Food security has always been a priority in human civilization. The challenge of nourishing a growing human population is one that farmers, scientists, and policymakers continue to address every day.

On a small scale, one solution to localized food security is to create food forests. Unlike a garden, food forests are diverse, self-sustaining ecosystems composed of mostly food-bearing plants. They can provide a resilient source of food that requires minimal inputs while promoting biodiversity and soil health. These human-designed food forests take inspiration from actual forests as designed by Mother Nature, as these natural ecosystems are full of life, sustainable, and require no human intervention to thrive.

Where gardens are usually only composed of one flat layer of vegetables, food forests simulate the verticality of forests to create a highly diverse ecosystem. Typically, food forests are composed of seven layers, though depending on scale, it can be a little less and still function the same. These layers are:

• Canopy, composed of large fruit and nut trees

• Understory, composed of dwarf fruit trees

• Shrubs, such as blueberries or currants

• Perennials, or herbaceous plants

• Soil surface, composed of ground cover crops like creeping thyme

• Soil/rhizosphere, composed of root crops

• Vertical layer, composed of climbing vines

Because of the biodiversity created by this layering, many of the problems that come up in traditional gardening or agriculture are self-addressed in a food forest. For example, the environment of a food forest attracts bugs that prey on common pest insects, eliminating the need for pesticides and reducing damage to the vegetation. This same diversity attracts pollinators like bees and butterflies which are essential for the healthy reproduction of many food crops.

A major environmental benefit of food forests is their ability to sequester carbon. Trees are known to be excellent carbon sinks, and food forests can sequester even more carbon than traditional forests due to their high plant diversity and density. In addition, food forests can help to mitigate climate change by reducing the need for transportation and storage of food, as the food is grown and consumed locally.

Another benefit of food forests is that they can help to conserve water. The deep roots of trees and shrubs in a food forest can help to retain moisture in the soil, reducing the need for irrigation. Additionally, the diverse range of plants in a food forest can help to prevent erosion and improve soil health, which can further reduce water consumption.

In terms of social benefits, food forests can promote community building and education. Food forests can provide a space for community members to come together to learn about sustainable agriculture practices, share knowledge and skills, and build relationships. Additionally, food forests can provide opportunities for education about nutrition and healthy eating, as well as food preparation and preservation.

Finally, food forests can promote economic development by providing a source of income for farmers and small-scale producers. Food forests can produce a wide range of crops, including fruits, nuts, vegetables, and herbs, which can be sold in local markets or used for value-added products such as jams and preserves. In addition, food forests can promote ecotourism, which can generate income for local communities.

These are just some of the great reasons why the Science Mill is developing its own food forest in the heart of Johnson City, Texas. Designed as a self-sustaining food forest and an aesthetic, educational space where kids can learn about sustainable agriculture and nutrition, the Science Mill food forest will be the newest addition to the interactive science museum. Stay tuned for its grand opening this year!

Did you know that the Science Mill is housed in a historic 1880s feed mill in Johnson City? The mill, originally established as a steam grist mill and cotton gin by J.P. Johnson, had a significant impact on the economic development of the town, and has served as a community landmark for decades.

In transforming the building into the Science Mill as it is today, much care and attention was given in ensuring that much of the original structure was kept intact. This is the Science Mill’s way of honoring the history it is proud to build upon.

The silos that used to store grain now serve as unique spaces for one-of-a-kind exhibits like the Light Loom, Dig In!, and Cell Phone Disco.

Once separate structures have been artfully connected with walkways that create a sense of cohesion while retaining the distinct energy of each studio, giving visitors a smooth but dynamic experience.

Learn about the building’s history through the A Mill in Time exhibit. Science enthusiasts and history lovers will surely find the Science Mill a worthwhile visit! Come drop by the museum from Wednesday to Sunday!

The Science Mill, only an hour from Austin or San Antonio, is a high-tech science museum in Johnson City, Texas, Established in 2012, the museum is home to over 50 interactive exhibits, and has helped provide high quality, accessible STEM programs for children all over the state. Learn more about the Science Mill’s impact here.

The idea of traveling space has inspired the minds of writers, artists, and inventors for centuries.

While the discoveries and innovations in this field remain endless, rocket science has greatly advanced since humans first imagined it. It is, indeed, a challenging but exciting field, but the fundamentals of rocket science can be understood through Newton’s Laws of Motion.

First, what is a rocket? Technically speaking, a rocket is any vehicle that uses jet propulsion to accelerate without using the surrounding air. It can be as large as the space rockets created by NASA, or as small as something launched from your own backyard!

Here’s how the three Laws of Motion play a role in rocketry:

Newton’s First Law

Objects at rest remain at rest and objects in motion remain in motion in a straight line unless acted upon by an unbalanced force. What does this mean for rockets?

Scientists have to figure out how an object at rest, such as the rocket, can be moved with enough exertion in order to lift off. For lift off to happen, the force exerted must be greater than the force of gravity. This force is called thrust. In sending rockets to space, figuring out how to generate enough thrust to quickly propel a large amount of weight against gravity is incredibly challenging!

Newton’s Second Law

Force equals mass times acceleration (or f = ma). In rocketry, this means that the force or thrust produced is as great as the amount of propellant or fuel (m) used and the acceleration (a) of the combustion products out of the nozzle. In other words: the more propellant and acceleration, the greater the force or thrust, which is important in successful launches.

Newton’s Third Law

For every action there is an equal and opposite reaction. The combustion of propellants when rockets lift off is the action—the reaction is the rocket moving in the opposite direction. Upon lift off, while the propellants accelerate rapidly, the rocket itself slowly accelerates, which may seem like an imbalanced or unequal reaction. What is happening here can be explained by another Newtonian law: the Law of Inertia, which states that it takes a force to change the motion of an object. The greater the mass, the greater the force required to move it. Since the mass of the rocket is much greater than that of the gas, smoke, and flame produced by the propellant, more force is required.

Of course, actual rocket science is much more complex, as there are numerous other factors to consider like:

• The weight of the rocket in relation to the force or thrust that can feasibly be produced

• The materials used as propellants

• The purpose of the rocket in relation to the size

• Its safe return

• Its environmental impact

• And many more!

Learn more about the basics of how rockets work by visiting the Science Mill! This month’s Homeschool Day will focus on activities exploring rocket science, and you can check out the museum’s rocketry exhibit from Wednesday to Sunday. Learn more about admission here.