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STS-4

STS-4 was the fourth mission of NASA's Space Shuttle program and the final orbital flight test of the Columbia orbiter, launched on June 27, 1982, from Kennedy Space Center's Pad 39A to validate the vehicle's operational readiness before transitioning to full mission capabilities. The two-person crew consisted of Commander Thomas K. Mattingly II, a veteran astronaut on his second spaceflight, and Pilot Henry W. Hartsfield Jr., on his debut mission, who together conducted a series of engineering evaluations and scientific experiments over the 7-day, 1-hour, 9-minute, and 31-second flight that spanned 113 orbits at an altitude of approximately 197 nautical miles and an inclination of 28.5 degrees. The primary objectives focused on assessing the shuttle's thermal protection system, contamination environment, and remote manipulator system (RMS) performance, marking the first deployment of a Department of Defense-sponsored payload, the Cryogenic Infrared Radiance Instrumentation for Shuttle (CIRRIS), although it ultimately failed to activate due to a lens cap that did not open. Other notable payloads included the Continuous Flow Electrophoresis System (CFES) for biological material separation, which operated successfully; the Induced Environment Contamination Monitor (IECM), the heaviest object (850 pounds) manipulated by the RMS during the mission; the Monodisperse Latex Reactor (MLR) for microgravity materials science; and several Get Away Specials (GAS) canisters under the Shuttle Student Involvement Program (SSIP), enabling student-designed experiments in areas like crystal growth and plant biology. Significant events included the first in-flight demonstration of the () spacesuit, tested for future spacewalks, and the achievement of the highest to date for the program at 202 by 183 miles, while minor anomalies such as warped payload bay doors from pre-launch cold exposure and tile damage from rainwater were addressed without impacting overall success. The concluded with a historic on , 1982, at 9:09:31 a.m. PDT on the concrete Runway 22 at , —the first such concrete runway touchdown for the —covering a total distance of 2.9 million miles, where the crew was personally greeted by President in a attended by over 45,000 spectators, symbolizing a patriotic milestone as the first American Independence Day observed from space. Post- revealed damage to the solid rocket boosters from deployment failures during , but the flight's accomplishments paved the way for operational missions starting with later that year.

Crew

Primary crew

The primary crew for STS-4 consisted of two tasked with commanding and piloting during its final orbital flight test. Commander Thomas K. Mattingly II and Pilot Henry W. Hartsfield Jr. were selected to oversee the mission's vehicle operations, payload deployments, and overall certification objectives for the . Thomas Kenneth Mattingly II, aged 46 at the time of launch, served as the mission commander. A U.S. Navy captain and veteran , Mattingly was responsible for overall mission command, including decision-making during ascent, orbital maneuvers, and reentry, as well as coordinating vehicle systems performance to validate the shuttle's operational readiness. This marked his second , following his role as command module pilot on in 1972, where he logged over 265 hours in space while supporting the lunar landing and conducting scientific observations from . Selected from NASA's Group 5 astronaut class in 1966, Mattingly's extensive experience in and development, including contributions to the Apollo command module design, made him a key figure in transitioning from Apollo-era missions to the reusable shuttle program. Henry Warren Hartsfield Jr., aged 48 during the mission, acted as the pilot. As a U.S. Air Force , Hartsfield handled primary piloting duties, such as controlling the orbiter during launch ascent, any required rendezvous operations, and the precision landing phase, while also assisting with systems monitoring and handling. This was his first , drawing on his background as a distinguished with over 7,500 hours of experience, including evaluations of advanced like the F-104 and F-111. A member of NASA's Group 5 astronaut class since 1966, Hartsfield had previously supported Apollo and missions in mission control and engineering roles before assignment to the shuttle program. The STS-4 crew was announced by on March 16, 1978, as part of the initial assignments for the first four orbital flight tests, with and Hartsfield chosen for their proven expertise to ensure the shuttle's full certification after three prior test flights. This selection emphasized operational reliability and risk mitigation, aligning with 's goal to demonstrate the vehicle's maturity for future operational missions.

Backup crew

For the STS-4 mission, discontinued the practice of assigning a complete flight , which had been standard for the earlier orbital flights of the . This shift, effective starting with STS-4, allowed the agency to draw from a broader pool of trained astronauts for any necessary individual substitutions, reflecting increased confidence in the program's operational readiness and the depth of experience within the astronaut office. The decision streamlined training resources and emphasized continuity through overlapping expertise from prior missions, as the primary crew—Commander Thomas K. Mattingly II and Pilot Henry W. Hartsfield Jr.—had themselves served as the full backup team for just months earlier. Their prior role ensured thorough knowledge of shuttle systems, ascent profiles, and contingency procedures, which informed the rationale for relying on such shared operational familiarity rather than dedicated alternates. Support functions critical to mission success, including simulation oversight and capsule communicator (CAPCOM) duties, were handled by other seasoned astronauts such as S. David Griggs, who served as ascent CAPCOM, and , who managed entry communications from Mission Control. These ground-based roles provided real-time guidance and rehearsal support, compensating for the absence of a formal backup while maintaining high standards of safety and preparedness.

Crew assignments

The STS-4 crew assignments positioned Commander Thomas K. Mattingly in seat 1, the left forward location, and Pilot Henry W. Hartsfield in seat 2, the right forward location. These seats were fixed throughout the mission, enabling the two-person team to manage ascent, orbital operations, and entry without additional mission specialists, as STS-4 marked the final developmental flight limited to a minimal crew configuration. Support roles were handled by a team coordinated from NASA's , incorporating biomedical monitoring specialists who tracked crew physiological data via telemetry and a photo documentation team responsible for capturing pre-launch and in-flight imagery using 35mm and 70mm cameras equipped for timestamping. Pre-flight preparations adhered to standard protocols for test flights, featuring a Health Stabilization Program that enforced semi-isolation during the final week to reduce risks and a controlled training pace. Suit-up occurred approximately three hours before launch in the crew quarters at Kennedy Space Center's Launch Complex 39, involving donning of launch and entry suits with assistance from Astronaut Support Personnel. Following tile damage concerns from due to pre-launch rain exposure, training emphasized procedures for inspecting and mitigating thermal protection system vulnerabilities, including water absorption and drying techniques applied after a incident prior to STS-4's rollout.

Mission parameters

Vehicle and orbit

The Space Shuttle Columbia (OV-102) conducted its fourth flight on STS-4 as the final dedicated orbital flight test, emphasizing verification of vehicle systems for operational transitions. The orbiter was outfitted with a that incorporated pre-launch repairs to address and rain-induced damage to its tiles; specifically, the right wing received a to restore integrity and prevent moisture-related degradation. On-orbit maneuvers maintained a bottom-to-sun orientation to facilitate drying of any residual wet tiles, ensuring TPS performance during reentry. The launch stack utilized the fourth pair of Solid Rocket Boosters (SRBs), alongside External Tank ET-4 as the propellant reservoir. These components provided the initial ascent thrust, with the SRBs delivering approximately 5.6 million pounds of force combined at liftoff. The three Space Shuttle Main Engines (SSMEs), labeled SSME-1, SSME-2, and SSME-3, were integrated into the orbiter's aft section; engines No. 1 and No. 2 underwent modifications to their high-pressure fuel turbopumps prior to the mission to enhance reliability and performance margins. Following insertion, STS-4 established an initial at approximately 160 nautical miles (296 kilometers) altitude and 28.5-degree inclination, optimized for test objectives including structural loads and environments. The mission profile encompassed 113 orbits, accumulating a total distance of 2.9 million statute miles before deorbit.

Launch and landing details

The Space Shuttle Columbia launched from Pad 39A at NASA's Kennedy Space Center in Florida at precisely 11:00 a.m. EDT on June 27, 1982, achieving the program's first exact on-time liftoff with no delays. The launch occurred under clear skies with favorable atmospheric conditions, including an ambient temperature of approximately 24°C and northeast winds. Columbia landed on Runway 22 at Edwards Air Force Base in California at 9:09:31 a.m. PDT on July 4, 1982, marking the first Space Shuttle touchdown on a concrete runway after a rollout distance of 9,878 feet in 73 seconds. The landing took place amid clear skies and optimal synoptic patterns that supported ideal glide slope visibility and wind conditions. Post-landing, the orbiter underwent initial recovery procedures at Edwards before being mated to NASA's modified Boeing 747 Shuttle Carrier Aircraft for ferry flight back to Kennedy Space Center, a standard process for missions concluding at the California site to enable refurbishment and reuse preparation. The overall mission spanned 7 days, 1 hour, 9 minutes, and 31 seconds from liftoff to wheels stop.

Mission timeline

Launch sequence

The countdown for STS-4 began approximately 90 hours prior to launch to accommodate the loading of super-cold helium for the Department of Defense payload. The orbiter had been rolled out to Launch Complex 39A nominally several weeks earlier, with pre-launch holds resolved through routine weather and systems checks. At approximately T-2 hours, the crew of Commander Thomas K. Mattingly II and Pilot Henry W. Hartsfield Jr. ingressed the vehicle, donning pressure suits and undergoing final health checks. Cryogenic fueling of the external tank with and commenced at T-3 hours, proceeding without incident as ground teams monitored tank pressures and vent systems. The terminal countdown included built-in holds at T-20 minutes for weather verification and at T-9 minutes for range safety confirmation, both resolved nominally. The three Space Shuttle Main Engines started up at T-6.6 seconds, followed by solid rocket booster ignition at T-0; liftoff occurred precisely at 15:00:00 UTC on June 27, 1982, from Kennedy Space Center's Pad 39A. Ascent proceeded through the standard phases, with the solid rocket boosters providing initial thrust augmentation until their separation at T+2:05, marked by a brief flash from the separation motors visible to the crew. The main engines continued firing, passing maximum around T+1:10, as the stack accelerated toward orbital velocity. External tank separation occurred at T+8:35, jettisoning the empty tank via forward and aft attachment , with the crew confirming a clean separation via onboard cameras. Main engine cutoff followed immediately at approximately T+8:37. Following separation from the tank, the crew initiated post-launch checks, including verification of thermal protection system integrity and systems stability. Two initial burns were performed on the first orbit to achieve orbital insertion and circularize the orbit at approximately 150 nautical miles. Subsequent checks confirmed successful opening of the payload bay doors at around T+2:00, essential for thermal control and payload deployment, with no anomalies reported in door mechanisms or radiator deployment.

Orbital operations

Following orbital insertion, the STS-4 crew performed two (OMS) burns on the first day to circularize the orbit at approximately 150 nautical miles altitude, verifying the vehicle's propulsion and attitude control systems in the sustained orbital phase. The payload bay doors were opened shortly thereafter to initiate thermal control operations, allowing and preventing overheating of internal systems during the seven-day mission. Systems verification dominated early orbital activities, with extensive testing of the (RCS) thrusters to assess performance and plume visibility, noting that forward thrusters induced noticeable vehicle vibrations while aft ones were smoother. Thermal control evaluations included maintaining various attitudes, such as tail-to-Sun for cooling and belly-to-Sun orientations to dry moisture-absorbed thermal protection tiles exposed during pre-launch rain; this tile-drying maneuver on flight day 4 raised the orbit to 185 nautical miles via additional OMS firings. The Remote Manipulator System (RMS) was activated on day 2 to deploy and maneuver the Induced Environment Contamination Monitor (IECM) pallet for sampling, demonstrating the arm's precision grappling and rate-holding capabilities with minimal flexure against orbiter structures. Crew activities focused on and biomedical monitoring to support vehicle operations and human factors assessment. Navigation sightings used the Crew Optical Alignment Sight (COAS) for calibration and star tracking, though vehicle torqueing occasionally affected accuracy, with readings providing repeatable data for . Biomedical efforts included treadmill exercises starting on day 3 for the pilot and day 4 for the , each session lasting about one hour to maintain physical , alongside an end-of-mission test to low-level accelerations using the (EMU) suit in the . Subsequent days featured orbit adjustments, including an OMS burn on day 5 to reach 195 by 186 nautical miles and RCS maneuvers on days 6 and 7 to fine-tune to 202 by 183 nautical miles, while payload bay doors underwent functional testing for deployment and latching. On July 4, Independence Day, the crew executed a special over , , aligning with ground celebrations and providing visual confirmation of landing site preparations below. Scientific payloads were activated briefly during these operations to gather preliminary data on the orbital environment.

Reentry and landing

The deorbit burn for STS-4 was initiated at 15:10 UTC on July 4, 1982, using the two (OMS) engines while was in a 202 by 183 , with the maneuver targeted to set up at in . The burn lasted approximately 172.5 seconds, achieving a velocity change of 309 feet per second and lowering the perigee to enable atmospheric reentry. Atmospheric entry began at the interface (400,000 feet altitude) at 15:40 UTC, with peak heating occurring near 24.9 as the orbiter executed programmed bank maneuvers to manage descent trajectory and heat loads. The experienced vertical load factors up to 1.8 during the high-speed phase, while stability and attitude control were maintained through manual speedbrake deployment (typically at 55 degrees) and body flap adjustments. Minor vibrations were noted around 22, attributed to possible structural modes excited by firings. Columbia touched down on runway 22 at at 16:09:40 UTC, 948 feet past the threshold and 14 feet left of centerline, marking the first shuttle landing on a runway. The rollout covered 9,878 feet in 73 seconds, with nosewheel deployment occurring immediately after main gear contact at approximately 200 knots . Post-landing safing included repositioning vent doors to the purge configuration 34 minutes after touchdown, followed by initiation of the purge to remove residual fuels from the OMS and reaction control systems.

Objectives and payloads

Test objectives

STS-4 served as the final orbital flight test in the program's development phase, with primary objectives centered on validating the vehicle's operational readiness for routine s. The aimed to demonstrate the Space Transportation System's capability for an extended duration of approximately seven days, confirming the orbiter's endurance in space and its integration with the solid rocket boosters and external tank. Key engineering goals included assessing the thermal protection system's performance under prolonged orbital exposure and atmospheric reentry, particularly after pre-launch exposure to adverse weather that affected tile integrity. Additionally, the flight evaluated the shuttle's reusability by inspecting post-mission conditions to ensure efficient turnaround for subsequent launches. Specific tests focused on critical aspects to certify the for full operational use. Aerodynamic was verified through entry evaluations, including control surface responses at high numbers and buffet conditions during descent. integration was tested via backup flight software displays, abort scenario simulations, and onboard computing performance to ensure reliable and . Crew-vehicle interfaces underwent assessments for , including workstation in microgravity, waste system functionality, and communication protocols to optimize human operations for future missions. The remote manipulator system was exercised to deploy and berth the Induced Environment Contamination Monitor, validating arm and software for handling. Following a successful on July 4, 1982, certified the as an operational vehicle, marking the transition from test flights to routine operations. This certification enabled the integration of Department of Defense payloads, including a brief overlap with classified objectives on STS-4, and paved the way for commercial satellite deployments. The mission's outcomes confirmed the shuttle's reliability for sustained .

Scientific payloads

The scientific payloads on STS-4 encompassed a series of non-military experiments designed to leverage microgravity for materials science, biological research, and fluid dynamics studies. These payloads marked early efforts in commercial and student-led space research, providing data on processes unattainable or limited on Earth. A primary payload was the Getaway Special (GAS) G-001, consisting of nine self-contained canisters mounted in the shuttle's payload bay, sponsored by Utah State University students. These experiments investigated microgravity effects on crystal growth, including the curing of epoxy resin-graphite composites to assess structural integrity without gravitational settling; fluid dynamics, such as surface tension and thermal conductivity in a water-oil mixture to model low-gravity fluid behavior; and space environment impacts on biological and material systems, encompassing successive generations of fruit flies and brine shrimp for genetic changes, duckweed root growth, algae proliferation rates, soldering processes, and homogeneous alloy formation. The GAS program enabled affordable access for educational projects, with G-001 representing the inaugural such payload worldwide. The Continuous Flow Electrophoresis System (CFES), developed by McDonnell Douglas Astronautics Company, operated in the shuttle's mid-deck to perform biological separations aimed at pharmaceutical production. This first commercial experiment processed high-concentration samples like and proprietary media in a continuous aqueous film, exploiting microgravity to minimize and enhance separation resolution. It ran for approximately 96 hours during the mission, yielding over 400 times the throughput of ground-based systems without resolution loss, thus validating space-based for purifying proteins and cells. The Mono-disperse Latex Reactor (MLR), flying for its second mission, focused on materials processing to produce uniform microspheres in microgravity. This experiment polymerized seeded systems to generate large-particle-size (up to 20 microns) monodisperse latexes, which are used in standards, diagnostics, and coatings. However, on STS-4, the experiment suffered an electrical failure, producing no usable latex batches. Successful production of monodisperse latex products occurred on subsequent missions, such as STS-6. Additionally, under the Shuttle Student Involvement Program (SSIP), the crew performed two medical experiments on themselves to study physiological responses in microgravity.

Military payload

The STS-4 mission carried the first Department of Defense (DoD)-sponsored payload, designated DoD 82-1, which consisted of a classified U.S. Air Force experiment mounted in the shuttle's payload bay. This payload included the Cryogenic Infrared Radiance Instrumentation for Shuttle (CIRRIS), designed to calibrate infrared sensors for detecting missile launches from orbit, as well as supporting tests for space environment effects on reconnaissance systems. Additional components encompassed six experiments covering atmospheric composition, navigational aids, plasma physics, and attitude-determination measurements, all aimed at validating future surveillance satellite technologies like the Teal Ruby program. The primary objectives focused on evaluating the as a viable platform for payloads, with emphasis on collecting data about vibrations, variations, and the orbital environment's impact on sensitive . These tests sought to ensure compatibility between DoD hardware and shuttle systems, including , control, and data interfaces, while simulating operational conditions for missions. The remained deployed in the bay throughout the seven-day flight, monitored from a secure in , without requiring crew intervention or the Remote Manipulator System. The mission achieved partial success with the DoD payload, as five of the six experiments operated nominally and provided valuable environmental data, but CIRRIS encountered a malfunction when its lens cap failed to open, preventing infrared observations and limiting recorded data to approximately four minutes from the payload recorder. Despite this issue, the integration procedures proved effective, confirming the shuttle's readiness for classified DoD missions and paving the way for subsequent flights like . This outcome contributed to the overall of the shuttle for operational use, including defense applications.

Anomalies

Launch and ascent issues

During the ascent of STS-4 on June 27, 1982, the launch sequence was nominal until the separation of the Solid Rocket Boosters (SRBs) from the External Tank at approximately T+126 seconds. Both SRBs' drogue parachutes deployed successfully to orient the boosters tail-first and initiate deceleration, but the main parachute clusters failed to deploy properly. A 7.5 g accelerometer switch, intended to trigger main parachute deployment at a specific deceleration threshold, was prematurely activated by pyrotechnic shock from the frustum separation linear shaped charge. This caused the separation nuts to fire early, releasing the main parachutes before they could extract and inflate, leading to uncontrolled descent and loss of both SRBs upon splashdown in the Atlantic Ocean. The incident marked the only SRB recovery failure during the Space Shuttle program's flight tests prior to the Challenger disaster.

In-flight and reentry problems

During the orbital phase of STS-4, Columbia's protection system tiles that had absorbed rainwater while the orbiter was on the required special attention to prevent potential reentry heating issues. The crew oriented the vehicle belly-down toward for several hours to vaporize the moisture, a procedure that successfully dried the affected tiles without compromising the mission timeline significantly. This orientation, however, constrained other activities by limiting options. Post-flight analysis revealed minor tile losses, including one from the forward and another from the upper body flap, along with degradation of a high-temperature reusable surface (HRSI) tile on the body flap due to exposure to the aft ventral (VRCS) plume. Despite these losses, no structural damage or overheating occurred during reentry, confirming the robustness of the remaining thermal protection system under the mission's entry conditions. The Department of Defense (DOD) payload, designated P82-1 and involving classified sensor technology including the Cryogenic Infrared Radiance Instrumentation for Shuttle (CIRRIS), failed to operate due to activation issues but did not affect vehicle operations. Minor propellant leaks were detected in the (), specifically in forward primary thruster F1L, where oxidizer leakage occurred due to contamination from a particle and iron buildup. The crew promptly deselected the affected thruster, and subsequent checks confirmed the leak had stopped, with no impact on orbital maneuvers, attitude control, or deorbit preparations. Similar minor issues affected R5R (nozzle coating degradation) and primary thruster F3D (water intrusion), but all were managed without mission disruption.

Post-mission assessment

Recovery operations

Following the successful landing of Space Shuttle Columbia at Edwards Air Force Base on July 4, 1982, recovery operations commenced immediately to secure the orbiter and facilitate crew egress. The recovery convoy approached the vehicle to initiate safing procedures, which included shutting down the auxiliary power units, activating cooling systems, and securing the maneuvering systems. Personnel in SCAPE suits connected cooling and purge units to the orbiter to maintain safe conditions. The crew egressed through the hatch within approximately 30 minutes of touchdown, after conducting post-landing checks on the flight deck. Columbia was then towed to the Mate-Demate Device at the Dryden Flight Research Center (now Armstrong Flight Research Center) for further processing, including weighing at the Air Force Weight and Balance Hangar to determine its center of gravity. Preparation for the orbiter's return to began shortly thereafter, with tanks drained, engines purged, and the tail cone installed atop the (SCA), a modified 747. The ferry flight departed Edwards AFB on July 15, 1982, with an overnight stop en route, arriving at the following day. Recovery efforts for the Solid Rocket Boosters (SRBs) proved unsuccessful due to malfunctions in their subsystems. Both SRBs experienced failures after frustum separation, with main failing to deploy properly—likely due to damage during deployment—and risers disconnected as a precaution, resulting in high velocities that caused the boosters to sink. The USNS Vandenberg provided tracking and photographic support, but no salvage was achieved, and the loss precluded ocean floor analysis or of flight data. A Board of Investigation was convened, leading to modifications such as replacing separation nuts with non-explosive structural ones for STS-5.

Mission evaluation and legacy

The STS-4 achieved all major test objectives, including evaluations of the orbiter's thermal protection system, system operations, and payload bay contamination, despite minor anomalies such as suboptimal ascent performance and deployment failures in the Solid Rocket Boosters during their recovery. officials described the flight as one of the cleanest in the program's early , confirming the 's reliability for operational use. On July 4, 1982, following Columbia's landing at , President addressed the crew and a crowd of over 45,000 spectators, declaring the Shuttle system operational and hailing the as a "" in America's space transportation development. This flight also marked the first integration of a Department of Defense-sponsored , the Cryogenic Infrared Radiance Instrumentation for (CIRRIS), which failed to activate due to a issue but represented an important step in military accommodation. Post-flight inspections at NASA's Dryden Flight Research found in remarkably good condition overall, with no significant structural damage. Minor repairs included addressing contamination in one thruster and filter clogging, while data on tile moisture content and drying procedures informed thermal protection enhancements for STS-5. As the culmination of the Space Shuttle's four orbital test flights, STS-4 transitioned the program from development to routine operations, enabling 135 total missions through 2011 and underscoring the viability of despite persistent challenges like thermal tile vulnerabilities. The mission's success validated key engineering principles, such as rapid turnaround and multi-mission adaptability, influencing subsequent shuttle designs and international collaborations.

Mission memorabilia

Insignia

The STS-4 mission insignia is an oval-shaped emblem designed by the flight crew, astronauts Thomas K. Mattingly II and Henry W. Hartsfield Jr. It depicts the ascending into orbit, with its stylized in red, white, and blue stripes to form the numeral "4," evoking the colors of the American flag. This central element symbolizes the mission's designation as the fourth flight and the completion of the program's initial test phase. The patriotic color scheme represents national pride in the Space Transportation System's development, while the "4" underscores the flight's role in validating the shuttle's operational readiness for future missions. The design also alludes to the mission's landing on July 4, 1982—Independence Day—highlighting the shuttle's contribution to U.S. leadership in space exploration. Crew members wore the patch on their flight suits during the seven-day mission, and it appeared in NASA press kits, reports, and commemorative publications. Although STS-4 carried the first Department of Defense payload—a classified subscale test assembly—the insignia includes no sensitive elements, ensuring its open distribution as a symbol of the program's transparency.

Wake-up calls

The wake-up call tradition, initiated during 's early spaceflights to help maintain crew schedules and boost morale, was employed throughout the STS-4 mission aboard from June 27 to July 4, 1982. These calls, totaling seven over the mission's duration, were broadcast each morning via the ground control intercom system at 's in and captured in official mission audio logs for documentation and review. Selections for the wake-up music and messages were curated by the crew's families in coordination with public affairs personnel, emphasizing personal significance to the astronauts or alignment with mission milestones to enhance crew motivation and a sense of connection during orbital operations. For instance, choices often highlighted the astronauts' backgrounds, such as alma maters or fraternal affiliations, while the final call incorporated patriotic themes to coincide with the landing, underscoring the mission's timing near Day. The specific wake-up calls for STS-4 proceeded as follows:
DateMission DaySelectionContext/Notes
June 28, 1982Day 2"Up, Up and Away" by The 5th DimensionThematic tie to the shuttle's orbital flight, evoking ascent and space travel.
June 29, 1982Day 3"Hold That Tiger" performed by the Auburn University BandHonoring commander Thomas Mattingly and pilot Henry Hartsfield, both graduates of Auburn University; the crew responded appreciatively in audio logs.
June 30, 1982Day 4Taped messages from pilot Henry Hartsfield's familyNo music; personalized greetings marking Hartsfield's 25th wedding anniversary to foster emotional support.
July 1, 1982Day 5No music specified; standard ground-to-space wake-up at 1:10 a.m. CDT over Dakar, SenegalFocused on routine activation, coinciding with crew preparations like operating the food warmer.
July 2, 1982Day 6"Theme from 'Chariots of Fire'" by VangelisInstrumental selection to energize the crew during late-mission activities.
July 3, 1982Day 7College fraternity songs: "Delta Tau Delta" for Mattingly; "Delta Chi" for HartsfieldReflecting the astronauts' collegiate affiliations to personalize the call and maintain high spirits.
July 4, 1982Day 8"This Is My Country" (traditional patriotic song)Played to celebrate the mission's conclusion on Independence Day, reinforcing national pride and mission success themes.

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    Ten times Houston picked out appropriate musical selections, albeit none of them "Hail Purdue" in honor of Gene's alma mater,. Purdue University. There was no ...