20 River Terrace, The Solaire

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Overview

• Location: New York, NY
• Building type(s): Multi-unit residential
• New construction
• 357,000 sq. feet (33,100 sq. meters)
• Project scope: 27-story building
• Urban setting

• Completed August 2003
  The project was delayed due to its proximity to the World Trade Center site. Construction resumed June 2002.

• Rating: U.S. Green Building Council LEED-NC, v.2/v.2.1--Level: Gold (41 points)
  Rating: Green Building Challenge --Level: 2.0

The Solaire at 20 River Terrace is a 27-story, 293-unit, glass-and-brick residential tower in Battery Park City, a planned residential and commercial neighborhood built on landfill bordering the west side of New York City's financial district and directly adjacent to the site of the former World Trade Center. It is the first building designed in accordance with new environmental guidelines instituted in 2000 by the Battery Park City Authority (BPCA), the government entity that has overseen the development of Battery Park City since 1969.

Environmental Aspects

20 River Terrace was designed to consume 35% less energy, reduce peak demand for electricity by 65%, and require 50% less potable water than a conventional, residential high-rise building. An integrated array of photovoltaic panels generates 5% of the building's energy at peak loading. The building incorporates an advanced HVAC system, fueled by natural gas and free of ozone-depleting refrigerants. Multi-level humidification and ventilation systems supply filtered fresh air to each residential unit. Daylighting was maximized and balanced with the thermal envelope. High-performance casement windows were used throughout. All residential units include programmable digital thermostats, Energy Star fixtures, and a master shut-off switch. Common areas include occupancy sensors and daylight sensors to further optimize energy use.

An on-site black water treatment and reuse system supplies the cooling tower and the building's toilets with water. A stormwater catchment system provides irrigation to both a rooftop garden and a green roof. 66.8% of the building's materials (by cost) were manufactured within a 500-mile radius of the site, and 19% contain recycled content. All materials are free of formaldehyde and contain low- or no-VOC's. More than 93% of the construction waste for the project was recycled. The building was extensively commissioned and has sophisticated monitoring systems.

Owner & Occupancy

• Owned by Albanese Organization, Inc. and Northwestern Mutual Life, Corporation, for-profit

• Occupants: Individual(s)

• Typically occupied by 578 people, 84 hours per person per week; and 89 visitors per week, 8 hours per visitor per week

Building Programs

Indoor Spaces:	Living quarters, Structured parking, Lobby/reception, Restrooms
Outdoor Spaces:	Garden—decorative, Patio/hardscape

Keywords

Integrated team, Green framework, Green specifications, Contracting, Commissioning, Performance measurement and verification, Transportation benefits, Stormwater management, Water harvesting, Efficient fixtures and appliances, Efficient irrigation, Graywater, Wastewater treatment, Insulation levels, Glazing, Airtightness, HVAC, Lighting control and daylight harvesting, Efficient lighting, On-site renewable electricity, Cogeneration, Benign materials, Recycled materials, Local materials, C&D waste management, Occupant recycling, Daylighting, Natural ventilation, Ventilation effectiveness, Moisture control, Thermal comfort, Low-emitting materials, Indoor air quality monitoring

Team & Process

The success of 20 River Terrace was the result of the commitment and efforts of many parties on the team. The Battery Park City Authority (BPCA) maintains ownership of all of Battery Park City with all parcels leased to building owners on a long-term basis. BPCA gave the process a regulatory push with the establishment of the BPCA Environmental Guidelines in 2000. They then designated a developer who took the environmental mission to heart and exceeded the guidelines’ objectives in the pursuit of an exceptional building that would set a new standard. 20 River Terrace was developed as a rental building, with the developers as the intended long-term owner and operator. Thus, they were very interested in life-cycle costs, overall performance, and operational issues.

In the initial project meeting, the developer laid out the objectives of satisfying the requirements of the Battery Park City Environmental Guidelines, meeting the criteria set for the New York State Green Building Tax Credit, and submitting for a Gold or Platinum LEED certification. Though these were overlapping objectives from the start, differences were discovered along the way and some interpretation was required. In order to meet these objectives, the design process required heavy involvement in the early design stages by a larger consultant team than is typical for this building type. The process also required closer coordination than a typical large building project, and there were ongoing research efforts to confirm the costs, compatibility, and constructability of all systems. Many advertised products were not yet available. This early and intensive analysis allowed for the integration of systems as the design evolved.

The design of the exterior envelope was one of the most complex analyses. The design intention of weaving the photovoltaics through a brick-and-glass exterior wall to achieve a full integration, while optimizing traditional brick-and-block wall performance, touched on many issues. The final wall design required input from product manufacturers (especially the photovoltaics manufacturer), wind-tunnel tests to set air-infiltration rates for traditional walls, computer simulations (using DOE-2, THERM and CONTAM) to test alternatives, and contractors to assess electrical coordination issues and overall wall constructability to reconfigure the typical section.

The contributions of an at-risk construction manager were vital to the examination local labor practices for constructability questions. Similarly, the understanding of the tax and grant possibilities was essential to the project and required substantial input from the developer’s project management staff.

20 River Terrace is the first building built to meet the new BPCA Environmental Guidelines. There was a great deal of cooperation with BPCA to determine appropriate interpretations of the guidelines and to assist with the New York City zoning and building codes. The final building is serving as a test case for the consideration of comparable requirements in other New York City buildings, including many of the new structures to be built at the site of the former World Trade Center.

Early research uncovered very little data to use as benchmarks for the evaluation of high-rise residential structures. As a completed structure, extensive monitoring programs and continuous commissioning will provide data to multiple public agencies as well as to the building owner. Taken together, these efforts set firm benchmarks for new buildings and provide a laboratory to assist in the evolution of future design standards.

• DOE 2.1 E
• CONTAM
• THERM
• Autocad 2002 1

Russell Albanese The Albanese Organization, Inc. Owner/developer Garden City, NY [http://www.albaneseorg.com/](http://www.albaneseorg.com/)

Nicholas Jahnke Northwestern Mutual Life Corporation Co-owner MacLean, VA

Timothy Carey Battery Park City Authority Land owner / governing authority New York, NY [http://www.batteryparkcity.org/](http://www.batteryparkcity.org/)

Rafael Pelli Cesar Pelli & Associates Design architect New York, NY [http://www.cesar-pelli.com](http://www.cesar-pelli.com)

[David Hess](learnmore.cfm?ProjectID=273) Cesar Pelli & Associates Architect (Project manager) New York, NY [http://www.cesar-pelli.com](http://www.cesar-pelli.com)

Richard De Marco Schuman, Lichtenstein, Claman, Efron Architects Architect of record New York, NY

Marvin Lewin Cosentini Associates MEP Engineer New York, NY [http://www.cosentini.com/](http://www.cosentini.com/)

Silvian Marcus The Cantor Seinuk Group, Inc. Structural engineer New York, NY [http://www.cantorseinuk.com](http://www.cantorseinuk.com)

Adrian Tuluca Steven Winter Associates Energy consultant Norwalk, CT [http://www.swinter.com](http://www.swinter.com)

Asher Derman Green October Environmental building consultant Elizabeth, New Jersey

Jeffery Boynton Ann Kale Associates Lighting designer Santa Barbara, CA

Diana Balmori Balmori Associates Landscape architect New York, NY [http://www.balmori.com/](http://www.balmori.com/)

Tim Button Stedila Design, Inc. Interior designer New York, NY

Edward Clerico Applied Water Management Water reuse consultant Belle Mead, NJ [http://www.appliedwater.com/](http://www.appliedwater.com/)

Michael English Horizon Engineering Commissioning agent New York, NY [http://www.horizon-engineering.com/](http://www.horizon-engineering.com/)

Charlie Avolio Turner Construction Company Construction manager New York, NY [http://www.turnerconstruction.com/](http://www.turnerconstruction.com/)

[Michael Gubbins](learnmore.cfm?ProjectID=273) The Albanese Organization, Inc. Resident manager

The design team also included:

• Civil engineer
• Contractor

Finance & Cost

The project was initially financed through a traditional construction loan and long-term financing. All work was postponed following the September 11 World Trade Center attacks in 2001. Financing was withheld, requiring the developer, along with the Battery Park City Authority, to re-structure. The new financing structure used an innovative approach including public-sector participation that was subsequently replaced by economic incentive Liberty Bonds issued by the State of New York Housing Finance Authority. These were combined with permanent credit enhancement through a private bank.

The project met the stringent requirements necessary to qualify for the New York State Green Buildings Tax Credit, a pilot program designed to encourage the design and development of more environmentally sustainable buildings. The value achieved by the tax credit over five years is $2,800,000.

Additional funding was obtained from The New York State Energy Research and Development Authority (NYSERDA) for several elements of the project. Through its New Construction Program (NCP) NYSERDA provided a $100,000 grant for LEED design assistance and energy modeling, a $319,079 incentive for EEMs that reduce the use of electricity, and $119,000 for commissioning. NYSERDA also provided a $90,000 grant for the purchase of the photovoltaic panels. In conjunction with NYSERDA, the U.S. Department of Energy contributed $100,000 to the commissioning of The Solaire.

• Credit Enhancement: Loan guarantees-private
• Equity: Cash, Green building tax credits, Other tax credits
• Grant: Public agency

Cost data in U.S. dollars as of date of completion.

• Total project cost (land excluded): $114,500,000
• Property cost: $20,000,000

• Soft cost: $34 per sq foot ($370 per sq meter)

  • professional fee: $12 per sq foot ($130 per sq meter)
  • management fee: $8 per sq foot ($90 per sq meter)
  • finance: $13 per sq foot ($140 per sq meter)

• Hard cost: $248 per sq foot ($2,670 per sq meter)

  • construction: $247 per sq foot ($2,660 per sq meter)

Some of the green features and technologies had especially high first costs but are expected to pay for themselves within a few years. The $375,000 photovoltaic system has an estimated after-tax 4-year payback period. The low-e glazing casement windows cost approximately $1,500,000 and have an estimated 7-year payback, and the $125,000 lighting control system has an estimated after-tax 4-year payback. The wastewater treatment system cost approximately $1,000,000. Payback for this system cannot be readily calculated.

Land Use & Community

The 0.38-acre site lies in the North Residential Area of Battery Park City, a 92-acre, publicly sponsored, mixed-use landfill project on the Hudson River in lower Manhattan. 52% of Battery Park City is dedicated to public uses that include parks, recreational facilities, and museums. The building site for 20 River Terrace was predetermined, and the building footprint occupies the entire site.

This building was designed in accordance with the overall urban design plan and guidelines prepared for Battery Park City. Building height, building form, and exterior building materials – such as the brick used for the majority of the exterior wall and the stone at the base and expression zone at the top levels – are dictated by those guidelines. 20 River Terrace helps to enclose a shared green space, Teardrop Park, and provides water for its irrigation. All of the adjacent parks and green spaces at the ground level existed prior to the construction of the building.

Community Connection

Battery Park City is a planned residential community with a high percentage of landscaped, public, open space. It is located in a dense urban environment within walking distance of New York City’s financial district and multiple nearby public transportation options. No parking is included in the building’s zoning requirements. Parking spaces are limited to fewer than 20% of the number of residential units, and they are provided in a basement garage. The building owners have contracted with ZipCar, a company offering on-demand access to rental cars, to provide hybrid technology vehicles with first priority given to building residents. Taxis and buses serve the immediate area, and subway service is located within 2,000 feet of the building. Extensive ferry service is located on the adjacent waterfront. The key efficiency measure for transit use is the building’s location in New York City, where few people use cars as their primary mode of transportation. Storage has been provided for bicycles, and provisions have been made for electric vehicle charging.

20 River Terrace is surrounded by existing public parks and other public facilities. Many of the design criteria, including form, massing, and the use of specified materials, were mandated by the master plan. The building contains public restroom facilities to serve the surrounding area.

There is no specific data on the building's population using single-occupancy vehicles; however, public transit use in New York City is the highest in the nation.

• Responsible Planning

  • Ensure that development fits within a responsible local and regional planning framework

• Support for Appropriate Transportation

  • Design development to have pedestrian emphasis rather than automobile emphasis

  • Provide safe access for bicyclers and pedestrians
  • Provide storage area for bicycles
  • Provide access to public transportation
  • Design houses to be adaptable for home office use

Site Description

The stormwater management measures are intended to accomplish the following:

1. Decrease the stormwater volumes and velocities associated with development-induced changes in hydrology;

2. remove suspended solids and associated pollutants entrained in stormwater volumes; and

3. Retain hydrological conditions that closely resemble those of the pre-disturbance condition.

The system consists of a vegetated roof and stormwater retention and reuse.

The vegetated roof is designed to include approximately 57% of the site area (75% of the open roof area). Beneath the vegetation and soil the design includes a water retention layer that reduces the velocity of water flow, giving soil and vegetation an opportunity to utilize the stormwater before it reaches the building stormwater infrastructure. The planting materials include drought-tolerant self-sustaining shrubs, perennials, and bamboo, resistant to wind damage and adaptable to shallow soil depths between 6” and 18”.

The stormwater retention system is designed to retain 10,000 gallons of stormwater in a tank located in the basement. Within this tank is a sediment basin and treatment system. The retained water is reused for irrigation for the vegetated roof and adjacent park. The planted roofs and high-albedo roofing materials minimize the building's contribution to the urban heat island effect.

• Lot size: 16,700 ft2
• Building footprint: 16,700 sq ft (1,550 sq meters)
• Previously developed land

Water Conservation and Use

20 River Terrace has an on-site blackwater system that recycles 100% of the building’s wastewater. Water recaptured by the system is used to supply the cooling tower and the building’s toilets, and 5,000 gallons per day are provided to the adjacent public park. 50% less potable water is needed from the municipal water supply than would be used in a conventional apartment building, and no potable water is used outdoors. Low-flow appliances and fixtures are used, and the public restroom facilities use waterless urinals.

Stormwater runoff is collected in a storage tank in the building’s basement. The system will capture approximately 170,000 gallons of water per year, to be used for irrigation of the rooftop gardens. The system was designed to precisely accommodate the irrigation load for the site, allowing for reduction of the capacity of the retention tank by 60% and utilizing 100% of the stormwater captured on the site.

Rooftop plants were selected for visual interest, drought tolerance, resistance to wind damage, and adaptability to shallow soil depths. They consist of masses of self-sustaining shrubs, perennials, and bamboo. The roof system beneath the plants was designed to retain nearly 70% of rainwater for eventual use by the plants. The process of evapotranspiration contributes to a cooling effect in the garden’s microclimate.

Water Use -

Indoor potable water use: 4,440,000 gal/yr
(16,800,000 liters/yr)

• Outdoor potable water use: 0 gal/yr (0 liters/yr)

• Total potable water use: 4,440,000 gal/yr (16,800,000 liters/yr)

• Potable water use per occupant: 7,680 gal/person/yr (29,100 liters/person/yr)

• Potable water use per unit area: 12.4 gal/sq ft (507 liters/sq meter)

• Runoff Reduction

  • Design a green roof system

• Water Conservation Education

  • Educate residents about water conservation

• Low-Water-Use Fixtures

  • Use low-flow toilets

• Managing Stormwater

  • Use subsurface infiltration basins

• Rainwater Collection

  • Collect and store rainwater for landscape irrigation
  • Collect and filter rainwater for use in cooling towers

• Wastewater and Graywater Recycling

  • Design buildings to use treated wastewater for non-potable uses
  • Plumb building to accommodate graywater separation

• Irrigation Systems

  • Retain water on site in pond for irrigation
  • Recycle graywater for landscape irrigation

Energy

The exterior walls were extensively studied to maximize thermal performance while working with local labor practices to maintain maximum quality control. A central HVAC (heating, ventilating, and air-conditioning) system was chosen for its energy efficiency and to maintain the integrity of the wall. Plumbing, electrical, and other penetrations through the building envelope were minimized, reducing air infiltration. 3,400 square feet of photovoltaic panels generate 5% of the base building overall energy requirements at peak performance. Panels are located on the building's west façade and clipped onto the mechanical bulkhead on the roof. Locations were chosen to balance efficiency with the associated costs of installation.

Energy-conserving technologies include an efficient gas-based chiller system; high-efficiency and variable-speed pumps, motors, and fans; and the re-use of waste heat from mechanical systems. Efficient lamps and fixtures and occupancy and daylight sensors further minimize electricity use. Energy Star appliances and a computerized building management system increase overall energy efficiency.

Energy Security

The building’s photovoltaic system is designed to operate at peak production coincident with peak demand on the local power grid. Placement of the photovoltaic cells on the west portion of the building’s façade takes advantage of the intensity and position of the sun in the summer months. The building makes use of a gas-fired chiller, further reducing the electric load. This is especially significant during periods of peak demand when the New York City power grid does not have the necessary distribution system to accommodate demand. At these times, users rely on supplemental power provided by highly polluting generators. The gas-fired chiller in use at 20 River Terrace reduces the need to rely on power from these highly polluting sources.

During a blackout, building ventilation is provided by operable windows, and lighting is provided by daylighting and battery-powered emergency lighting. Space has been provided for the installation of fuel-cell technology, eliminating the need for costly building modifications when such technology is more mature and its use is more viable. On-site renewable energy sources include only photovoltaic technology.

Bioclimatic Design

The site plan, massing, orientation, and primary building materials were all dictated by the BPCA guidelines. The photovoltaic panels were located to take advantage of unobstructed sun exposure to the west. The south façade of the building will be predominantly in shadow following the completion of a proposed new building.

 

Materials & Resources

A total of 66.79% of the building materials (by cost) were manufactured within a 500-mile radius of the building. An effort was made to ensure that 50% of these materials also contained raw materials extracted from the local area. The materials used contained 19% recycled content (when measured using the LEED calculation method), and materials manufactured with renewable or rapidly renewable resources were used whenever possible. The photovoltaic cells were made from 100% recycled materials.

Building materials included concrete masonry blocks with a portion of the cement replaced by fly-ash, recycled content gypsum board, locally manufactured brick, cast stone, slate and granite, ceramic tile, recycled content aluminum, and FSC certified woods. Many of the exterior building materials were pre-determined by the BPCA guidelines.

Only materials free of formaldehyde and containing low or no VOC’s were used. VOC limits of South Coast Air Quality Management District Rule #1168; Bay Area Air Quality Management District Reg. 8; Rule 51 for adhesives and sealants were used. Indoor air quality testing included criteria of a total VOC of 200 micrograms per cubic meter above the outside air, and criteria for formaldehyde at 50 parts per billion.

All sub-contractors were required to submit a plan noting the anticipated weight of all on-site construction waste they would produce. This allowed the contractor to plan for the volume of waste that would have to be disposed of. All site-generated construction waste was brought to a transfer station, where it was sorted by category to be sold for re-use. 93% (by weight) of the construction waste for 20 River Terrace was recycled.

• Coal Fly Ash
• Cork Flooring Tiles
• Energy-Efficient Refrigerators
• Green Roof System
• High-Performance Insulating Glass
• Recycled-Content Gypsum Board
• Recycled-Content Mineral Wool Insulation
• Recycled-Content Mineral-Fiber Ceiling Panels and Tiles
• Slate Roofing Shingles

The developers saw the larger up-front costs of this project as an investment that would give the building greater enduring value and would allow them to rent the units for a premium price. This has proven to be true. The building is a flat-slab structure, typical of NYC concrete construction, and there is great flexibility to reconfigure the apartments to meet changing demands of tenants over time. It is not particularly adaptable to non-residential uses, but it is unlikely that the building would undergo that kind of conversion. The anticipated service life of the building is 75-100 years. This compares favorably to existing high-rise apartment buildings in New York City, with many highly desirable buildings over 70-80 years old.

• Protection of Global Ecosystem

  • Minimize ozone-depletion potential of refrigerants in cooling systems

• Job Site Recycling

  • Investigate local infrastructure for recycling

  • Seek a waste hauler who can separate recyclables out of commingled waste

  • Require a waste management plan from the contractor

• Recycling by Occupants

  • Design a physical in-house recycling system

• Greenhouse Gas Emissions from Manufacture

  • Use concrete masonry units with flyash replacing a portion of the cement

  • Replace up to 30% of the cement in concrete with flyash

• Transportation of Materials

  • Prefer materials that are sourced and manufactured within the local area

Indoor Environment

Air

The indoor air quality at 20 River Terrace follows stringent standards, with fully filtered, humidified, centrally conditioned air provided to all residential units and common spaces. Combined with the low- or no-VOC materials choices discussed on the Materials page, this provides an indoor environment that is benign and healthy. All apartments have digitally programmable thermostats and operable windows, allowing for occupants to choose between fresh and conditioned air. The building maintains seasonally adjusted humidity levels of between 30% and 60%, and a positive air pressure is maintained within the building. The parking garage is equipped with carbon-monoxide monitors, and outdoor-air intakes throughout the building are located away from pollution sources. A comprehensive commissioning plan is in place, in order to ensure that the building meets its intended design standards.

Light

High ceilings and large windows provide a generous amount of daylight to all the apartments. The lobby was designed to optimize the use of daylight with large windows facing the surrounding park space. Occupancy or daylight sensors are employed in all public spaces. Fluorescent lighting and master shut-off switches are provided in all apartments.

• Entry of Pollutants

  • Locate outdoor air intakes away from pollution sources
  • Keep positive pressure in the building

• Thermal Comfort

  • Use glazing with a low Solar Heat Gain Coefficient
  • Maintain relative humidity levels between 30% and 60%

  • Provide occupants with the means to control temperature in their area

• Visual Comfort and Light Sources

  • Use electronic ballasts with fluorescent lighting
  • Provide occupants with control of light in their area
  • Provide illumination sensors

• Ventilation and Filtration Systems

  • Provide occupants with access to operable windows

• Building Commissioning for IEQ

  • Use a comprehensive commissioning process to ensure that design intent is realized

Awards

• AIA/COTE Top Ten Green Projects in 2004

• Environmental Design & Construction Magazine Excellence in Design Awards in 2004;  Category/title: Multi-Use Residential Category Winner

• Green Roofs for Healthy Cities Award in 2004;  Category/title: Intensive Residential

Ratings

• U.S. Green Building Council LEED-NC, v.2/v.2.1 in 2004;  achievement level: Gold (41 points)

  • Sustainable Sites, 10 of 14 possible points

    • SS Prerequisite 1, Erosion & Sedimentation Control
    • SS Credit 1, Site Selection
    • SS Credit 2, Urban Redevelopment

    • SS Credit 4.1, Alternative Transportation, Public Transportation Access

    • SS Credit 4.2, Alternative Transportation, Bicycle Storage & Changing Rooms

    • SS Credit 4.4, Alternative Transportation, Parking Capacity
    • SS Credit 6.1, Stormwater Management, Rate and Quantity
    • SS Credit 6.2, Stormwater Management, Treatment

    • SS Credit 7.1, Landscape & Exterior Design to Reduce Heat Islands, Non-Roof

    • SS Credit 7.2, Landscape & Exterior Design to Reduce Heat Islands, Roof

    • SS Credit 8, Light Pollution Reduction

  • Water Efficiency, 5 of 5 possible points

    • WE Credit 1.1, Water Efficient Landscaping, Reduce by 50%

    • WE Credit 1.2, Water Efficient Landscaping, No Potable Water Use or No Irrigation

    • WE Credit 2, Innovative Wastewater Technologies
    • WE Credit 3.1, Water Use Reduction, 20% Reduction
    • WE Credit 3.2, Water Use Reduction, 30% Reduction

  • Energy and Atmosphere, 3 of 17 possible points

    • EA Prerequisite 1, Fundamental Building Systems Commissioning
    • EA Prerequisite 2, Minimum Energy Performance
    • EA Prerequisite 3, CFC Reduction in HVAC&R Equipment
    • EA Credit 3, Additional Commissioning
    • EA Credit 4, Ozone Depletion
    • EA Credit 5, Measurement and Verification

  • Materials and Resources, 6 of 13 possible points

    • MR Prerequisite 1, Storage & Collection of Recyclables
    • MR Credit 2.1, Construction Waste Management, Divert 50%
    • MR Credit 2.2, Construction Waste Management, Divert 75%

    • MR Credit 4.1, Recycled Content: 5% (post-consumer + 1/2 post-industrial)

    • MR Credit 4.2, Recycled Content: 10% (post-consumer + 1/2 post-industrial)

    • MR Credit 5.1, Local/Regional Materials, 20% Manufactured Locally

    • MR Credit 5.2, Local/Regional Materials, of 20% Above, 50% Harvested Locally

  • Indoor Environmental Quality, 13 of 15 possible points

    • EQ Prerequisite 1, Minimum IAQ Performance
    • EQ Prerequisite 2, Environmental Tobacco Smoke (ETS) Control
    • EQ Credit 1, Carbon Dioxide (CO2) Monitoring

    • EQ Credit 3.1, Construction IAQ Management Plan, During Construction

    • EQ Credit 3.2, Construction IAQ Management Plan, Before Occupancy

    • EQ Credit 4.2, Low-Emitting Materials, Paints
    • EQ Credit 4.3, Low-Emitting Materials, Carpet
    • EQ Credit 4.4, Low-Emitting Materials, Composite Wood
    • EQ Credit 5, Indoor Chemical & Pollutant Source Control
    • EQ Credit 6.1, Controllability of Systems, Perimeter
    • EQ Credit 6.2, Controllability of Systems, Non-Perimeter
    • EQ Credit 7.1, Thermal Comfort, Comply with ASHRAE 55-1992
    • EQ Credit 7.2, Thermal Comfort, Permanent Monitoring System
    • EQ Credit 8.1, Daylight & Views, Daylight 75% of Spaces
    • EQ Credit 8.2, Daylight & Views, Views for 90% of Spaces

  • Innovation and Design Process, 4 of 5 possible points

    • ID Credit 1.1, Innovation in Design
    • ID Credit 1.2, Innovation in Design
    • ID Credit 1.3, Innovation in Design
    • ID Credit 2, LEED® Accredited Professional

  The Solaire received "Innovation in Design" credits for "Operations and Maintenance Plan," "Regorous Water Use Reduction," and "Exemplary Performance in Recycled Content."

• Green Building Challenge in 2002;  achievement level: 2.0

Lessons Learned

The design for 20 River Terrace required an investigation into many issues for which there was little precedent. As the first of eight buildings planned to be built under new environmental guidelines, the building's design and performance is being extensively documented by public agencies to assist in future projects. Some lessons learned include the following:

• Advances in computer simulation allowed for much more extensive study of system and envelope options in the conceptual design phase.

• Local labor practice and construction methodology are as critical to sustainable design implementation as proper design and available technology.

• Analysis of building performance for various submissions relied heavily on performance relative to benchmarks. Very little benchmark data exists for high-rise residential buildings in New York City, and building standards vary widely compared to commercial structures.

• Indoor Air Quality and Energy Efficiency are competing goals once a central plant is used for ventilation, dehumidification, and air filtration. Integrated technical systems that optimize both remain to be developed. Exhaust rates need to be re-examined.

• Underlying data is often insufficient for best-practice decisions. An example is the requirement for a 500-mile radius for the sourcing of materials. This requirement often doesn’t correspond to embodied energy due to transportation methods.

Learn More

It is possible to visit this project and tours are available. 20 River Terrace can be visited by appointment. Please contact Michael Gubbins.

Location Information and directions can be found at the Battery Park City Authority Web site.

Michael Gubbins (Tour Contact) The Albanese Organization, Inc.   212-528-0100

• Magazines

  • Battery Park City's Environmental Guidelines
    Publication: Environmental Building News Vol. 11, No.6 (June 2002)
    This short article describes the PBCA Environmental Guidelines, which helped define the design intent of the Solaire. http://www.buildinggreen.com/auth/article.cfm?fileName=110605d.xml

  • New York's First Green Residential High-Rise at Battery Park City by Malin, Nadav
    Publication: Environmental Building News Vol. 9, No.11 p. 2 (November 2000)
    This article documents plans for 20 River Terrace as they stood in November 2000. http://www.buildinggreen.com/auth/article.cfm?fileName=091102a.xml

• Web sites

  • Battery Park City Authority
    This is the main Web page for the Battery Park City Authority.

  • First "Green" High-Rise Residential Building In The World
    Publication: IAQ News Vol. 49, No.9 (10-2-2002) ISBN: 1096-7214
    This article offers an overview of 20 River Terrace and some of its green-design features.

  • The Solaire
    This Web site includes detailed information about the building, including floorplans and views from the apartments.

  • Writing the Green RFP (April 2003)
    This free, online resource includes Battery Park City's RFP as an example.

• Others

  • Newspaper article: A Look at the Future of Residential Buildings by Johnson, Kirk
    Publication: The New York Times (10-15-2002)
    This article, from the October 15, 2002 New York Times, explains 20 River Terrace to a general audience. http://www.nytimes.com/2002/10/15/nyregion/15GREE.html?ex=1035729303&ei=1&e
    n=59fc6ffbe5f07d1c

  • Brochure: Highlighting High Performance: Twenty River Terrace: Battery Park City, New York, New York (2002)
    This brochure, from the National Renewable Energy Laboratory, is one in the Highlighting High Performance series. (PDF 1.50 MB) Download Acrobat Reader

  • Newspaper article: Luxuriously Green: Environmentally Friendly Building Planned for Manhattan by Dobnik, Verena
    Publication: ABCNews.com (6-22-00)
    This June 2000 Associated Press article provides a basic overview of plans for 20 River Terrace. http://abcnews.go.com/sections/science/DailyNews/apartment_green000622.html

David Hess Cesar Pelli & Associates Architect (Project manager) 322 Eighth Avenue, 18th floor New York, NY  10001 212-417-9496 [http://www.cesar-pelli.com](http://www.cesar-pelli.com)