times faster than we thought was possible. We need to look at what works and scale it. We need to look at what doesn’t work, and modernize it. And most importantly, we need to all work together. I hope we can respond to the climate emergency faster and better than we ever imagined!

How Sustainable Air Conditioners Cut Greenhouse Gas Emissions

I just returned from visiting family in Egypt. We stayed in the desert, and it was hot! One day we were talking about air conditioners and they showed me their new desert cooler. What a fantastic and sustainable way to cool the air!

Traditional air conditioners produce tons of greenhouse gases, mostly during production and disposal of the chemical refrigerants. According to project drawdown, air conditioners, fridges and freezers are the number one solution to address global warming. If 87% of chemical refrigerants can be contained instead of released over the next 30 years, nearly 90 gigatons of emissions can be avoided. Designing sustainable cooling solutions seems not only brilliant but also necessary.

So what is a desert cooler? Also called evaporative cooler or swamp cooler, they cool down air by using fans and water. This is how it works:

Hot air gets blown through an evaporative pad and comes out as cool, moisturized air. Traditionally, materials such a as wood slivers, as shown in the photo above, were used in the evaporative pad. Now companies are experimenting with new materials and structures to get even better water evaporation.

Unlike air conditioners, desert coolers don’t require chemical refrigerants, they don’t heat up the outside air, and they need very little electricity. They cool the air by humidifying it, so they work best in dry areas, such as the south west US or the desert in Egypt.

And as always, I’ll highlight a startup or research team. This week’s team is Quilo, a group of engineers and product designers based in Hong Kong, China and USA. They successfully launched a Kickstarter campaign in 2017 and are now selling two different evaporative coolers. Having worked for big brands, they started their own company to focus on good design and user friendly product.

Our products are expertly designed to look great while providing energy-efficient performance.

https://quilohome.com/faqs/

While big home appliance companies seem to dominate the air cooler market, I’m excited to see how this startup develops and continues to innovate climate solutions for our homes.

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Can Our Streets Absorb Greenhouse Gases?

I wrote about driving to work before, wondering if we could cut emissions with sustainable fuels. Now I’m wondering – what about the roads we drive on?

From streets to buildings, concrete is the most widely used material in the world. Concrete is made from sand, crushed rocks, and water and is glued together with cement. Unfortunately, cement factories are some of the largest emitters of greenhouse gases. The emissions come from decarbonizing limestone and the very high temperatures needed to manufacture cement.

Manufacturing a single ton of cement requires the equivalent energy of burning four hundred pounds of coal

Paul Hawken https://www.drawdown.org/solutions/materials/alternative-cement

So, how can we design a more sustainable version of concrete? Imagine a high-tech skyline with remarkable towers and shopping centers. And heat, a lot of heat. This week we are covering an invention from Abu Dhabi in the United Arab Emirates.

Kemal Celik, an assistant professor at NYU Abu Dhabi, researches how to make sustainable cement. He explores using by-products from other industries. Basically, making cement from recycled materials.

There are a lot of desalination plants in the United Arab Emirates to produce drinking water from seawater. A by-product of the desalination process is residual brine. Kemal figured out a way to make cement with the leftover brine. This is how it works:

His invention, reactive magnesium oxide cement, is produced at much lower temperatures than traditional cement. And the best thing? It actually absorbs carbon dioxide during the hardening process and long after it has been mixed into the concrete, making it carbon negative.

Roads and buildings made with it could actually absorb carbon dioxide from the atmosphere over the years and help combat climate change

Kemal Celik, https://nyuad.nyu.edu/en/research/impact/our-research/2018/just-add-salt.html

Another inspiring innovation. Let’s hope we can all drive on roads made from sustainable concrete sometime soon.

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Can Cactus Reduce Global Warming?

Recent posts from the BBC, Futurism and Fronteras about bioplastic made from cactus caught my eye. So let’s explore this!

How does bioplastic help to fight global warming? Plastic is made out of oil. From extracting the oil to manufacturing plastic, greenhouse gases are emitted. After we use plastic, it ends up in the environment or in landfills, where it degrades over hundreds of years, emitting greenhouse gases. Alternatively, plastic trash is burnt which also releases greenhouse gases. Besides that, it releases toxins, harms our oceans and enters our food chain. Project Drawdown estimates that by replacing half our plastic with bioplastic by 2050, 4.3 gigatons of carbon dioxide emissions can be avoided.

So, how do we switch to bioplastic? Previously I wrote about amazing bioplastic solutions from teams all over the world. I covered Notpla’s seaweed pouches from London, and Cove’s PHA bottles from California. This week’s innovation comes from the hot deserts of Mexico.

Imagine a very, very bright green – that’s what cactus juice looks like. Sandra Pascoe Ortiz, a chemical engineering professor from Guadalajara, developed a way to turn this green cactus juice into bioplastic. This is how it works:

She starts by harvesting and peeling cactus leaves. Then she juices and chills the cactus concentrate. After that, the concentrate is mixed with glycerin and wax and finally it is laminated. Sandra has produced bioplastic with different colors, shapes, and flexibility.

What I like most about her approach is that it’s made entirely from renewable resources. She has been researching cactus plastic for over 6 years and says more research needed. Let’s hope we can use her bioplastic one day soon!

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Can Sustainable Air Conditioners Stop Global Warming?

A recent report from the Australian think tank Breakthrough evaluates global warming as existential threat to human civilization. The report says it is essential to build a zero emissions system. Global mobilization is needed quickly to reduce the risk. While reading this I got very scared. But then I asked myself if there was good news as well?

I think the good news is that we know how to reduce greenhouse gas emissions that lead to global warming. In his fantastic book Drawdown, Paul Hawken and a team of over 70 researchers from all over the world list 100 solutions to address global warming.

On place number 1 is refrigeration management, so your air conditioner, fridge, and freezer. The chemicals used to cool the air are greenhouse gases that do harm during production, servicing, when they leak, and especially during disposal. Out of all 100 solutions, refrigeration management can avoid or remove the most amount of greenhouse gases. So let’s look into this. How can we design air conditioners without harmful chemicals?

This week we are highlighting a team from Singapore. Ernest Chua teamed up with three other researchers from the National University of Singapore. Together they are developing an air conditioner that works without harmful chemicals, in fact, it uses water to cool down the air. Here is how it works:

The first step is to dehumidify the air by directing it though a membrane. A nice side effect is that they are able to capture the water, which is almost as pure as bottled drinking water. After that, the dry hot air goes through a water-based evaporative cooler. The cold air is then released to the room.

I’m happy to report that a totally green air conditioner that is chemical free and does not emit heat to the environment is a possibility.

Ernest Chua at his talk at the World Economic Forum 2019

The sustainable air conditioner consumes 40% less electricity and can cool a space as low as 18 °C (64 °F). Ernest and his coworkers are now working on iterating their working prototype. There is huge market for air conditioners worldwide. Unfortunately, with raising temperatures, more and more air conditioners are needed.

What I like most about this project is that is helps in two ways. First, they don’t heat up the environment and second, they don’t use chemical refrigerants. I’m excited about their next steps and hope they are ready to cool down the world soon!

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