Hubbry Logo
LandscapingLandscapingMain
Open search
Landscaping
Community hub
Landscaping
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Contribute something
Landscaping
Landscaping
Landscaping
View on Wikipedia
from Wikipedia
Landscaping an elementary school courtyard in the city of Kuching

Landscaping refers to any activity that modifies the visible features of an area of land, including the following:

  1. Living elements, such as flora or fauna; or what is commonly called gardening, the art and craft of growing plants with a goal of creating a beauty within the landscape.
  2. Natural abiotic elements, such as landforms, terrain shape and elevation, or bodies of water.
  3. Abstract elements, such as the weather and lighting conditions.

Landscaping requires a certain understanding of horticulture and artistic design, but is not limited to plants and horticulture. Sculpting land to enhance usability (patio, walkways, ponds, water features) are also examples of landscaping being used. When intended as purely an aesthetic change, the term Ornamental Landscaping is used.[1]

Often, designers refer to landscaping as an extension of rooms in your house (each one has a function). Outdoor spaces have a vast amount of flexibility as far as materials and function. It is often said the only limitation to outdoor space is one's imagination.

Understanding the land

[edit]

Construction requires both study and observation, and the process varies in different parts of the world. Landscaping varies according to different regions.[2] Therefore, normally local natural experts are recommended if it is done for the first time. Understanding of the site is one of the chief essentials for successful landscaping.[3] Different natural features and phenomena, like the position of the sun, terrain, topography, soil qualities, prevailing winds, depth of the frost line, and the system of native flora and fauna must be taken into account.[4] Sometimes the land is not fit for landscaping. In order to landscape it, the land must be reshaped to direct water for appropriate drainage. This reshaping of land is called grading.[4] Sometimes in large landscaping projects like, parks, sports fields and reserves soil may need to be improved by adding nutrients for growth of plants or turf, this process is called soil amelioration.[5]

Removal of earth from the land is called cutting while when earth is added to the slope, it is called filling. Sometimes the grading process may involve removal of excessive waste (landfills), soil and rocks, so designers should take into account while in the planning stage.[6][7]

Additional information

[edit]

At the start, the landscaping contractor issues a statement which is a rough design and layout of what could be done with the land in order to achieve the desired outcome.[4] Different pencils are required to make graphics of the picture. Landscaping has become more technological than natural, as few projects begin without bulldozers, lawnmowers, or chainsaws.[2] Different areas have different qualities of plants. When growing new grass, it should ideally be done in the spring and the fall seasons to maximize growth and to minimize the spread of weeds. It is generally agreed that organic or chemical fertilizers are required for good plant growth. Some landscapers prefer to use mix gravel with rocks of varying sizes to add interest in large areas.[8]

See also

[edit]

References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Landscaping

View on Grokipedia
from Grokipedia
Landscaping is the and of planning, designing, and maintaining outdoor spaces by modifying natural and constructed elements to create functional, aesthetically pleasing, and environmentally sustainable environments. It encompasses the arrangement of , , features, structures, and pathways to enhance the visual appeal and usability of areas such as residential yards, public parks, and commercial properties. The history of landscaping traces back to ancient civilizations, where early practices integrated environmental, cultural, and utilitarian needs into land design. In , geometric planning and irrigation systems shaped walled gardens and labyrinths, influencing later maze designs. Assyrian cultures developed expansive wooded hunting parks with pavilions, while emphasized water features like fountains for sensory appeal. During the from the 7th century, paradise-inspired gardens incorporated fragrance, color, and flowing water to evoke tranquility. In , imperial gardens featured artificial islands and water elements for contemplation, a concept adapted into Japan's gardens. Greek and Roman contributions included orchards, vineyards, , and urban spatial organization, setting precedents for formal layouts. The medieval period shifted toward practical food and medicinal gardens, but the revived humanism through geometric designs and water spectacles. In 17th-century , André Le Nôtre's grand projects like Versailles introduced axial perspectives and vast scales. English landscape gardening emerged in the early , favoring irregular, naturalistic styles over formal geometry, as seen in the works of . In America, figures like and advanced naturalistic and public from the 18th century onward. Key principles of landscaping guide the creation of cohesive designs, balancing artistic elements with practical considerations. Unity achieves a sense of oneness by grouping plants and features to organize views and emphasize family needs. Balance provides stability through symmetrical (formal) or asymmetrical (informal) arrangements of elements. Line defines spaces and directs movement via bold curves or straight paths, while form refers to the three-dimensional mass of plants and structures. Texture varies with plant foliage size and viewing distance to add depth, and color evokes moods—such as red for energy or blue for calm—typically limited to 10% accents against 90% green. Scale relates element sizes to human proportions for emotional impact, with simplicity avoiding clutter through repetition and variety preventing monotony. Emphasis creates focal points via dominant features, and sequence ensures smooth transitions in form, color, and texture for rhythmic flow. These principles apply across elements like mass, line, and color to foster functional outdoor living. Contemporary landscaping emphasizes , incorporating ecological practices to reduce water use, minimize pesticides, and support . Types include residential designs for home and utility, commercial landscapes for business enhancement, and ecological approaches like rain gardens that manage and promote native . Florida-Friendly Landscaping principles, for instance, promote right plant placement, efficient watering, appropriate fertilizing, and mulching to conserve resources. Overall, landscaping serves both ornamental and environmental roles, adapting historical influences to modern challenges like .

Definition and Fundamentals

Definition and Scope

Landscaping is the art and science of arranging natural and constructed elements in a planned manner to enhance the aesthetic, functional, and environmental qualities of outdoor spaces. This practice involves thoughtful modification of areas to create harmonious environments that support human activities while respecting ecological balance. The scope of landscaping spans diverse scales and contexts, ranging from intimate residential gardens and urban courtyards to expansive parks and institutional grounds. It applies to both permanent features, such as enduring gardens and site infrastructure, and temporary installations, including event setups with modular plantings or seasonal displays that transform spaces for specific occasions. This versatility allows landscaping to address needs in residential, commercial, and domains, adapting to urban, suburban, and rural settings. Key concepts in landscaping emphasize the integration of living elements—such as , , and water features—with non-living components, including hardscapes like pathways, walls, and furniture, to achieve cohesive designs. Unlike , which primarily concerns the science of cultivation and care, or , which focuses on built structures, landscaping holistically blends these aspects to optimize outdoor and .

Historical Context

The origins of landscaping trace back to ancient civilizations in and , where early gardens served both practical and symbolic purposes. In , the , constructed around 600 BCE under King , represented one of the earliest known monumental landscape projects, featuring terraced structures with exotic plants irrigated by advanced hydraulic systems to evoke a lush paradise amid arid surroundings. Similarly, in around 1500 BCE, formal gardens emerged adjacent to temples and tombs, characterized by symmetrical layouts of pools, papyrus beds, and shade trees like sycamore and date palms, designed for aesthetic pleasure, religious rituals, and agricultural experimentation. Classical influences from and further refined these concepts, emphasizing harmony between human-made spaces and nature. Greek landscapes, particularly around temples from the BCE, incorporated geometric symmetry and proportion, with sacred groves () and stoas that integrated natural topography to symbolize order and divine favor. Romans expanded this vision in their villas during the 1st century BCE to 4th century CE, creating expansive estates with courtyards, fountains, and —elaborate water features—that blended , , and to reflect imperial power and . During the medieval period, landscaping adapted to religious and cultural contexts in and the Islamic world. In , monastery gardens from the 9th to 12th centuries, such as those in Benedictine , featured enclosed herbularii (herb gardens) and paradisi (paradise gardens) with fruit trees and fountains, symbolizing spiritual enclosure and self-sufficiency. Concurrently, Islamic paradise gardens in , inspired by Quranic descriptions of heaven, flourished with quadrilateral layouts divided by channels representing the four rivers of paradise; the in , developed in the 14th century, exemplifies this with its intricate courtyards, reflective pools, and aromatic plantings that merged with sensory landscapes. The revived classical ideals in , leading to innovative garden designs that showcased and engineering. In , 16th-century Mannerist gardens like the in Tivoli, built between 1550 and 1572, integrated hydraulic fountains, terraces, and grottos into dramatic, illusionistic landscapes that manipulated water and perspective for theatrical effect. This formal style contrasted with the 18th- and 19th-century English landscape movement, which rejected geometric rigidity in favor of naturalism; Lancelot ", active from the 1750s to 1780s, transformed estates like into sweeping parks with serpentine lakes, rolling lawns, and clustered trees, emulating idealized wilderness to promote sublime emotional experiences. In the , landscaping shifted toward and integration with everyday life, particularly in the United States. Wright's from the early 1900s onward, as seen in projects like (1935), pioneered the seamless blending of buildings with their natural surroundings, using native and site-specific forms to achieve environmental harmony. Post-World War II suburban expansion in the U.S., fueled by the and highway development from the 1940s to 1960s, popularized standardized residential landscapes with lawns, hedges, and driveways, reflecting mass consumerism and the ideal of private domestic retreats. Global perspectives enrich this history, with enduring Asian traditions emphasizing and symbolism. Chinese scholar gardens, dating to the (10th–13th centuries) but rooted in earlier Han-era principles, created intimate, asymmetrical compositions of rocks, water, and pavilions in urban settings like , designed to evoke poetic landscapes and philosophical retreat. In Japan, gardens (karesansui) evolved from the 14th century, building on Heian-period (8th–12th centuries) influences, using raked gravel, moss, and stones to represent mountains and islands in minimalist dry landscapes, fostering within temple precincts.

Importance and Applications

Landscaping plays a crucial role in enhancing aesthetic appeal by creating visually pleasing and serene environments that mitigate urban monotony and foster tranquility. Well-designed landscapes, incorporating elements like greenery and features, have been shown to reduce through physiological responses such as lowered levels and improved mood, with studies indicating significant stress recovery in natural settings compared to urban or indoor alternatives. For instance, exposure to landscaped green spaces can decrease by up to 12.4% and promote emotional , aligning with biophilic principles that reconnect humans to . These aesthetic improvements not only elevate the sensory experience but also contribute to restorative environments that support daily relaxation. Functionally, landscaping boosts property values, with research demonstrating increases of 5.5% to 11.4% for homes featuring sophisticated designs, translating to thousands of dollars in added resale worth for average properties. Strategic planting of shade trees can yield energy savings by reducing household cooling needs by 15-50% in summer and heating demands by up to 25% in winter through windbreaks and insulation effects. Additionally, landscapes facilitate recreational spaces such as patios and playgrounds, encouraging outdoor activities that enhance and in both private and shared areas. On social and health fronts, landscaping promotes mental well-being via , which reduces stress, improves cognitive function, and accelerates recovery from fatigue by up to 37% through natural stimuli like views of greenery. It also encourages , with access to landscaped parks tripling the likelihood of meeting exercise guidelines and fostering interactions in shared green spaces that build social cohesion. Economically, the landscaping industry sustains over 1 million jobs across 661,000 businesses in the United States, with a market size of $153 billion as of 2024 (projected to reach $188.8 billion in 2025); the global market exceeded $330 billion as of 2024. Furthermore, landscaped attractions like botanical gardens generate revenue by drawing visitors for recreational value, contributing significantly to local economies through visitor spending and related activities. Landscaping finds applications across diverse sectors: in residential settings, it enhances home gardens for personal enjoyment and value appreciation; commercially, it improves office campuses and retail spaces for better and employee ; institutionally, it creates therapeutic environments in hospitals and schools to support and learning; and publicly, it develops parks and urban greenways for community and .

Design Principles

Core Principles

The core principles of landscape design provide foundational guidelines to create functional, aesthetically pleasing outdoor spaces that integrate harmoniously with their environment. These principles emphasize balance, visual flow, and sensory engagement, ensuring that designs are not only visually appealing but also practical for maintenance and user experience. By applying unity, scale, rhythm, emphasis, simplicity, and the strategic use of color, texture, and form, designers achieve cohesive landscapes that enhance the site's natural and architectural features. and refer to the cohesive integration of all elements to create a sense of wholeness and consistency across the . This is achieved through repetition of motifs, such as recurring patterns or materials, continuity via seamless transitions between spaces, and balance, which can be symmetrical for formal order or asymmetrical for natural dynamism. ensures that diverse components complement rather than compete, fostering a unified visual character that ties the to its surroundings. Scale and proportion address the relative sizes of elements in relation to the overall site and human dimensions, preventing designs from appearing overwhelming or insignificant. Scale considers the site's dimensions and the mature growth of features to maintain equilibrium, while proportion evaluates how individual components relate to each other and to structures like buildings, ensuring compatibility and . For instance, elements scaled to human proportions, such as pathways or seating areas, promote comfort and without dominating the space. Rhythm and movement guide the viewer's eye through the , creating a of progression and dynamism via lines, curves, and repeating sequences. Rhythm is established by gradual transitions or alternating patterns in elements like shapes or spacing, which direct circulation and visual flow, while movement is enhanced by curving paths or layered arrangements that suggest motion and prevent static compositions. This principle contributes to an engaging experience by linking areas and building anticipation. Emphasis and focal points highlight key features to add interest and structure, using contrast in , , or placement to draw attention without overwhelming the . A focal point, such as a central or prominent , serves as an anchor that organizes the space and guides views, often framed by surrounding elements to reinforce and prevent visual clutter. This selective highlighting creates depth and within the . Simplicity promotes clarity and restraint by eliminating unnecessary elements, focusing on essential features to enhance and reduce demands. By limiting variety and avoiding overcrowding, strengthens unity and allows each component to contribute meaningfully, resulting in timeless, low-effort designs that prioritize purpose over ornamentation. Color, texture, and form provide sensory variety and seasonal interest, with color schemes influencing mood and perception—warm tones advancing to energize spaces, cool tones receding for calm. Texture adds depth through contrasts between coarse, bold surfaces and fine, subtle ones, affecting spatial feel, while form defines the overall silhouette and style, such as geometric for formality or organic for naturalism, ensuring elements interact cohesively. These attributes are selected to support the other principles, enhancing visual and tactile appeal.

Site Analysis and Planning

Site analysis and planning constitute the initial and essential phase of , where professionals systematically evaluate a site's inherent characteristics to develop a preliminary framework that aligns with environmental conditions, user requirements, and legal constraints. This process ensures that subsequent designs are practical, resilient, and tailored to the site's unique attributes, minimizing risks such as failure or structural issues. By integrating data from , , , and human factors, planners create a foundation for sustainable landscapes that enhance functionality without compromising ecological integrity. Soil testing is fundamental to determining plant suitability, as it reveals levels, drainage capabilities, and profiles that directly affect root health and growth. , assessed on a 0-14 scale where 7 is neutral, governs availability— for instance, iron becomes more accessible below 6, while most horticultural thrive between 6.1 and 6.9. analysis typically measures macronutrients like , , calcium, and magnesium in parts per million, guiding amendments to address deficiencies. Drainage is evaluated through percolation tests, which involve digging a hole, saturating it with , and timing infiltration rates to gauge retention; poor drainage (e.g., less than 1 inch per hour) signals the need for adapted or modifications to prevent . Samples are collected at 6-10 inches depth using probes or spades and analyzed by accredited labs to provide actionable recommendations. Topography and climate evaluation map physical and atmospheric features to identify opportunities and limitations for plant placement and site use. Slopes are surveyed to assess erosion potential and water flow, with steeper grades (over 15%) requiring terracing or erosion-control plants. Sun exposure is tracked over a year, noting south-facing areas for warmth-loving and shaded north sides for shade-tolerant ones, while wind patterns—such as prevailing southwestern summer breezes or harsh northwestern winter gusts—inform windbreaks using dense evergreens. Microclimates, variations within the site like frost pockets in low valleys or heat-trapping urban areas near structures, refine broader assessments. The 2023 USDA Plant Map, based on 30-year average minimum winter temperatures in 5°F increments (e.g., Zone 7a: 0° to 5°F), serves as a baseline for selection, though site-specific factors like and can shift effective hardiness by one zone. User captures functional priorities through structured client interviews, ensuring the landscape supports daily activities and lifestyle goals. Interviews explore desires for (e.g., screening with tall hedges or fences), (e.g., wide, level paths with gradual slopes under 5% for use), and recreational spaces like play areas with soft surfacing. Compatibility with personal expectations, such as low-maintenance preferences or aesthetic themes, is evaluated to define , drawing on principles like prospect-refuge theory for comfortable, explorable environments. Regulatory considerations encompass zoning laws, permitting requirements, and environmental protections that shape site development. Zoning ordinances dictate allowable uses, setbacks, and lot coverage, often mandating landscape buffers to screen incompatible activities. Permits are required for projects altering drainage, structures, or vegetation, reviewed by local planning departments within 20-30 days to ensure compliance. Environmental restrictions, such as those under the federal Clean Water Act's Section 404, prohibit unpermitted dredging or filling in jurisdictional wetlands, which cover approximately 6% of the conterminous U.S. land area (as of 2019) and require delineation and mitigation plans for any impacts. Wetland buffers, often ranging from 50 to 300 feet depending on jurisdiction and wetland type, preserve hydrology and habitat, with violations leading to fines or restoration orders. Preliminary sketching translates into , starting with base maps that depict existing conditions at a consistent scale (e.g., 1 inch = ) to include property lines, structures, utilities, and . These maps, derived from surveys or on-site measurements using tape and levels, provide a factual overlay for ideation. diagrams then layer functional zones—such as circulation paths or planting beds—using simple bubbles or lines to explore layout options, emphasizing balance in spatial distribution before advancing to detailed drawings.

Key Elements

Hardscape Features

Hardscape features in landscaping refer to the non-living, structural components that provide foundational support, define spatial boundaries, and enhance durability within outdoor environments. These elements, typically constructed from durable materials like stone, , or metal, contrast with softer, organic features by offering permanence and functionality against weather and wear. They are essential for creating usable spaces, managing site conditions such as slopes or drainage, and integrating aesthetic appeal with practical utility. Hardscape elements can constitute a significant portion of a project's in urban designs, emphasizing their role in long-term site resilience. Paths and walkways form the of landscaped areas, guiding movement while preventing and . Common materials include for permeable, low-cost options that allow water infiltration; interlocking pavers for modular, visually appealing surfaces; and poured for smooth, economical durability. Designs prioritize , with the Americans with Disabilities Act (ADA) mandating minimum widths of 36 inches for primary paths to accommodate wheelchairs and ensure safe passage. For instance, paths often use stabilized bases to maintain even surfaces under foot traffic, as recommended by the U.S. Access Board for principles. Walls and retaining structures serve critical roles in erosion control, terracing uneven terrain, and creating privacy or visual interest. Dry-stack stone walls, built without mortar for a natural appearance, rely on interlocking stones and proper drainage behind them to withstand pressure, commonly used on slopes up to 3 feet high. Mortared block walls, such as those made from or , provide greater stability for taller structures through and , often incorporating fabrics for added tensile strength on steeper grades. The International Building Code (IBC) specifies that retaining walls over 4 feet require review to prevent , highlighting their engineering demands in landscaping applications. Patios and decks expand usable outdoor living areas, offering flat platforms for gatherings or relaxation. Surface options range from natural stone slabs for rustic elegance and heat resistance to pressure-treated wood for cost-effective warmth underfoot, while composite materials blend wood fibers with recycled plastics for low-maintenance longevity and resistance to rot. Key considerations include drainage, achieved via slight slopes (typically 1/8 inch per foot) to direct water away and prevent pooling, and load-bearing capacity, with decks engineered to support at least 40 pounds per for residential use as per the IBC. These features enhance property value, with the noting that backyard patios can yield a 95% . Water features introduce dynamic elements like fountains, , or artificial streams, adding auditory tranquility and visual focal points to hardscape layouts. Fountains often employ recirculating systems with submersible rated in gallons per hour (GPH)—for example, a 500 GPH suits small basin designs to maintain flow without overflow. and streams require liners (e.g., ) for and systems to keep water clear, with circulation sized at 1 GPH per of volume for biological balance. The Quality Association underscores the importance of UV sterilizers in these setups to control , ensuring ecological harmony in non-natural features. Outdoor furniture and lighting complete hardscape functionality by promoting comfort and visibility. Benches crafted from or recycled offer durable seating integrated into walls or paths, while pergolas—open-roofed structures of or metal—provide shaded alcoves for vines or lounging. LED fixtures, valued for their energy efficiency (up to 80% less power than incandescents), illuminate pathways and features for nighttime and ambiance, often solar-powered to minimize wiring. The Illuminating Engineering Society recommends 5-10 foot-candles for walkways to prevent hazards, aligning with hardscape's emphasis on user .

Softscape Components

Softscape refers to the living, organic elements of a landscape design that contribute to aesthetic appeal, ecological balance, and functional benefits, such as providing shade, color, and habitat support. These components, including plants, soils, and ground covers, evolve over time in response to environmental conditions, unlike static hardscape features. Effective softscape selection emphasizes compatibility with local , , and exposure to ensure long-term viability and minimal intervention. Plants form the core of softscape, selected based on their functional roles and growth habits to create layered, dynamic compositions. Trees are often chosen for canopy shade and vertical structure, with species like oaks (Quercus spp.) providing broad coverage in temperate zones, while shrubs such as boxwood (Buxus spp.) define borders and offer privacy screening. Perennials, including daylilies (Hemerocallis spp.) and coneflowers (Echinacea spp.), deliver seasonal color bursts and support biodiversity through nectar-rich blooms. Native species are prioritized for their adaptation to regional conditions, reducing maintenance needs like watering and ; for instance, black-eyed Susan () thrives in North American prairies with minimal care. Considerations include plant hardiness zones, as outlined by the USDA, to match species like Japanese maple (Acer palmatum) to zones 5-8 for frost tolerance. Lawns and ground covers provide foundational coverage in softscapes, balancing open space with and foot traffic tolerance. Traditional turf grasses, such as Kentucky bluegrass (), require regular mowing and irrigation but offer durable play surfaces in cool-season climates. Alternatives like ( spp.) or creeping thyme (Thymus serpyllum) suit shaded or low-traffic areas, minimizing water use; drought-tolerant varieties, including buffalograss (Bouteloua dactyloides), demand up to 50% less irrigation than conventional lawns in arid regions. layers, often 2-4 inches deep from organic sources like bark or leaves, suppress weeds and retain in ground cover designs. Soil amendments enhance softscape health by improving fertility and structure, directly influencing plant vigor and landscape longevity. Organic , applied at rates of 2-4 inches and incorporated into , boosts nutrient content and microbial activity, as demonstrated in studies on and ornamental beds. For erosion-prone sites, amendments like peat moss or aged stabilize slopes, preventing nutrient leaching during heavy rains. not only conserves water but also moderates soil temperature fluctuations, with wood chip reducing evaporation by 20-30% in field trials. Fauna integration in softscapes fosters ecological connectivity by incorporating habitat elements that attract beneficial wildlife without intensive management. Nectar-bearing plants like bee balm (Monarda spp.) draw pollinators such as bees and butterflies, enhancing pollination services for surrounding vegetation. Simple features, including shallow birdbaths or dense shrubbery, provide watering and shelter for birds like cardinals (Cardinalis cardinalis), promoting natural pest control through seed dispersal and predation. Seasonal planting strategies ensure year-round visual interest and resilience in softscapes, layering elements to address varying climatic demands. Spring bulbs, such as tulips (Tulipa spp.) and daffodils (Narcissus spp.), offer early color pops before perennials emerge, naturalizing in well-drained soils for recurring displays. Evergreens like spruces (Picea spp.) maintain structural backbone through winter, providing windbreaks and continuity in colder regions. This approach, combining and persistent species, optimizes resource use across seasons.

Planning and Implementation

Design Process

The landscape design process begins with conceptualization, where designers brainstorm themes and concepts tailored to the client's vision and site characteristics. This stage involves initial consultations to gather requirements, such as desired (e.g., formal geometric layouts versus naturalistic, flowing arrangements) and functional needs, often informed by preliminary site evaluation inputs like and . Landscape architects formulate graphic and written criteria to guide the project, including feasibility studies that align ideas with environmental and regulatory constraints. Following conceptualization, drafting and visualization translate ideas into tangible representations. Designers create initial sketches, 2D plans, or 3D models using tools like for precise layouts or hand-drawn diagrams for creative exploration; mood boards assemble material samples, such as stone types or plant palettes, to convey texture and color schemes. This phase develops spatial arrangements, highlighting functions, opportunities, and aesthetic elements to ensure the design harmonizes with the site's existing features. Iteration and feedback refine the draft through collaborative reviews. Clients provide input on preliminary concepts, prompting adjustments via simulations like virtual walkthroughs to test and visual impact. Designers address identified issues, such as scale discrepancies or incompatibilities, iterating until the scheme meets expectations while maintaining feasibility. This back-and-forth ensures the evolving design balances creativity with practicality. Budgeting and costing occur concurrently with , estimating expenses for materials, labor, and other elements to align with client finances. Professionals provide detailed opinions, factoring in variables like regional pricing for plants or hardscape features, and typically recommend a 10-15% contingency buffer for unforeseen issues such as soil amendments or supply fluctuations. This step prevents and confirms the design's economic viability. Finalization culminates in polished deliverables, including scaled drawings, detailed plant schedules specifying species and quantities, and comprehensive specifications for materials and installation methods. These documents, often produced in digital formats for clarity, serve as the blueprint for contractors, ensuring accurate execution of the approved vision.

Construction Techniques

Construction techniques in landscaping involve the physical execution of design plans, transforming conceptual layouts into functional outdoor spaces through methodical site work and material installation. These methods prioritize durability, proper drainage, and integration with the natural environment to ensure long-term viability. Best practices emphasize precision in and assembly to avoid structural failures or environmental damage. Site preparation begins with clearing the area of , , roots, and obstacles to create a clean working surface. Prior to starting, obtain necessary permits, conduct tests for and nutrients, and call to mark utility lines to ensure compliance and safety. This step often requires removing large items using heavy machinery like backhoes or front-end loaders, while marking and protecting utility lines and desirable trees to prevent damage. Following clearing, grading reshapes the by leveling or the subsoil to establish the desired and . Excavation may be necessary for deeper adjustments, such as creating swales or removing excess , with tools like skid steers ensuring even distribution. A key aspect is achieving a minimum of 2% away from structures to facilitate drainage and prevent water pooling. Hardscape installation follows site preparation, starting with foundational work to support features like patios and pathways. For patios, excavate to a depth accommodating a compacted base of 4-6 inches, topped with for leveling, to provide stability and drainage. This base is compacted in layers to minimize settling, with edge restraints securing the perimeter. systems are typically installed concurrently or prior to surfacing, involving trenching for pipes and emitters, such as drip lines typically laid on the surface under or shallow buried as needed for protection, connected to a water source with pressure regulators for efficient distribution. Planting techniques focus on root establishment to promote healthy growth. Dig holes two to three times wider than the root ball's diameter but no deeper than the root ball's height, creating saucer-shaped depressions with sloped sides to encourage lateral root spread. Position the plant so the root flare sits 1-2 inches above grade, backfill with native soil without amendments near the roots, and gently firm the soil to eliminate air pockets. Stake trees only if necessary for stability (e.g., in windy areas or if top-heavy), using one or two sturdy stakes driven outside the root ball, secured with flexible ties to allow natural movement, and remove after one growing season. Apply 2-4 inches of organic mulch, such as wood chips or bark, in a ring extending to the drip line but kept 2-4 inches from the trunk to retain moisture, suppress weeds, and regulate soil temperature. Equipment use is essential for efficient , with backhoes employed for large-scale excavation and , and tillers for breaking up and aerating in planting beds. Safety protocols mandate (PPE), including hard hats for overhead hazards, ANSI Z87.1-rated eye protection against debris, hearing protection for noisy operations exceeding 85 decibels, respirators for dust exposure, gloves for handling materials, and ASTM-compliant steel-toed boots. Employers must conduct hazard assessments, provide training on PPE maintenance, and ensure compliance with OSHA standards to mitigate risks during operation. Phased implementation sequences tasks to minimize site disruption and allow progressive completion. Typically, hardscape elements like patios and are installed first, followed by grading and final planting, enabling access and reducing on sensitive areas. This approach divides projects into stages based on budget and timeline, prioritizing foundational work before soft features.

Styles and Types

Residential Landscaping

Residential landscaping focuses on enhancing private home environments to improve , functionality, and property value through tailored outdoor spaces. It typically involves designing front yards to boost curb appeal with elements like foundation plantings—low-growing shrubs and perennials positioned along the base of the house to frame its —and welcoming entryways with walkways bordered by uncluttered turf or groundcovers. In backyards, privacy is often prioritized using fences combined with climbing vines such as or Virginia creeper, which soften structures, reduce noise, and create secluded areas for relaxation. Colorful shrubs and shade trees further contribute to visual appeal while providing practical benefits like cooling outdoor areas during warm weather. For urban homes with limited space, solutions emphasize vertical and efficient use of available areas. Vertical gardens, utilizing trellises or wall-mounted , allow climbing like peas or ivy to maximize height without expanding footprints, ideal for balconies or narrow side yards. Container planting offers flexibility, enabling portable pots for herbs, flowers, or small shrubs on patios or rooftops, adapting to changing or mobility needs. , which incorporates drought-tolerant natives and to minimize water use, suits compact urban lots by replacing high-maintenance lawns with low-water perennials and paths, reducing upkeep in water-restricted regions. Family-oriented designs integrate practical zones that support daily life and . Play areas for children often feature soft turf or under swings and play structures, ensuring safe, durable surfaces within fenced enclosures. gardens, such as raised beds with tomatoes, , and , provide educational and nutritional benefits, often placed in sunny spots for easy access. Pet-friendly elements include selecting non-toxic like marigolds or hostas to avoid hazards for animals, combined with shaded resting spots and fenced boundaries to create secure zones. Cost considerations vary based on scope and approach, with average U.S. residential projects ranging from $3,000 to $15,000 as of 2025, covering basic plantings and hardscape additions for a typical yard. DIY methods, such as installing containers or simple beds, can reduce expenses to under $1,000 by using affordable materials and personal labor, while professional services—essential for complex designs or —provide expertise in and execution. Emerging trends in residential landscaping highlight and convenience. Edible landscapes, blending trees, bushes, and plots into ornamental beds, have gained popularity in 2025 for providing fresh produce alongside aesthetic value, appealing to homeowners seeking self-sufficiency. Smart irrigation systems, including weather-based controllers and soil sensors, optimize water delivery to prevent overwatering, potentially saving up to 30% on usage in home settings. These innovations reflect a shift toward efficient, multifunctional outdoor spaces that align with modern lifestyle demands.

Commercial and Public Landscaping

Commercial landscaping for businesses and institutions emphasizes large-scale designs that integrate functionality, , and branding to enhance and property value. Office plazas often feature durable seating areas, shaded walkways, and integrated greenery to foster employee breaks and client interactions, creating welcoming entry points that align with corporate . Branding elements, such as shaped into company logos or floral beds arranged to spell out business names using brand-specific colors, serve as subtle yet impactful visual identifiers that reinforce identity without overwhelming the landscape. Public parks and urban green spaces prioritize communal utility through expansive layouts that accommodate diverse activities, promoting social cohesion and in densely populated areas. These designs commonly include winding trails for pedestrian and cyclist access, open plazas for gatherings, and multipurpose amenities like sports fields, playgrounds, and event lawns to support and . in stands as a seminal model, spanning 843 acres with over 36 bridges and arches along its trails, nearly 50 fountains and monuments in plaza areas, and facilities for skating, , and team sports, drawing over 42 million visitors yearly as of 2025 as a critical urban refuge for both people and . Institutional landscaping tailors environments to specific organizational needs, blending , , and in shared public-facing settings. Schoolyards redesigned as green learning hubs incorporate outdoor classrooms amid native gardens and play zones, boosting cognitive function, attendance, and ecological awareness through hands-on activities like management projects. Hospital healing gardens, by contrast, focus on restorative elements such as wheelchair-accessible paths, sensory plantings for visual and tactile stimulation, water features for calming sounds, and shaded benches, which studies show can lower patient stress, shorten recovery times (such as by about one day for patients), reduce , and decrease the need for medication. Key challenges in commercial and public landscaping revolve around ensuring longevity and inclusivity amid heavy use. High-traffic durability demands vandalism-resistant materials like stainless steel fixtures, anti-graffiti coatings, and reinforced masonry to deter damage from graffiti, theft, or impacts, particularly in parks where such issues can escalate costs and disrupt usability. Accessibility compliance is equally critical, requiring adherence to standards like the Americans with Disabilities Act (ADA) through features such as firm, slip-resistant pathways with minimal slopes (no steeper than 1:12), curb ramps, and ample clear space for mobility aids to enable equitable navigation for all users. Singapore's , opened in 2012, exemplifies innovative urban integration in commercial-public landscaping, transforming 101 hectares of reclaimed land into a biophilic showcase with supertrees that collect rainwater and generate , themed conservatories housing diverse ecosystems, and elevated walkways connecting green spaces to the city fabric, thereby enhancing , , and sustainable urban living for millions of visitors.

Sustainability and Maintenance

Environmental Considerations

Landscaping practices significantly influence local ecosystems by integrating design elements that conserve resources, support , and minimize ecological disruptions. Thoughtful environmental considerations ensure that landscapes enhance rather than degrade natural , addressing challenges like habitat loss and through strategic plant selection and site modifications. By prioritizing and sustainable techniques, landscapers can foster resilience against environmental stressors while reducing the associated with traditional maintenance. Biodiversity enhancement is a core aspect of environmentally conscious landscaping, achieved primarily through the use of native plants that provide food, shelter, and breeding grounds for local wildlife such as pollinators, birds, and insects. These plants are adapted to regional climates and soils, requiring less water and fertilizer, which indirectly supports ecosystem stability by minimizing resource inputs that could harm surrounding areas. For instance, incorporating native wildflowers and shrubs can attract beneficial insects that sustain bird populations through seed and nectar provision. Additionally, native plantings reduce the spread of invasive species, which often outcompete locals and disrupt habitats; by avoiding non-native ornamentals, landscapes prevent the establishment of aggressive weeds that alter soil composition and reduce native species diversity in affected areas. Effective water management in landscaping mitigates flooding and preserves by capturing and infiltrating rather than allowing it to run off impervious surfaces. Rain gardens, shallow vegetated depressions designed to collect runoff from roofs and driveways, can infiltrate up to 90% of annual rainfall in suitable soils, thereby reducing peak flows and preventing downstream. These features use layered soils and deep-rooted plants to slow velocity and promote , capturing 50-90% of runoff from typical events depending on garden size and soil type. Complementing this, permeable surfaces like porous pavers or gravel paths allow to seep through, reducing overall site runoff by 25-50% while filtering out sediments and chemicals before they reach waterways. Such approaches recharge aquifers and decrease the volume of polluted discharge into local streams. Soil health is safeguarded in landscaping through measures and organic practices that maintain fertility and prevent degradation. Ground covers, such as low-growing perennials or native grasses, stabilize slopes by binding particles with their systems, reducing rates by intercepting raindrop impact and slowing surface flow. These plants increase microbial and diversity, enhancing nutrient cycling and accumulation, which improves over time. Organic practices, including the application of and cover crops, further bolster health by adding slow-release nutrients and preventing leaching; for example, cover crops trap excess in their tissues, minimizing its loss to during wet seasons and avoiding in nearby water bodies. This integrated approach preserves integrity and supports long-term landscape productivity without synthetic inputs. Climate adaptation strategies in landscaping counteract rising temperatures and by incorporating features that moderate microclimates. Green roofs, covered with lightweight and layers, provide insulation and evaporative cooling, reducing effects by 2-5°C in surrounding areas through shade and . These installations lower ambient air temperatures by up to 11°C compared to conventional roofs and mitigate buildup in densely built environments, where impervious surfaces can elevate local temperatures by several degrees. By integrating such designs, landscapes contribute to broader , buffering against heatwaves and supporting cooler, more habitable spaces. Pollution reduction is facilitated by in landscaping, which acts as a natural filter for both air and water contaminants. Trees and shrubs intercept airborne particulates, with urban forests removing significant amounts of PM2.5 through leaf deposition; for example, a mature canopy can capture up to approximately 0.5-1 kg of fine particles annually per , improving air quality by reducing respiratory irritants. This process also absorbs gaseous pollutants like and oxides via stomatal uptake. In water filtration, vegetated buffers and rain gardens trap sediments, , and excess nutrients from runoff, preventing their entry into aquatic systems; in these areas can remove 60-90% of and loads through root uptake and microbial activity in the soil. Overall, these mechanisms lessen the environmental burden of urban pollutants, promoting cleaner ecosystems.

Long-Term Maintenance

Long-term maintenance of landscaped areas involves ongoing practices to preserve plant , structural integrity, and aesthetic appeal while minimizing resource use. Regular and trimming are essential for promoting vigorous growth and preventing overgrowth that can lead to structural weaknesses in plants. For trees, is typically scheduled during late winter or early spring before bud break, allowing wounds to heal quickly as growth resumes and reducing the risk of entry through fresh cuts. This timing, often through in temperate regions, enables clear visibility of branch structure without leaves, facilitating the removal of dead, , or crossing branches. Shrubs and perennials may require lighter trimming in late summer to shape growth, but heavy should align with periods to avoid stressing the plants. Effective and fertilization sustain and levels tailored to needs, preventing both under- and over-watering that could harm . systems deliver water directly to the root zone, achieving up to 90% efficiency by minimizing , , and deep compared to overhead sprinklers. These systems are particularly beneficial in landscapes with mixed plantings, allowing zoned watering based on species requirements. For fertilization, annual soil testing determines specific deficiencies, guiding the application of balanced NPK (nitrogen-phosphorus-potassium) ratios such as 3:1:2 for most trees and shrubs to support healthy foliage and root development without excess buildup. Testing every one to three years, depending on , ensures targeted amendments like slow-release fertilizers applied in spring or fall. Pest and disease management relies on (IPM) strategies that prioritize prevention and minimal intervention to maintain ecological balance. IPM integrates monitoring, cultural practices, and biological controls—such as introducing predatory insects like ladybugs to target —over broad-spectrum chemical pesticides, reducing environmental impact and resistance development. Regular for early signs of infestation, combined with habitat enhancements like diverse plantings to attract beneficial organisms, forms the core of this approach. When necessary, targeted, low-toxicity treatments are used only after thresholds are exceeded, ensuring long-term pest suppression without disrupting pollinators or . Seasonal tasks address environmental stresses to protect plants through cycles of and renewal. In winter, tender plants such as young evergreens or broadleaf shrubs benefit from wrapping with burlap or anti-desiccant sprays to shield against wind, salt spray, and freeze-thaw cycles that cause bark splitting. Mulching around bases with 2-4 inches of organic material further insulates and conserves moisture, applied after the ground freezes to prevent rodent harborage. Spring cleanup involves removing winter debris, such as fallen leaves and protective wraps, to improve air circulation and reveal emerging growth; this includes raking lawns to prevent and inspecting for damage from loads. Ongoing monitoring and adjustments through annual assessments ensure the landscape adapts to wear, weather, and growth changes. Site evaluations, conducted in late fall or early spring, identify issues like thinning turf or settling hardscape elements, informing corrective actions such as overseeding lawns with cool-season grasses in early fall to thicken coverage and repair bare spots. For hardscape, inspections reveal cracks in patios or walkways, which are repaired by resetting pavers or resealing surfaces to prevent water infiltration and erosion. These yearly plans, based on pest levels and plant performance, allow for proactive tweaks like aerating compacted soils or replacing declining features, sustaining the landscape's functionality over decades. As of 2025, emerging practices include the integration of smart sensors for automated adjustments to further enhance in maintenance routines.

References

  1. https://content.ces.ncsu.edu/extension-gardener-handbook/19-landscape-design
  2. https://edis.ifas.ufl.edu/publication/EP375
  3. https://pressbooks.lib.vt.edu/emgtraining/chapter/16/
  4. https://content.ces.ncsu.edu/extension-gardener-handbook/appendix-f-history-of-landscape-design
  5. https://heald.nga.gov/mediawiki/index.php/Landscape_gardening
  6. https://cmg.extension.colostate.edu/Gardennotes/413.pdf
  7. https://extension.okstate.edu/fact-sheets/homeowner-garden-design-series-elements-and-principles-of-design.html
  8. https://extension.umn.edu/lawns-and-landscapes/landscape-design
  9. https://ffl.ifas.ufl.edu/about-ffl/9-principles/
  10. https://www.fedcenter.gov/assistance/facilitytour/grounds/landscaping/index.cfm?&printable=1
  11. https://www.asla.org/aboutlandscapearchitecture.aspx
  12. https://syntheticgrassmasters.com/artificial-grass-for-event-spaces-temporary-and-permanent-solutions/
  13. https://extension.colostate.edu/resource/sustainable-landscaping/
  14. https://commons.lib.jmu.edu/cgi/viewcontent.cgi?article=1779&context=honors201019
  15. https://admisiones.unicah.edu/scholarship/olzXgP/9OK169/gardners__art-through-the__ages.pdf
  16. https://ejournal.upi.edu/index.php/IJOMR/article/download/60561/23493
  17. https://admisiones.unicah.edu/scholarship/olzXgP/9OK169/gardners_art__through__the-ages.pdf
  18. https://repository.arizona.edu/bitstream/handle/10150/191979/azu_td_hy_e9791_1988_201_sip1_w.pdf
  19. https://online.ucpress.edu/jsah/article/80/2/202/117770/The-Gardens-of-the-Alhambra-and-the-Search-for
  20. https://digitalcommons.unl.edu/context/etas/article/1098/viewcontent/italianvillast00whar.pdf
  21. https://admisiones.unicah.edu/virtual-library/v3khXN/1OK019/HistoryOfModernArchitecture.pdf
  22. https://museum.okstate.edu/site-files/2015/frank-lloyd-wright/frank-lloyd-wright-bio.pdf
  23. https://repository.usfca.edu/cgi/viewcontent.cgi?article=3150&context=capstone
  24. https://pmc.ncbi.nlm.nih.gov/articles/PMC5981243/
  25. https://www.fs.usda.gov/sites/default/files/fs_media/fs_document/urbannatureforhumanhealthandwellbeing_508_01_30_18.pdf
  26. https://www.pubs.ext.vt.edu/426/426-087/426-087.html
  27. https://www.firstenergycorp.com/help/saving_energy/trees.html
  28. https://www.terrapinbrightgreen.com/reports/14-patterns/
  29. https://www.landscapeprofessionals.org/LP/LP/Media/landscape-industry-statistics.aspx
  30. https://www.ibisworld.com/united-states/industry/landscaping-services/1497/
  31. https://www.grandviewresearch.com/industry-analysis/landscaping-services-market-report
  32. https://www.researchgate.net/publication/240414380_The_economic_value_of_botanic_gardens_a_recreational_perspective
  33. https://www.ebsco.com/research-starters/architecture/landscaping-services-industry
  34. https://edis.ifas.ufl.edu/publication/MG086
  35. https://ohioline.osu.edu/factsheet/hyg-1132
  36. https://yardandgarden.extension.iastate.edu/how-to/testing-and-improving-soil-drainage
  37. https://planthardiness.ars.usda.gov/pages/how-to-use-the-maps
  38. https://libguides.nybg.org/siteinventory
  39. https://sfyl.ifas.ufl.edu/media/sfylifasufledu/wakulla/images/master-gardeners/Space%2C-People-and-Design.pdf
  40. https://www.fws.gov/project/2019-wetlands-status-and-trends-report
  41. https://www.pace.edu/sites/default/files/2024-08/law-land-use-primer.pdf
  42. https://dec.ny.gov/regulatory/permits-licenses/waterways-coastlines-wetlands/freshwater-wetlands
  43. https://apps.ecology.wa.gov/publications/documents/1406022.pdf
  44. https://fieldreport.caes.uga.edu/publications/C1032-3/drawing-a-landscape-plan-the-base-map/
  45. https://cms.nar.realtor/sites/default/files/documents/2023-03-remodeling-impact-outdoor-features-03-17-2023.pdf
  46. https://worldlandscapearchitect.com/practice-stages-of-a-landscape-architecture-design-project/
  47. https://cc-asla.org/cc/wp-content/uploads/2019/08/LATC-Consumer-Guide.pdf
  48. https://www.rooted-lm.com/blog/a-guide-to-budgeting-for-a-landscape-project
  49. https://extension.psu.edu/lawn-establishment/
  50. https://johnston.ces.ncsu.edu/wp-content/uploads/2020/02/January-2018.pdf
  51. https://extension.colostate.edu/resource/drip-irrigation-for-home-gardens/
  52. https://extension.umn.edu/irrigation/drip-irrigation
  53. https://extension.colostate.edu/resource/tree-planting-steps/
  54. https://extension.okstate.edu/fact-sheets/tree-planting-guide.html
  55. https://extension.unh.edu/resource/planting-and-mulching-trees-and-shrubs-fact-sheet
  56. https://www.treesaregood.org/treeowners/plantingtrees
  57. https://www.landscapeprofessionals.org/LP/LP/Safety/PPE.aspx
  58. https://extension.umd.edu/resource/landscape-planning
  59. https://extension.msstate.edu/publications/home-landscape-design
  60. https://extension.missouri.edu/publications/mg11
  61. https://www.extension.iastate.edu/fayette/files/documents/HomeLandscapeWorksheet.pdf
  62. https://hgic.clemson.edu/factsheet/vine-selections-for-landscaping/
  63. https://extension.missouri.edu/publications/g6840
  64. https://www.epa.gov/watersense/landscaping-tips
  65. https://gardeningsolutions.ifas.ufl.edu/design/landscaping-for-specific-sites/gardening-with-limited-space/
  66. https://extension.colostate.edu/resource/xeriscaping-retrofit-your-yard/
  67. https://engagement.source.colostate.edu/front-yard-xeriscape-ideas-with-photos-of-drought-tolerant-colorado-landscapes/
  68. https://johnston.ces.ncsu.edu/2021/02/basic-steps-for-home-landscaping/
  69. https://www.mass.gov/doc/more-than-just-a-yard-ecological-landscaping-tools-1/download
  70. https://www.angi.com/articles/how-much-does-landscaping-cost.htm
  71. https://www.homeadvisor.com/cost/landscape/install-landscaping/
  72. https://extension.umn.edu/news/trends-garden-designs-2025
  73. https://www.epa.gov/watersense/watering-tips
  74. https://extension.umn.edu/lawn-care/water-saving-strategies-home-lawns
  75. https://uslawns.com/blog/effective-commercial-landscape-ideas-to-beautify-your-business/
  76. https://www.fiveseasonslandscape.com/business-park-landscape-design/
  77. https://www.nycgovparks.org/parks/centralpark
  78. https://www.centralparknyc.org/about
  79. https://www.landscapeperformance.org/collections/the-case-for-green-schoolyards
  80. https://www.usa-shade.com/blog/guide-to-hospital-healing-gardens-and-landscape-architecture/
  81. https://www.theatlantic.com/health/archive/2013/03/how-nature-resets-our-minds-and-bodies/274455/
  82. https://www.permogreen.com/blog/2024/october/commercial-landscaping-how-to-enhance-safety-and/
  83. https://www.vandalstop.com/blog/how-to-prevent-vandalism-public-parks
  84. https://pipelinenc.net/ada-compliant-landscaping-accessibility-in-commercial-landscapes/
  85. https://citychangers.org/singapore-gardens-by-the-bay/
  86. https://www.fs.usda.gov/wildflowers/Native_Plant_Materials/documents/intronatplant.pdf
  87. https://tpwd.texas.gov/wildlife/birding/bird-city-texas/resources/habitat-resources
  88. https://www.kcmo.gov/programs-initiatives/kc-green/native-plants
  89. https://www.dcr.virginia.gov/natural-heritage/native-vs-aliens
  90. https://extapps.dec.ny.gov/docs/remediation_hudson_pdf/hrebch13.pdf
  91. https://extension.psu.edu/rain-gardens-bioretention-cells-a-stormwater-bmp/
  92. https://www.epa.gov/soakuptherain/soak-rain-rain-gardens
  93. https://www.epa.gov/soakuptherain/soak-rain-permeable-pavement
  94. https://pmc.ncbi.nlm.nih.gov/articles/PMC8166338/
  95. https://vtechworks.lib.vt.edu/bitstreams/771d0c02-15f9-4bd8-b613-07e24c71ef6d/download
  96. https://www.nrcs.usda.gov/conservation-basics/natural-resource-concerns/soil/soil-health
  97. https://extension.umd.edu/resource/organic-matter-and-soil-amendments
  98. https://www.epa.gov/heatislands/using-green-roofs-reduce-heat-islands
  99. https://www.nps.gov/articles/000/uerla-trees-air-pollution.htm
  100. https://www.fs.usda.gov/nrs/pubs/jrnl/2014/nrs_2014_nowak_001.pdf
  101. https://edis.ifas.ufl.edu/publication/SS646
  102. https://extension.unh.edu/resource/pruning-deciduous-trees-fact-sheet
  103. https://yardandgarden.extension.iastate.edu/how-to/proper-time-prune-trees-and-shrubs
  104. https://hort.extension.wisc.edu/articles/pruning-deciduous-trees/
  105. https://www.eng.uc.edu/~beaucag/DripIrrigation/Books/Singh%2C%2520Ajay%2520-%2520An%2520introduction%2520to%2520drip%2520irrigation%2520systems-New%2520Delhi%2520Publishers%2520%282012%29.pdf
  106. https://hgic.clemson.edu/factsheet/fertilizing-trees-shrubs/
  107. https://njaes.rutgers.edu/fs102/
  108. https://extension.okstate.edu/fact-sheets/integrated-pest-management-ipm-for-the-home-landscape.html
  109. https://ipm.ucanr.edu/GENERAL/whatisipmurban.html
  110. https://lgpress.clemson.edu/publication/biological-control-strategies-in-integrated-pest-management-ipm-programs/
  111. https://extension.okstate.edu/fact-sheets/winter-protection-for-landscape-plants.html
  112. https://www.canr.msu.edu/news/smart_winter_protection_for_trees_and_shrubs
  113. https://yardandgarden.extension.iastate.edu/how-to/spring-garden-tasks
  114. https://extension.psu.edu/lawn-management-through-the-seasons/
  115. https://byf.unl.edu/hardscapes/
  116. https://www.umass.edu/agriculture-food-environment/sites/ag.umass.edu/files/pdf-doc-ppt/lawn_bmp_establishment_2016_final.pdf
  117. https://www.epa.gov/system/files/documents/2022-04/green-infrastructure-toolbox_raingardens.pdf
Add your contribution
Related Hubs
Contribute something
User Avatar
No comments yet.