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Alaskan Way Viaduct

The Alaskan Way Viaduct was an elevated highway segment of State Route 99 (SR 99) in Seattle, Washington, extending approximately two miles along the city's waterfront from the neighborhood northward to the Battery Street Tunnel. Constructed in phases from 1949 to 1959 to bypass congested surface streets and facilitate north-south travel parallel to the denser corridor, its initial section opened on April 4, 1953, and it ultimately carried around 110,000 vehicles per day by the early . The structure suffered significant damage during the , exposing its vulnerability to seismic events and accelerating replacement efforts amid ongoing debates over options including a new elevated structure, surface streets, or a bored tunnel. Ultimately, the viaduct closed permanently on January 11, 2019, was succeeded by a two-mile SR 99 tunnel that opened to traffic on February 4, 2019, and underwent demolition thereafter, enabling waterfront redevelopment and improved urban connectivity.

Physical Characteristics

Route Description

The Alaskan Way Viaduct formed the elevated core of State Route 99's waterfront corridor in , , extending 2.2 miles (3.5 km) in a predominantly north-south alignment parallel to Alaskan Way and the eastern shoreline of . This double-decked structure in its northern sections carried two lanes in each direction, elevated approximately 50 feet (15 m) above the surface street to bypass waterfront rail lines, piers, and urban development below. It served as a critical link for regional traffic, connecting southern industrial zones to northern residential and commercial areas while offering views of the and . Commencing at its southern terminus near South Nevada Street in the SoDo neighborhood—adjacent to major venues like T-Mobile Park and Lumen Field—the viaduct ascended from ground level via ramps integrating with surface arterials such as South Royal Brougham Way. It then proceeded northward through Seattle's Industrial District, traversing above piers and wharves before aligning with the historic Pioneer Square area, where it skirted the edges of early 20th-century brick warehouses and the stadium district. Midway, the route hugged the base of downtown Seattle's high-rise core, passing landmarks including the Seattle Aquarium and Bell Street Pier, with interchanges facilitating access to surface streets like Yesler Way and Seneca Street. In its northern reach, the viaduct entered the Belltown district, curving slightly inland to merge with the Battery Street Tunnel entrance near Mercer Street, thereby linking to broader State Route 99 continuity toward Aurora Avenue and points north. The path's design prioritized capacity over scenic integration, resulting in a utilitarian span that shadowed Alaskan Way's two-way traffic below and constrained pedestrian access along until post-demolition transformations. Daily volumes exceeded 100,000 vehicles prior to its closure, underscoring its role as one of Seattle's primary north-south spines alongside Interstate 5.

Engineering Design and Specifications

The Alaskan Way Viaduct was designed as a reinforced concrete girder bridge, spanning approximately 2.1 miles (3.4 km) along the eastern shoreline of Elliott Bay in Seattle, Washington, to carry State Route 99 traffic. Constructed primarily between 1950 and 1953, with additional phases extending to 1959, the structure featured a double-deck configuration in its northern portions, providing a total of six lanes—three on the upper deck and three on the lower—for northbound and southbound travel. The viaduct's reinforced concrete elements included continuous girders supported by columns, with the lower deck maintaining a ceiling height of 14 feet 6 inches (4.4 m). Original engineering specifications emphasized efficient urban waterfront routing over seismic resilience, reflecting mid-20th-century design standards prior to widespread adoption of earthquake-resistant detailing. Columns exhibited substandard transverse , limiting under lateral loads, while spans varied to accommodate terrain and integrate with the adjacent Battery Street Tunnel. The structure's reached up to 50 feet (15 m) above Alaskan Way, utilizing construction methods typical of the era to minimize disruption to port operations below.

Historical Development

Planning and Construction Phase

The concept of an elevated roadway along 's waterfront emerged in the as a response to increasing caused by automobiles, streetcars, and freight rail operations, which hindered maritime commerce and downtown access. In 1911, engineer Virgil Bogue's comprehensive Plan of Seattle proposed street widenings and tunnels to alleviate these issues, but voters rejected the bond measures in 1912, favoring surface improvements instead. By 1916, engineer Albert L. Valentine advocated a mile-long tunnel from the waterfront to Eighth Avenue, though this too failed to advance amid competing priorities like rail relocation. Planning gained momentum in the 1930s amid worsening conditions, including 922 traffic deaths and 179,167 accidents recorded from 1926 to 1936 along the waterfront corridor. The construction of the Alaskan Way seawall and surface roadway from 1934 to 1936 provided temporary relief but highlighted the need for grade separation to bypass rail lines and reduce hazards. In 1934, engineer Ray Murray, previously involved in the Aurora Bridge project, sketched an initial viaduct route paralleling the waterfront; engineer James Bollong proposed a variant in 1935. A 1937 traffic survey by city engineers formally recommended an elevated viaduct for Alaskan Way to handle projected volumes, and in 1939, the Propeller Club of Seattle urged immediate action for congestion relief. Post-World War II federal funding via the 1944 Federal-Aid Highway Act accelerated designs, integrating the viaduct into broader plans for a Seattle Freeway (later Interstate 5) as a north-south bypass around downtown. Construction commenced on February 6, 1950, under the direction of City Engineer R. W. Finke, who authorized the initial excavation, with the project funded by a combination of city ($1.5 million), state (over $1.9 million), and federal ($1.5 million) contributions for the core segment from Battery Street to King Street. The structure, designed as a to carry (later State Route 99), featured eight ramps, two underpasses, and integration with a southern at-grade roadway, prioritizing limited-access efficiency over initial double-decking due to budget constraints. The first southern section opened to traffic on April 4, 1953, ceremonially by Mayor Allan Pomeroy, providing immediate relief after three years of segmented work that displaced some waterfront uses but avoided major disruptions to port operations. Subsequent phases extended the viaduct northward through 1959, including connections to the Battery Street Tunnel (opened 1954) and southward to the district, with the final Columbia Street on-ramp completed on February 1, 1966, marking full operational integration after over a decade of incremental builds.

Early Operation and Expansion

The first section of the Alaskan Way Viaduct opened to traffic on April 4, 1953, marking the initial phase of a multi-stage construction project designed to bypass Seattle's congested downtown waterfront streets. This segment extended approximately 1.5 miles northward from near Pioneer Square to Western Avenue, just beyond the Pike Place Market, and connected to the existing Battery Street Tunnel for continued northbound travel. The opening, officiated by Mayor Allan Pomeroy, provided drivers with an elevated alternative to surface routes like Alaskan Way, reducing travel times through the central business district amid post-World War II population growth and increasing vehicle ownership. Initial operation focused on accommodating north-south traffic along what would become State Route 99, with the viaduct handling freight and commuter flows that previously bottlenecked at rail yards and piers. features, including box girders and minimal seismic considerations typical of mid-20th-century design, supported daily volumes that grew steadily as Seattle's expanded. By integrating with surface ramps and avoiding at-grade interruptions, the facilitated smoother for port-related , though early usage revealed needs for further southward to link with industrial areas south of downtown. Subsequent expansions addressed these gaps through additional phases completed by 1959, extending the viaduct's total length to about 2 miles along the waterfront. The final southern segment, connecting Aurora Avenue (now part of SR 99) to East Marginal Way, opened on September 3, 1959, completing the elevated corridor and enhancing regional access to Seattle's port facilities and southern suburbs. These additions, built across multiple contracts starting from 1949, doubled the effective capacity for through-traffic and integrated the viaduct into the broader , setting the stage for decades of heavy reliance despite lacking modern redundancies.

Pre-2001 Maintenance and Usage

The Alaskan Way Viaduct, completed in phases between 1949 and 1959 with the central section opening on April 4, 1953, initially handled 19,000 vehicles per day, providing a direct waterfront route for State Route 99 that alleviated congestion on surface streets and improved access for southwest neighborhoods. By 1959, following the southern extension, daily traffic volumes reached 37,000 vehicles, reflecting growing reliance on the structure as 's population and port activity expanded. Truck operators particularly favored the viaduct for its elevation, which avoided steep hills and intersections on alternative routes. Traffic volumes continued to rise through the mid-20th century, peaking at approximately 88,000 vehicles per day in the mid-1960s before declining to around 54,000 following the opening of , which diverted some long-distance traffic. By the late 1990s and into 2000, usage rebounded to over 100,000 vehicles daily, positioning the viaduct as a critical artery carrying nearly half the north-south traffic volume of parallel sections while serving commuters, freight from the , and tourists accessing waterfront attractions. This high utilization underscored the structure's economic importance, handling up to 110,000 vehicles per day by the end of the amid Seattle's urban growth. Maintenance efforts prior to 2001 focused primarily on routine upkeep rather than comprehensive seismic upgrades, despite growing awareness of vulnerabilities. A 1991 Washington State legislative approval of the Seismic Risk Reduction Program allocated initial funding for evaluating retrofit or replacement options for the viaduct, recognizing its non-ductile design's susceptibility to earthquakes. However, substantive did not occur, as a 1995 evaluation concluded the structure's seismic vulnerability exceeded modern standards due to inadequate reinforcement in columns, joints, and foundations, yet prioritized other bridges amid budget constraints. Minor repairs addressed wear from heavy traffic and environmental exposure, but the viaduct operated without major structural interventions, relying on its original 1950s engineering amid periodic inspections.

Seismic Risks and 2001 Earthquake

Nisqually Earthquake Damage Assessment

The Nisqually Earthquake, which occurred on , 2001, with a moment magnitude of 6.8, subjected the Alaskan Way Viaduct to moderate ground shaking, resulting in observable structural damage concentrated in the southern section near South Washington Street, specifically at Bents 97–100. Post-earthquake evaluations identified cracking in transverse floorbeams, expansion joints, and longitudinal edge girders within each bent, with the most severe effects at the upper east knee joint of Bent 100, where concrete spalling and fractured reinforcement bars were evident. Additional cracking occurred at the upper east knee joint of Bent 97, alongside vertical displacements of approximately 3 inches at the top of Bent 100 and 1.5 inches at Bent 97, the latter partially attributable to pre-existing . Washington State Department of Transportation (WSDOT) conducted initial drive-through inspections immediately after the event, followed by detailed examinations starting March 2, 2001, including photographic documentation of Pier 100 and crack monitoring installations at Piers 97–103 by April 2. These assessments quantified rotation at Bent 100's lower crossbeam at 0.0045 radians and revealed a rating factor of 0.44 under HS20 loads at the upper crossbeam, indicating marginal capacity and prompting closure to heavy traffic. No significant or failure was observed, and crack monitors recorded no further movement by May 10, 2001, though minor settlements at east footings of Bents 98 (0.4 feet) and 99 (0.5 feet) were noted as likely pre-earthquake. Engineering analyses, including inelastic modeling, confirmed the damage's consistency with observed ground motions but underscored the viaduct's , estimating a at a 210-year event with spectral acceleration of 0.26g, below levels anticipated for larger quakes. While immediate repairs stabilized the structure for partial reopening, the assessments highlighted systemic issues like corrosion-exacerbated cracking in crossbeams—evident since the —and reinforced calls for comprehensive seismic or to address inherent limitations from its 1950s era.

Immediate Response and Partial Closures

Following the magnitude 6.8 Nisqually earthquake on February 28, 2001, the Alaskan Way Viaduct was immediately closed to traffic for structural inspections, as initial observations revealed visible damage including settlement and cracking in floor beams and column connections. Emergency response teams from the (WSDOT) conducted rapid assessments, identifying light apparent damage at first but confirming shear cracks near column corbels and transverse floor beam fractures upon closer examination. Temporary and repairs allowed the viaduct to reopen after approximately one day, with crews stabilizing the most critically affected sections to restore partial functionality amid ongoing evaluations. However, further inspections in early 2001 uncovered propagating cracks at column tops and additional settlement of 2-3 inches in some areas, necessitating additional closures for targeted reinforcements and monitoring instrumentation installation. As part of the post-earthquake safety protocol, WSDOT established routine partial closures, limiting access to specific segments twice annually for detailed seismic inspections to detect ongoing deterioration and ensure short-term operability, a measure implemented from onward until full replacement planning advanced. These interventions, while disruptive to Seattle's carrying up to 100,000 vehicles daily, prioritized given the viaduct's pre-1950s lacking seismic standards.

Debates on Long-Term Viability

Engineering Evaluations and Retrofit Proposals

Following the (magnitude 6.8 on February 28), the (WSDOT) conducted immediate structural assessments of the Alaskan Way Viaduct, identifying cracking in transverse floorbeams, joints within each bent, and longitudinal edge girders, with the most severe damage at bents 97-100, including spalling and fractured reinforcement in upper east knee joints. employed a 3D nonlinear finite element model using ADINA software to simulate the damage under factored dead and live loads per AASHTO standards, yielding a rating factor of 0.44 for the upper crossbeam at bent 100, indicating insufficient to support traffic. Initial repairs involved , tie-rods, and planned fiber strengthening of affected elements to restore partial functionality. Broader engineering evaluations, including those by WSDOT's Structural Sufficiency Review Committee in June 2001, confirmed the viaduct's high seismic vulnerability, projecting severe damage or collapse under design-level ground motions with a 10% probability of exceedance in 50 years (equivalent to a 475-500-year event). Key risks stemmed from inadequate transverse , short lap splices in column bases, brittle beam-to-column joints, and susceptibility to in loose, saturated soils, potentially causing 0-24 inches of vertical and 3-4 feet of lateral spreading. These assessments built on pre-2001 studies but were intensified post-earthquake, highlighting the structure's non-ductile design from its 1949-1953 era, predating modern seismic codes. Retrofit proposals evaluated by WSDOT included full seismic upgrades to meet contemporary standards, encompassing strengthening via grouting or micropile extensions, footing overlays, and enhancements to columns and joints, with an estimated of $720 million in dollars. Localized measures, such as improvements at vulnerable piers, were projected at $69 million, while immediate post-quake fixes focused on shear reinforcement and joint repairs. Alternative concepts under the Elevated Structure option proposed retrofitting segments between and Streets with reduced excavation (15,000 cubic yards), alongside seismic upgrades to the adjacent Street Tunnel including fire suppression and egress additions. WSDOT's June 2001 review concluded that retrofits, even comprehensive ones, were not feasible long-term due to the viaduct's age (over 50 years with a 75-year life), the risk of piecemeal interventions disrupting overall structural behavior, and comparative costs ($720 million for retrofit versus $870 million for full replacement) that did not justify the lower reliability against future events. Ongoing hazards and inability to achieve code-compliant performance without excessive disruption further favored replacement, as retrofits could only mitigate but not eliminate collapse risks in a Seattle Fault Zone event. These findings shifted focus to permanent alternatives by late 2001, prioritizing structures designed for higher seismic resilience.

Alternative Replacement Options

The primary alternatives to the bored tunnel replacement for State Route 99 (SR 99) along Seattle's waterfront included an elevated structure rebuild, a cut-and-cover , and surface/ enhancements. The elevated structure option proposed replacing the existing with a new multi-level aerial , featuring a stacked design in sections to maintain similar while improving seismic through modern standards like ductile frames and base isolators. This approach was estimated to cost around $2.8 billion and was favored by some for its shorter construction timeline—potentially 4-5 years versus over a for tunneling—and minimal disruption to existing utilities, though critics argued it would perpetuate waterfront barriers to pedestrian access and urban development. The cut-and-cover tunnel alternative involved excavating an open trench along the alignment, constructing a tunnel, and backfilling, which would have allowed for simultaneous seawall replacement but required extensive temporary traffic detours and business relocations. Evaluated in the 2006 Supplemental Draft , this option was projected at $3.2-3.5 billion with a 6-8 year build period, offering better integration with surface-level improvements but facing opposition due to higher costs, geotechnical risks from in the SoDo area, and environmental impacts from excavation near contaminated sites. Both the elevated and cut-and-cover options were rejected by voters in a 2007 referendum, with 60% opposing the elevated rebuild, citing preferences for options that enhanced waterfront connectivity over vehicular throughput. Surface and transit-focused alternatives emphasized reducing reliance on SR 99 by improving parallel arterials like (I-5), expanding , and developing a multi-modal with bike lanes and enhanced public capacity, potentially handling 20-30% of viaduct volumes through mode shifts. Proponents, including urban planners, highlighted long-term benefits such as lower emissions and economic revitalization via waterfront parks, with costs under $1 billion when paired with transit investments, though engineering assessments indicated potential congestion spikes during peak hours without sufficient capacity upgrades. These options were screened out early in the environmental review for failing to meet federal mobility standards under the , as modeled traffic simulations showed unacceptable level-of-service declines. Despite this, hybrid surface-tunnel concepts persisted in debates, influencing the final project's inclusion of surface street enhancements north and south of the tunnel.

Political and Economic Controversies

The replacement of the Alaskan Way Viaduct ignited prolonged political disputes in , primarily over whether to prioritize highway capacity via a or rebuild, or to pursue a lower-cost surface emphasizing transit and urban connectivity. After the exposed the structure's vulnerabilities, initial evaluations in 2004 favored a shallow , but by 2009, the selected a deep-bore option following the rejection of a 2007 regional measure for a surface-transit alternative funded by a increase. Proponents, including Chris Gregoire and business coalitions, argued the would preserve freight mobility and north-south traffic flows critical to the regional economy, while opponents highlighted engineering uncertainties and missed opportunities for waterfront revitalization. Seattle Mayor Mike McGinn emerged as a leading critic, pushing for a surface option and framing the as fiscally reckless; his efforts culminated in on , 2011, which asked voters whether the City Council should approve technical agreements with the state for the project. Nearly 60% of voters approved the measure, rejecting McGinn's position and clearing a key hurdle despite support from activists concerned about cost and seismic risks in a bored . backers, backed by eight of nine council members and labor groups, portrayed the opposition as delaying essential , potentially prolonging reliance on the seismically deficient . The vote underscored divisions between state-level priorities for throughput and city-level visions for pedestrian-oriented . Economic controversies centered on cost comparisons and execution risks, with rebuild estimates ranging from $2.7 billion to $3.1 billion over eight years, versus the tunnel's initial $3.3 billion projection. Critics, including public interest groups, warned of overruns, noting the Washington State Department of Transportation's pre-construction assessment of a 40% probability of exceeding budgets by up to $415 million. These fears materialized when the tunnel boring machine Bertha encountered steel pipe obstructions and halted in December 2013, causing a two-year standstill that added $223 million in overruns and deferred completion from 2015 to 2019. Change orders further inflated expenses by nearly $58 million, fueling debates on whether the project's scale justified diverting funds from broader maintenance needs amid Washington's transportation funding shortfalls. The final program cost totaled $3.35 billion, sourced from state gas taxes, federal grants, and tolls, but detractors labeled it a given risks and the absence of robust transit integration, arguing that elevated rebuilds or surfaces could have delivered comparable safety at lower expense without geological hazards. Proponents countered that the tunnel's mitigated collapse risks more definitively than retrofits, enabling economic continuity for port-dependent industries handling $200 billion in annual .

Replacement Implementation

Tunnel Project Initiation and Planning

Following the 2001 Nisqually earthquake, which exposed the Alaskan Way Viaduct's seismic vulnerabilities, Washington State officials evaluated replacement options for the aging elevated structure along State Route 99 in Seattle. By 2009, after considering alternatives such as elevated roadways, surface streets, and transit-oriented designs, the deep-bored tunnel emerged as the preferred solution due to its potential to maintain traffic flow during construction by keeping the viaduct operational and minimizing surface disruption in the dense urban waterfront area. In April 2009, the passed Engrossed Substitute Senate Bill 5768 (ESSB 5768), mandating replacement of the viaduct with a deep-bore featuring four general-purpose lanes in a stacked configuration to preserve capacity for approximately 100,000 daily vehicles. The legislation, signed by Governor , directed the (WSDOT) to expedite environmental reviews and design processes, allocating initial funding from state transportation accounts and emphasizing seismic resilience standards capable of withstanding a magnitude 9.0 earthquake. This decision resolved prior debates, including a 2007 regional favoring surface options, by prioritizing feasibility and economic continuity over costlier retrofits estimated at over $3 billion. Planning advanced through a collaborative framework involving WSDOT, the City of , King County, and the , culminating in the release of the Final (EIS) in 2011, which analyzed geotechnical risks, ventilation needs, and stormwater management for the 1.7-mile, double-decked tunnel. The U.S. issued a Record of Decision in August 2011, approving the bored tunnel alternative after public scoping and mitigation plans for noise, vibration, and habitat impacts along . Design-build procurement followed, with contracts awarded in 2010 for preliminary and relocations, projecting a total program cost of $3.35 billion funded via tolls, gas taxes, and federal grants. Geotechnical investigations confirmed stable glacial till for tunneling, though later challenges like machine breakdowns were not anticipated in initial phases.

Construction Challenges and Delays

The SR 99 tunnel construction, managed by Seattle Tunnel Partners under contract with the (WSDOT), commenced excavation using the 57.5-foot-diameter on July 30, 2013, after assembly at the south portal near S. Street. The advanced approximately 1,000 feet before overheating on , 2013, near Pier 48, due to damage from encountering an 8-inch-diameter, 119-foot-long steel pipe installed by WSDOT for groundwater monitoring in 2007. This incident compromised Bertha's seals, cutterhead, and main bearing, halting operations and necessitating extensive repairs. Repair efforts involved excavating a 120-foot-deep access pit to reach the , followed by disassembly of the cutterhead for surface repairs, of and gears, and with plating, at a of approximately $143 million. The stoppage lasted over two years, from December 2013 to January 2016, during which additional complications arose, including a in December 2015 and ongoing disputes over liability between WSDOT and the contractor, who attributed the damage to the pipe's placement rather than design flaws. resumed tunneling in early 2016 but encountered further issues, such as off-alignment in March 2017, before completing the 1.7-mile bore on April 4, 2017. Post-boring phases included tunnel lining installation, and system outfitting, and connections, extending delays amid legal battles; insurers denied coverage for $44 million in delay damages, citing the breakdown as non-physical under policy terms, while a ordered Tunnel Partners to pay WSDOT $57.2 million for inefficiencies. The project, originally slated for completion in late , opened to traffic on February 4, 2019, resulting in a three-year delay from the revised 2016 target. Total costs escalated from an initial $2.8 billion estimate to $3.374 billion, driven primarily by the Bertha repairs and associated overruns.

SR 99 Tunnel Completion and Opening

The SR 99 tunnel's excavation phase ended on , 2017, when the tunnel boring machine Bertha's cutterhead broke through the north portal after tunneling 9,270 feet (2.82 km) beneath . Following this, contractors extracted the machine, installed lining segments to reinforce the bore, and fitted out the interior with roadway pavement, drainage systems, fire suppression, , lighting, and electronic traffic management infrastructure. Seattle Tunnel Partners, the lead contractor consortium, announced substantial completion of the tunnel in October 2018, marking the handover to the (WSDOT) for final testing, systems integration, and surface connections. This milestone followed years of delays from Bertha's mechanical failure in 2013 and subsequent repairs, enabling WSDOT to prepare for transition from the viaduct. The tunnel opened to bidirectional traffic at 12:17 a.m. on , 2019, coinciding with the completion of viaduct replacement objectives after its permanent closure on January 11, 2019. A weekend public event on February 2–3 allowed pedestrian access for viewing the 1.75-mile (2.82 km), single-bore, double-deck structure ahead of regular use, with initial weekday volumes averaging over 70,000 trips within the first month. The opening integrated new ramps at South Dearborn and South Jackson streets for southbound access and Seneca Street for northbound entry, maintaining SR 99's north–south corridor capacity at two lanes per direction.

Viaduct Demolition Process

The demolition of the Alaskan Way Viaduct was awarded to Kiewit Infrastructure West Co. on June 23, 2016, under a $93.7 million contract as part of the SR 99 Demolition, Decommissioning, and Surface Street Project. This work followed the permanent closure of the viaduct to traffic and the opening of the replacement SR 99 tunnel on February 2, 2019, with demolition commencing on February 12, 2019, after a brief delay due to winter weather. The scope included removing approximately 1.4 miles of the double-deck viaduct structure from the vicinity of South Dearborn Street northward to the Battery Street Tunnel south portal, along with the Columbia Street on-ramp, Seneca Street off-ramp, and 210 feet of steel girder structures over tracks. Demolition proceeded methodically from south to north, starting at the Columbia Street on-ramp and extending beyond Pike Street, utilizing cranes fitted with hydraulic steel jaws to cut and crush sections, heavy equipment for dismantling, and trucks for debris removal. was pulverized on-site or at Terminal 25 for reuse, including as fill material for the concurrent decommissioning of the Battery Street Tunnel, which was sealed on February 1, 2019, and filled with over 3,140 feet of crushed viaduct rubble to prevent future use and support adjacent development. The process also encompassed demolishing viaduct columns and footings to 5 feet below grade, regrading Aurora Avenue from Harrison Street to Denny Way, and establishing new surface street connections at John and Thomas Streets to integrate with the waterfront reconfiguration. Key milestones marked steady progress: the central waterfront section was cleared by June 2019, 90 percent of the structure demolished by September 4, 2019, the final horizontal deck segment at Marion Street removed on September 23, 2019, following the opening of a temporary pedestrian bridge, and the last support columns at the northern end near BNSF tracks taken down on November 21, 2019, signifying full completion of the viaduct removal. Throughout, operations minimized disruptions to adjacent port activities and urban traffic, with crushed materials recycled where feasible to reduce landfill use. The effort cleared the waterfront corridor for seismic retrofits, new surface roadways, and public spaces under the broader .

Post-Replacement Outcomes

Traffic Flow and Capacity Comparisons

The Alaskan Way Viaduct carried an average of approximately 110,000 vehicles per day at its peak near Yesler Way in 2011, serving as a key north-south corridor parallel to Interstate 5. Prior to its full closure in January 2019, daily volumes had stabilized around 90,000 to 100,000 vehicles, with frequent during peak hours due to its two-lane configuration per direction and aging infrastructure limiting effective throughput. Partial closures in preceding years demonstrated elasticity, as volumes on the viaduct dropped by up to 40 percent without proportional increases elsewhere, indicating suppressed demand from induced patterns rather than inelastic necessity. Following the SR 99 tunnel's opening in February 2019, initial weekday volumes averaged about 75,000 vehicles, approaching but not exceeding pre-closure viaduct levels, with peak-hour flows reaching around 5,300 vehicles per hour in early operation—below the anticipated 7,000 vehicles per hour. The tunnel, also featuring two lanes per direction in a configuration, maintained similar theoretical to the viaduct (approximately 4,000–5,000 vehicles per hour per direction under free-flow conditions), but its design incorporated gentler curves and modern ventilation, potentially allowing higher sustained speeds at equivalent volumes. However, tolling implemented in November 2019 reduced average weekday volumes by 26 percent, resulting in screenline totals across SR 99 about 31 percent below viaduct-era baselines. By 2023, tunnel volumes had stabilized at around 40,000 tolled trips per day, with slight increases to approximately 47,000 daily users noted in maintenance reports by mid-2025, reflecting partial recovery amid post-pandemic shifts but remaining well below viaduct peaks and original projections of 53,000 daily trips. This reduction in throughput—coupled with observed declines in regional screenline volumes during viaduct closure periods—suggests a reversal of , where lower capacity constraints encouraged mode shifts to , carpooling, or alternative routes like I-5, rather than overwhelming parallel infrastructure. Peak-period flows in the tunnel post-tolling averaged lower than viaduct equivalents, contributing to reduced but also underutilized capacity, as northbound volumes north of halved relative to baselines during transition phases before stabilizing at subdued levels.
MetricViaduct (Pre-2019 Baseline)SR 99 (Post-Tolling Average)Notes
Average Daily Traffic~90,000–110,000 vehicles~40,000–47,000 vehiclesTunnel figures reflect 2023–2025 data; viaduct from 2011–2018 peaks.
Peak-Hour Flow (Weekday)~6,000–7,000 vehicles/hour~5,300 vehicles/hour (early); lower post-tollsBoth limited to 2 lanes/direction; tunnel peaks declined further after 2019.
Frequently congestedUnderutilized (31% below baseline screenlines)Empirical drop tied to tolls and demand elasticity, not geometric constraints.

Economic and Urban Impacts

The replacement of the Alaskan Way Viaduct with the SR 99 tunnel facilitated the removal of the aging structure, enabling the redevelopment of approximately nine acres of previously shadowed land into public open spaces, including parks, promenades, and enhanced pedestrian pathways that reconnect 's downtown core to . This transformation, part of the Waterfront Seattle initiative launched in coordination with viaduct completed in , has prioritized , installations, and improved viewsheds, fostering greater urban accessibility and recreational use along a 1.8-mile stretch previously dominated by the elevated roadway. Urban planners have noted that the absence of the viaduct barrier has stimulated private investment in adjacent mixed-use developments, with the central now featuring expanded plazas and transit-oriented amenities that integrate with existing landmarks like the . Economically, the viaduct replacement program incurred total costs of $3.35 billion, funded through a mix of state gas tax revenues, federal grants, and local contributions, with over $2 billion directed to the tunnel boring and associated surface improvements. Post-opening in February 2019, the tunnel has carried average daily volumes of around 70,000 vehicles—substantially below the viaduct's pre-closure peak of 110,000—exacerbated by persistent work-from-home trends and urban traffic shifts, leading to toll revenue shortfalls that prompted legislative bailouts and projected toll hikes to cover maintenance and repay $200 million in borrowed funds. These lower-than-forecast volumes, which generated only about 15% less revenue than biennial projections in some periods despite traffic upticks, have strained state budgets without evidence of proportional economic drag on regional freight, as studies indicate negligible impacts on Puget Sound goods movement reliant on SR 99. The redevelopment has indirectly supported economic activity through tourism and property value enhancements, with the revitalized attracting increased visitor foot traffic and enabling commercial leasing along Alaskan Way, though quantifiable boosts remain tied to broader growth rather than the project alone. Critics of the tunnel's financial model argue that its two-lane configuration per direction limits surge capacity compared to the viaduct's design, potentially constraining peak-hour commerce during events or disruptions, yet official evaluations post-2019 show no systemic decline in port throughput or business vitality attributable to the replacement. Overall, while the project has delivered long-term amenities at high upfront cost, its economic returns hinge on sustained toll collection amid evolving commuting patterns.

Criticisms of Replacement Choices

The decision to replace the Alaskan Way Viaduct with a deep-bore for State Route 99 faced criticism for prioritizing a high-capacity, car-centric solution amid declining regional traffic volumes that undermined projections of future demand. data indicated a 13% drop in vehicle-miles traveled from 2000 to 2008, while records showed a 6.25% decline in daily viaduct usage over the same period, even as population grew; critics contended this trend obviated the need for replicated , favoring instead investments in surface streets and that could accommodate shifts. Opponents, including urban planners and environmental groups like the People's Waterfront Coalition, argued the tunnel squandered opportunities for waterfront reclamation and enhancements, as an elevated replacement or viaduct removal paired with local improvements would have been cheaper and faster to construct while minimizing economic disruption from prolonged closures. The tunnel option, initially dismissed by Governor in 2007 for its safety risks and costs exceeding $1 billion more than alternatives, locked in fiscal inefficiencies, generating fewer jobs per dollar—approximately 480 versus over 6,000 from equivalent transit funding—without enhancing property values or urban connectivity as surface options could. Engineering and safety critiques highlighted the tunnel's vulnerabilities, such as limited for trucks carrying hazardous materials and evacuation difficulties over its 2-mile length in seismic events or fires, contrasting with the more straightforward seismic or rebuilding of an elevated structure. These concerns materialized during construction, when the boring machine stalled for two years after striking a steel pipe in 2013, incurring at least $223 million in overruns and pushing completion from 2015 to 2024, validating pre-decision doubts about technical feasibility raised by groups advocating for proven elevated designs. Post-opening assessments reinforced choice-related miscalculations, with toll revenues falling short of forecasts due to lower usage after initial novelty and effects, straining state budgets despite infusions and necessitating toll hikes as late as 2026 considerations. Ongoing , including $1.5 million for 2025 traction resurfacing and biennial closures for inspections, has amplified lifecycle expenses, outcomes critics attribute to forgoing adaptive, lower-cost alternatives that better aligned with observed traffic stabilization at around 47,000 daily vehicles.

Technical Details

Exit List

The Alaskan Way Viaduct, an elevated segment of State Route 99 (SR 99), included limited interchanges serving and adjacent neighborhoods. These provided northbound and southbound access primarily via on- and off-ramps at key waterfront and urban points, with northbound traffic featuring additional right-turn slip lanes to Republican Street and Roy Street from the structure. The viaduct's design emphasized through-traffic bypass, resulting in fewer exits compared to surface arterials. The following table enumerates the primary interchanges along the viaduct section, ordered from south to north by approximate milepost, with details on typical access configurations prior to demolition in 2019.
MilepostInterchangeDestinations and Access Notes
31Alaskan Way Viaduct rampsConnections to southern approaches including Way and area; southbound on-ramp and northbound off-ramp availability.
32Western Avenue / Elliott AvenueAccess to Belltown and ; northbound off-ramp and southbound on-/off-ramps.
32ADenny WayEntry to ; on- and off-ramps for both directions.
~33 / Streets (slip ramps)Northbound-only right-turn exits to South Lake Union and areas.
North of these, traffic continued to the Battery Street Tunnel without additional viaduct exits. Southbound ramps to Pioneer Square via Alaskan Way surface streets supplemented the elevated structure.

Daily Traffic and Capacity Data

The Alaskan Way Viaduct, a segment of Route 99 in , , carried an average of 110,000 vehicles per day on its mainline and ramps in , reflecting existing conditions prior to replacement planning. Traffic volumes varied by location along the structure: 105,400 vehicles per day at S. Spokane Street, 26,400 vehicles per day south of S. King Street, and 95,600 vehicles per day north of the Battery Street Tunnel. Earlier assessments reported lower averages, such as approximately 100,000 vehicles per day in 2001 and 86,000 vehicles per day in a pre-2001 seismic study, indicating growth in usage over time before stabilization and decline due to emerging alternatives like improvements and telecommuting trends. By 2011, volumes reached 110,000 vehicles per day at the Yesler Way location, underscoring its role as a critical north-south corridor handling about 20-25% of Seattle's inbound regional traffic.
LocationAverage Daily Traffic (Vehicles per Day)YearSource
Mainline + Ramps110,0002015WSDOT FEIS Appendix C
S. Spokane Street105,4002015WSDOT FEIS Appendix C
North of Battery Street Tunnel95,6002015WSDOT FEIS Appendix C
Yesler Way110,0002011FHWA
Overall Average~100,0002001WSDOT Bridge Report
The viaduct's was limited by its configuration—primarily two in each direction through sections, with some widening to three south of the stadium district—resulting in level of service () ratings of D to E during peak hours in 2015, indicating unstable flow and frequent . Peak-hour demands approached 10,000 per hour northbound in the morning and 9,000 southbound in the evening, often exceeding practical throughput due to merges, diverges, and seismic retrofits that reduced shoulder space. Approximately 3,720 trucks per day utilized the structure in baseline conditions, comprising a notable freight component that amplified strains given longer lengths and slower . These constraints contributed to average speeds dropping below 40 during peaks, with no explicit design in vehicles per day documented beyond operational LOS thresholds, as the structure prioritized post-1953 recovery over modern freeway standards. By in 2019, daily volumes had declined to around 90,000 vehicles, reflecting shifts and surface adaptations rather than inherent .

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